US20150101533A1 - Substrate processing apparatus - Google Patents
Substrate processing apparatus Download PDFInfo
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- US20150101533A1 US20150101533A1 US14/579,489 US201414579489A US2015101533A1 US 20150101533 A1 US20150101533 A1 US 20150101533A1 US 201414579489 A US201414579489 A US 201414579489A US 2015101533 A1 US2015101533 A1 US 2015101533A1
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/67005—Apparatus not specifically provided for elsewhere
- H01L21/67011—Apparatus for manufacture or treatment
- H01L21/67017—Apparatus for fluid treatment
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- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23C—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
- C23C16/00—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
- C23C16/22—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the deposition of inorganic material, other than metallic material
- C23C16/30—Deposition of compounds, mixtures or solid solutions, e.g. borides, carbides, nitrides
- C23C16/34—Nitrides
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- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23C—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
- C23C16/00—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
- C23C16/22—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the deposition of inorganic material, other than metallic material
- C23C16/30—Deposition of compounds, mixtures or solid solutions, e.g. borides, carbides, nitrides
- C23C16/34—Nitrides
- C23C16/345—Silicon nitride
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- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23C—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
- C23C16/00—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes
- C23C16/44—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the method of coating
- C23C16/455—Chemical coating by decomposition of gaseous compounds, without leaving reaction products of surface material in the coating, i.e. chemical vapour deposition [CVD] processes characterised by the method of coating characterised by the method used for introducing gases into reaction chamber or for modifying gas flows in reaction chamber
- C23C16/45523—Pulsed gas flow or change of composition over time
- C23C16/45525—Atomic layer deposition [ALD]
- C23C16/45527—Atomic layer deposition [ALD] characterized by the ALD cycle, e.g. different flows or temperatures during half-reactions, unusual pulsing sequence, use of precursor mixtures or auxiliary reactants or activations
- C23C16/45536—Use of plasma, radiation or electromagnetic fields
- C23C16/45542—Plasma being used non-continuously during the ALD reactions
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/02—Manufacture or treatment of semiconductor devices or of parts thereof
- H01L21/02104—Forming layers
- H01L21/02107—Forming insulating materials on a substrate
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/02—Manufacture or treatment of semiconductor devices or of parts thereof
- H01L21/02104—Forming layers
- H01L21/02107—Forming insulating materials on a substrate
- H01L21/02109—Forming insulating materials on a substrate characterised by the type of layer, e.g. type of material, porous/non-porous, pre-cursors, mixtures or laminates
- H01L21/02112—Forming insulating materials on a substrate characterised by the type of layer, e.g. type of material, porous/non-porous, pre-cursors, mixtures or laminates characterised by the material of the layer
- H01L21/02123—Forming insulating materials on a substrate characterised by the type of layer, e.g. type of material, porous/non-porous, pre-cursors, mixtures or laminates characterised by the material of the layer the material containing silicon
- H01L21/0217—Forming insulating materials on a substrate characterised by the type of layer, e.g. type of material, porous/non-porous, pre-cursors, mixtures or laminates characterised by the material of the layer the material containing silicon the material being a silicon nitride not containing oxygen, e.g. SixNy or SixByNz
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/02—Manufacture or treatment of semiconductor devices or of parts thereof
- H01L21/02104—Forming layers
- H01L21/02107—Forming insulating materials on a substrate
- H01L21/02225—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer
- H01L21/0226—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process
- H01L21/02263—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process deposition from the gas or vapour phase
- H01L21/02271—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process deposition from the gas or vapour phase deposition by decomposition or reaction of gaseous or vapour phase compounds, i.e. chemical vapour deposition
- H01L21/02274—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process deposition from the gas or vapour phase deposition by decomposition or reaction of gaseous or vapour phase compounds, i.e. chemical vapour deposition in the presence of a plasma [PECVD]
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/02—Manufacture or treatment of semiconductor devices or of parts thereof
- H01L21/02104—Forming layers
- H01L21/02107—Forming insulating materials on a substrate
- H01L21/02225—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer
- H01L21/0226—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process
- H01L21/02263—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process deposition from the gas or vapour phase
- H01L21/02271—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process deposition from the gas or vapour phase deposition by decomposition or reaction of gaseous or vapour phase compounds, i.e. chemical vapour deposition
- H01L21/0228—Forming insulating materials on a substrate characterised by the process for the formation of the insulating layer formation by a deposition process deposition from the gas or vapour phase deposition by decomposition or reaction of gaseous or vapour phase compounds, i.e. chemical vapour deposition deposition by cyclic CVD, e.g. ALD, ALE, pulsed CVD
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/67005—Apparatus not specifically provided for elsewhere
- H01L21/67011—Apparatus for manufacture or treatment
- H01L21/6715—Apparatus for applying a liquid, a resin, an ink or the like
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/67005—Apparatus not specifically provided for elsewhere
- H01L21/67242—Apparatus for monitoring, sorting or marking
Definitions
- the present invention relates to a method of manufacturing a semiconductor device, which includes a process of forming a thin film on a substrate, a method of processing a substrate, a substrate processing apparatus that may be used in the process of forming the thin film, and a non-transitory computer-readable recording medium.
- a silicon nitride (SiN) film may be formed on a substrate, as one process of a method of manufacturing a semiconductor device, e.g., a large-scale integrated circuit (LSI), static random access memory (SRAM), dynamic random access memory (DRAM), etc.
- the silicon nitride (SiN) film may be formed by alternately and repeatedly performing a process of supplying, for example, a silicon-containing gas to a substrate in a process chamber and a process of supplying a plasma-excited nitrogen-containing gas to the substrate in the process chamber.
- the silicon nitride (SiN) film may be used, for example, as an etching stopper layer when a silicon oxide (SiO) film is etched using a solution containing hydrogen fluoride, during a process of manufacturing a semiconductor device.
- the present invention is directed to provide a method of manufacturing a semiconductor device capable of forming a nitride film resistant to hydrogen fluoride at low temperatures, a method of processing a substrate, a substrate processing apparatus, and a non-transitory computer-readable recording medium.
- a substrate processing apparatus comprising: a process chamber configured to accommodate a substrate; a first gas supply system configured to supply a source gas to the substrate in the process chamber; a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber; a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber; a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber; an excitation unit configured to plasma-excite or thermally excite a gas; and a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including: (a) supplying the source gas to the substrate in the process chamber; (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber; (c) supplying a plasma-excited or thermally excited nit
- a substrate processing apparatus comprising: a process chamber configured to accommodate a substrate; a first gas supply system configured to supply a source gas to the substrate in the process chamber; a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber; a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber; a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber; an excitation unit configured to plasma-excite or thermally excite a gas; and a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including: (a) supplying the source gas to the substrate in the process chamber; (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber; (c) supplying a plasma-excited or thermally excited nit
- a substrate processing apparatus comprising: a process chamber configured to accommodate a substrate; a first gas supply system configured to supply a source gas to the substrate in the process chamber; a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber; a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber; a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber; an excitation unit configured to plasma-excite or thermally excite a gas; and a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including: (a) supplying the source gas to the substrate in the process chamber; (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber; (c) supplying a plasma-excited or thermally excited n
- FIG. 1 is a schematic configuration diagram of a vertical process furnace of a substrate processing apparatus according to an embodiment of the present invention, in which a vertical cross-sectional view of a portion of the vertical process furnace is provided.
- FIG. 2 is a schematic configuration diagram of the vertical process furnace of the substrate processing apparatus according to an embodiment of the present invention, in which a cross-sectional view taken along line A-A in the portion of the process furnace of FIG. 1 is provided.
- FIG. 3 is a schematic configuration diagram of a vertical process furnace of a substrate processing apparatus according to a modified example of an embodiment of the present invention, in which a vertical cross-sectional view of a portion of the vertical process furnace is provided.
- FIG. 4 is a schematic configuration diagram of a controller included in a substrate processing apparatus according to an embodiment of the present invention.
- FIG. 5 is a flowchart illustrating a method of forming a film according to a first embodiment of the present invention.
- FIG. 6 is a flowchart illustrating a method of forming a film according to a second embodiment of the present invention.
- FIG. 7 is a flowchart illustrating a method of forming a film according to a third embodiment of the present invention.
- FIG. 8 is a flowchart illustrating a method of forming a film according to a fourth embodiment of the present invention.
- FIG. 9 is a flowchart illustrating a method of forming a film according to a fifth embodiment of the present invention.
- FIG. 10 is a diagram illustrating timing of supplying a gas and plasma power according to the first embodiment of the present invention.
- FIG. 11 is a diagram illustrating timing of supplying a gas and plasma power according to the second embodiment of the present invention.
- FIG. 12 is a diagram illustrating timing of supplying a gas and plasma power according to the third embodiment of the present invention.
- FIG. 13 is a diagram illustrating timing of supplying a gas and plasma power according to the fourth embodiment of the present invention.
- FIG. 14 is a diagram illustrating timing of supplying a gas and plasma power according to the fifth embodiment of the present invention.
- FIG. 15A is a diagram comparing sequences of supplying a gas during forming of a silicon nitride (SiN) film according to Example 1 of the present invention and a Comparative Example.
- FIG. 15B is a graph illustrating a result of measuring wet-etching rates (WERs) of SiN films according to Example 1 of the present invention and the Comparative Example.
- FIG. 16A illustrates a sequence of supplying a gas during forming of each of the SiN films according to Example 1 of the present invention.
- FIG. 16B is a graph illustrating a result of measuring the WERs of the SiN films according to Example 1 of the present invention.
- FIG. 17A is a graph illustrating a result of measuring a range of the WERs of the SiN films in a plane of a wafer according to Example 1 of the present invention.
- FIG. 17B is a graph illustrating a result of measuring a distribution of the WERs of the SiN films in the plane of the wafer according to Example 1 of the present invention.
- FIG. 18A is a diagram illustrating a sequence of supplying a gas during forming of each of SiN films according to Example 2 of the present invention and a Comparative Example.
- FIG. 18B is a graph illustrating a result of measuring the WERs of the SiN films according to Example 2 of the present invention.
- FIG. 19A is a graph illustrating a result of measuring a range of the WERs of the SiN films in the plane of the wafer according to Example 2 of the present invention and the Comparative Example.
- FIG. 19B is a graph illustrating a result of measuring a distribution of the WERs of the SiN films in the plane of the wafer according to Example 2 of the present invention and the Comparative Example.
- FIG. 20 is a graph illustrating the relationship between the thickness uniformity of the SiN films in a plane of a wafer and gas species used in a modifying process according to Example 2 of the present invention.
- FIG. 21A illustrates a sequence of supplying a gas during forming of each of SiN films according to Example 3 of the present invention.
- FIG. 21B is a graph illustrating a result of measuring a range of the WERs of the SiN films in the plane of the wafer according to Example 3 of the present invention.
- FIG. 21C is a graph illustrating a result of measuring the thickness uniformity of the SiN films in the plane of the wafer according to Example 3 of the present invention.
- FIG. 22A is a graph illustrating the relationship between the WER of a SiN film and a film-forming temperature according to Example 4 of the present invention.
- FIG. 22B is a partially enlarged view of the graph of FIG. 22A .
- FIG. 23 is a graph illustrating the relationship between the WER of a SiN film and a film-forming temperature.
- FIG. 23 is a graph illustrating the relationship between the wet-etching rate (WER) of a silicon nitride (SiN) film and a film-forming temperature.
- WER wet-etching rate
- a horizontal axis denotes a film-forming temperature when the silicon nitride (SiN) film was formed
- a vertical axis denotes a WER ( ⁇ /min) when the silicon nitride (SiN) film was etched using a solution containing hydrogen fluoride.
- a nitride film highly resistant to hydrogen fluoride may be formed at low temperatures by plasma-exciting and supplying a modifying gas including at least one element among hydrogen, nitrogen, and argon to a substrate in a process chamber either before a nitrogen-containing gas is supplied and after a source gas is supplied or before the source gas is supplied and after the nitrogen-containing gas is supplied, when the nitride film is formed on the substrate by alternately and repeatedly performing a process of supplying the source gas to the substrate accommodated in the process chamber and a process of supplying a plasma-excited nitrogen-containing gas to the substrate in the process chamber.
- the process of plasma-exciting and supplying the modifying gas may be performed only before the nitrogen-containing gas is supplied and after the source gas is supplied, may be performed only before the source gas is supplied and after the nitrogen-containing gas is supplied, and may be performed both before the nitrogen-containing gas is supplied and after the source gas is supplied, and before the source gas is supplied and after the nitrogen-containing gas is supplied.
- FIG. 1 is a schematic configuration diagram of a vertical process furnace 202 of a substrate processing apparatus according to an embodiment of the present invention, in which a vertical cross-sectional view of a portion of the vertical process furnace 202 is provided.
- FIG. 2 is a schematic configuration diagram of the vertical process furnace 202 of the substrate processing apparatus according to an embodiment of the present invention, in which a cross-sectional view taken along line A-A in the portion of the process furnace 202 of FIG. 1 is provided.
- the present invention is not limited to the substrate processing apparatus according to the present embodiment and may also be applied to a substrate processing apparatus including a single-wafer type, a hot-wall type, or a cold-wall type process furnace.
- the process furnace 202 includes a heater 207 serving as a heating unit (heating mechanism).
- the heater 207 has a cylindrical shape, and is vertically installed by being supported by a heater base (not shown) serving as a retaining plate. Also, the heater 207 acts as an activating mechanism that activates a gas with heat, as will be described below.
- a reaction pipe 203 forming a reaction container (process container) in a concentric shape with respect to the heater 207 is provided.
- the reaction pipe 203 is formed of a heat-resistant material, e.g., quartz (SiO 2 ) or silicon carbide (SiC), and has a cylindrical shape, an upper end of which is closed and a lower end of which is open.
- a process chamber 201 is formed in a hollow tubular portion of the reaction pipe 203 , and is configured such that wafers 200 may be accommodated as substrates in a horizontal posture to be arranged in multiple stages in a vertical direction by means of a boat 217 which will be described below.
- a first nozzle 233 a serving as a first gas introduction port, a second nozzle 233 b serving as a second gas introduction port, and a third nozzle 233 c serving as a third gas introduction port are installed in the process chamber 201 to pass through lower sidewalls of the reaction pipe 203 .
- a first gas supply pipe 232 a is connected to the first nozzle 233 a .
- a second gas supply pipe 232 b , a fourth gas supply pipe 232 d , a sixth gas supply pipe 232 f , and an eighth gas supply pipe 232 h are connected to the second nozzle 233 b .
- a third gas supply pipe 232 c , a fifth gas supply pipe 232 e , a seventh gas supply pipe 232 g , and a ninth gas supply pipe 232 i are connected to the third nozzle 233 c .
- the three nozzles 233 a , 233 b , and 233 c and the nine gas supply pipes 232 a , 232 b , 232 c , 232 d , 232 e , 232 f , 232 g , 232 h , and 232 i are installed in the reaction pipe 203 so that a plurality of types of gases (five types of gases in the present embodiment) may be supplied into the process chamber 201 .
- a manifold formed of metal may be installed below the reaction pipe 203 to support the reaction pipe 203 , and the first to third nozzles 233 a through 233 c may be installed to pass through sidewalls of the manifold.
- an exhaust pipe 231 which will be described below may be further installed in the manifold.
- the exhaust pipe 231 may be installed below the reaction pipe 203 rather than in the manifold.
- a furnace port portion of the process furnace 202 may be formed of metal and nozzles may be installed at the furnace port portion formed of metal.
- a mass flow controller (MFC) 241 a which is a flow rate control device (flow rate control unit) and a valve 243 a which is a switch valve are sequentially installed at the first gas supply pipe 232 a in an upstream direction.
- a first inert gas supply pipe 232 j is connected to the first gas supply pipe 232 a at a downstream side of the valve 243 a .
- An MFC 241 j which is a flow rate control device (flow rate control unit) and a valve 243 j which is a switch valve are sequentially installed at the first inert gas supply pipe 232 j in an upstream direction.
- the first nozzle 233 a is connected to a front end of the first gas supply pipe 232 a .
- the first nozzle 233 a is installed in an arc-shaped space between inner walls of the reaction pipe 203 and the wafers 200 to move upward from lower inner walls of the reaction pipe 203 in a direction in which the wafers 200 are stacked.
- the first nozzle 233 a is installed along a wafer arrangement region in which the wafers 200 are arranged, in a region that horizontally surrounds the wafer arrangement region at sides of the wafer arrangement region.
- the first nozzle 233 a is configured as an L-shaped long nozzle, and includes a horizontal portion passing through lower sidewalls of the reaction pipe 203 and a vertical portion vertically moving at least from one end of the wafer arrangement region toward the other end thereof.
- a plurality of gas supply holes 248 a are formed in a side surface of the first nozzle 233 a to supply a gas.
- the gas supply holes 248 a may be opened toward a center of the reaction pipe 203 to supply a gas toward the wafers 200 .
- the gas supply holes 248 a are formed from a lower portion of the reaction pipe 203 to an upper portion thereof, and the gas supply holes 248 a each have the same opening area and are also provided at the same opening pitch.
- An MFC 241 b which is a flow rate control device (flow rate control unit) and a valve 243 b which is a switch valve are sequentially installed at the second gas supply pipe 232 b in an upstream direction.
- a second inert gas supply pipe 232 k is connected to the second gas supply pipe 232 b at a downstream side of the valve 243 b .
- An MFC 241 k which is a flow rate control device (flow rate control unit) and a valve 243 k which is a switch valve are sequentially installed at the second inert gas supply pipe 233 k in an upstream direction.
- the second nozzle 233 b is connected to a front end of the second gas supply pipe 232 b .
- the second nozzle 233 b is installed in a buffer chamber 237 b which is a gas dispersion space.
- the buffer chamber 237 b is installed in the arc-shaped space between the inner walls of the reaction pipe 203 and the wafers 200 and at a portion covering from the lower inner walls of the reaction pipe 203 to upper inner walls thereof, in the direction in which the wafers 200 are stacked.
- the buffer chamber 237 b is installed along the wafer arrangement region in which the wafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at the sides of the wafer arrangement region.
- a plurality of gas supply holes 238 b are formed at an end portion of a wall of the buffer chamber 237 b adjacent to the wafers 200 so as to supply a gas.
- the gas supply holes 238 b may be opened toward the center of the reaction pipe 203 to supply a gas toward the wafers 200 .
- the gas supply holes 238 b are formed from the lower portion of the reaction pipe 203 to the upper portion thereof, and each have the same opening area and are also provided at the same opening pitch.
- the second nozzle 233 b is installed at another end portion of the buffer chamber 237 b opposite to the end portion in which the gas supply holes 238 b are formed, so as to move upward from the lower inner walls of the reaction pipe 203 in the direction in which the wafers 200 are stacked.
- the second nozzle 233 b is installed along the wafer arrangement region in which the wafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at the sides of the wafer arrangement region.
- the second nozzle 233 b is configured as an L-shaped long nozzle, and includes a horizontal portion passing through the lower sidewalls of the reaction pipe 203 and a vertical portion vertically moving at least from one end of the wafer arrangement region toward the other end thereof.
- a plurality of gas supply holes 248 b are formed in a side surface of the second nozzle 233 b to supply a gas.
- the gas supply holes 248 b open toward the center of the buffer chamber 237 b .
- the gas supply holes 248 b are formed from the lower portion of the reaction pipe 203 to the upper portion thereof, similar to the gas supply holes 238 b in the buffer chamber 237 b .
- the gas supply holes 248 b may be formed to each have the same opening area at the same opening pitch from an upstream side (lower portion thereof) to a downstream side (upper portion thereof) when a difference between pressures in the buffer chamber 237 b and the process chamber 201 is small.
- the opening areas of the gas supply holes 248 b may increase or the opening pitch between the gas supply holes 248 b may decrease from the upstream side (lower portion) thereof to the downstream side (upper portion) thereof when the difference between the pressures in the buffer chamber 237 b and the process chamber 201 is large.
- gases are ejected through each of the gas supply holes 248 b by adjusting the opening areas or the opening pitch of the gas supply holes 248 b of the second nozzle 233 b from the upstream side to the downstream side as described above. Then, the gases ejected through the gas supply holes 248 b are introduced into the buffer chamber 237 b , and then the different flow velocities of the gases are equalized in the buffer chamber 237 b .
- the speeds of particles of the gases ejected through the gas supply holes 248 b of the second nozzle 233 b into the buffer chamber 237 b are reduced in the buffer chamber 237 b , and the gases are then ejected into the process chamber 201 through the gas supply holes 238 b of the buffer chamber 237 b .
- the gases ejected into the buffer chamber 237 b through the gas supply holes 248 b of the second nozzle 233 b are ejected into the process chamber 201 through the gas supply holes 238 b of the buffer chamber 237 b
- the gases each have a uniform flow rate and flow velocity.
- An MFC 241 c which is a flow rate control device (flow rate control unit) and a valve 243 c which is a switch valve are sequentially installed at the third gas supply pipe 232 c in an upstream direction.
- a third inert gas supply pipe 232 l is connected to the third gas supply pipe 232 c at a downstream side of the valve 243 c .
- An MFC 241 l which is a flow rate control device (flow rate control unit) and a valve 243 l which is a switch valve are sequentially installed at the third inert gas supply pipe 232 l in an upstream direction.
- the third nozzle 233 c is connected to a front end of the third gas supply pipe 232 c .
- the third nozzle 233 c is installed in a buffer chamber 237 c which is a gas dispersion space.
- the buffer chamber 237 c is installed in the arc-shaped space between the inner walls of the reaction pipe 203 and the wafers 200 and at the portion covering from the lower inner walls of the reaction pipe 203 to the upper inner walls thereof, in the direction in which the wafers 200 are stacked.
- the buffer chamber 237 c is installed along the wafer arrangement region in which the wafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at the sides of the wafer arrangement region.
- a plurality of gas supply holes 238 c are formed at an end portion of a wall of the buffer chamber 237 c adjacent to the wafers 200 so as to supply a gas.
- the gas supply holes 238 c open toward the center of the reaction pipe 203 to supply a gas toward the wafers 200 .
- the gas supply holes 238 c are formed from the lower portion of the reaction pipe 203 to the upper portion thereof, and each have the same opening area and are also provided at the same opening pitch.
- the third nozzle 233 c is installed at another end portion of the buffer chamber 237 c opposite to an end portion of the buffer chamber 237 c in which the gas supply holes 238 c are formed so as to move upward from the lower inner walls of the reaction pipe 203 , in the direction in which the wafers 200 are stacked. That is, the third nozzle 233 c is installed along the wafer arrangement region in which the wafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at sides of the wafer arrangement region.
- the third nozzle 233 c is configured as an L-shaped long nozzle, and includes a horizontal portion passing through the lower sidewalls of the reaction pipe 203 , and a vertical portion vertically moving at least from one end of the wafer arrangement region toward another end thereof.
- a plurality of gas supply holes 248 c are formed in a side surface of the first nozzle 233 a to supply a gas.
- the gas supply holes 248 c open toward the center of the buffer chamber 237 .
- the gas supply holes 248 c are formed from the lower portion of the reaction pipe 203 to the upper portion thereof, similar to the gas supply holes 238 c of the buffer chamber 237 .
- the gas supply holes 248 c may be formed to each have the same opening area at the same opening pitch from an upstream side (lower portion thereof) to a downstream side (upper portion thereof) when a difference between pressures in the buffer chamber 237 and the process chamber 201 is small. However, the opening areas of the gas supply holes 248 c may increase or the opening pitch between the gas supply holes 248 c may decrease from the upstream side (lower portion) thereof to the downstream side (upper portion) thereof when the difference between the pressures in the buffer chamber 237 and the process chamber 201 is large.
- gases are ejected through each of the gas supply holes 248 c by adjusting the opening areas or the opening pitch of the gas supply holes 248 c of the third nozzle 233 c from the upstream side to the downstream side as described above. Then, the gases ejected through the gas supply holes 248 c are introduced into the buffer chamber 237 c , and then the different flow velocities of the gases are equalized in the buffer chamber 237 c .
- the speeds of particles of the gases ejected through the gas supply holes 248 c of the third nozzle 233 c into the buffer chamber 237 c are reduced in the buffer chamber 237 c , and the gases are then ejected into the process chamber 201 through the gas supply holes 238 c of the buffer chamber 237 .
- the gases ejected into the buffer chamber 237 c through the gas supply holes 248 c of the third nozzle 233 c are ejected into the process chamber 201 through the gas supply holes 238 c of the buffer chamber 237 c
- the gases each have the same flow rate and flow velocity.
- An MFC 241 d which is a flow rate control device (flow rate control unit) and a valve 243 d which is a switch valve are sequentially installed at the fourth gas supply pipe 232 d in an upstream direction.
- a fourth inert gas supply pipe 232 m is connected to the fourth gas supply pipe 232 d at a downstream side of the valve 243 d .
- An MFC 241 m which is a flow rate control device (flow rate control unit) and a valve 243 m which is a switch valve are sequentially installed at the fourth inert gas supply pipe 232 m in an upstream direction.
- a front end of the fourth gas supply pipe 232 d is connected to the second gas supply pipe 232 b at a downstream side of the valve 243 b.
- An MFC 241 e which is a flow rate control device (flow rate control unit) and a valve 243 e which is a switch valve are sequentially installed at the fifth gas supply pipe 232 e in an upstream direction.
- a fifth inert gas supply pipe 232 n is connected to the fifth gas supply pipe 232 e at a downstream side of the valve 243 e .
- An MFC 241 n which is a flow rate control device (flow rate control unit) and a valve 243 n which is a switch valve are sequentially installed at the fifth inert gas supply pipe 232 n in an upstream direction.
- a front end of the fifth gas supply pipe 232 e is connected to the third gas supply pipe 232 c at a downstream side of the valve 243 c.
- An MFC 241 f which is a flow rate control device (flow rate control unit) and a valve 243 f which is a switch valve are sequentially installed at the sixth gas supply pipe 232 f in an upstream direction.
- a sixth inert gas supply pipe 232 o is connected to the sixth gas supply pipe 232 f at a downstream side of the valve 243 f .
- An MFC 2410 which is a flow rate control device (flow rate control unit) and a valve 243 o which is a switch valve are sequentially installed at the sixth inert gas supply pipe 232 o in an upstream direction.
- a front end of the sixth gas supply pipe 232 f is connected to the second gas supply pipe 232 b at a downstream side of the valve 243 b.
- An MFC 241 g which is a flow rate control device (flow rate control unit) and a valve 243 g which is a switch valve are sequentially installed at the seventh gas supply pipe 232 g in an upstream direction.
- a seventh inert gas supply pipe 232 p is connected to the seventh gas supply pipe 232 g at a downstream side of the valve 243 g .
- An MFC 241 p which is a flow rate control device (flow rate control unit) and a valve 243 p which is a switch valve are sequentially installed at the seventh inert gas supply pipe 232 p in an upstream direction.
- a front end of the seventh gas supply pipe 232 g is connected to the third gas supply pipe 232 c at a downstream side of the valve 243 c.
- An MFC 241 h which is a flow rate control device (flow rate control unit) and a valve 243 h which is a switch valve are sequentially installed at the eighth gas supply pipe 232 h in an upstream direction.
- a front end of the eighth gas supply pipe 232 h is connected to the second gas supply pipe 232 b at a downstream side of the valve 243 b.
- An MFC 241 i which is a flow rate control device (flow rate control unit) and a valve 243 i which is a switch valve are sequentially installed at the ninth gas supply pipe 232 i in an upstream direction.
- a front end of the ninth gas supply pipe 232 i is connected to the third gas supply pipe 232 c at a downstream side of the valve 243 c.
- a main flow of a gas within the reaction pipe 203 is controlled to be parallel to, i.e., to be horizontal with respect to, a surface of each of the wafers 200 by carrying the gas via the nozzles 233 a , 233 b , and 233 c and the buffer chambers 237 b and 237 c in the vertically long arc-shaped space, defined by the inner walls of the reaction pipe 203 and ends of a plurality of stacked wafers 200 , and then first ejecting the gas into the reaction pipe 203 near the wafers 200 through the gas supply holes 248 a , 248 b , 248 c , 283 b and 238 c which are formed in the nozzles 233 a , 233 b and 233 c , respectively, and the buffer chambers 237 b and 237 c .
- the gas may be equally supplied to the wafers 200 , thereby uniformizing the thickness of a thin film to be formed on each of the wafers 200 .
- a residual gas remaining after a reaction flows toward the exhaust pipe 231 , i.e., in the direction of the exhaust pipe 231 which will be described below, but a flowing direction of the residual gas may be appropriately defined by a location of the exhaust port and is not limited to the vertical direction.
- the two buffer chambers 237 b and 237 c are disposed to face each other via the center of the wafers 200 , i.e., the center of the reaction pipe 203 .
- the two buffer chambers 237 b and 237 c are disposed to be linearly symmetrical with respect to a straight line connecting the center of the wafers 200 and the center of the exhaust port 231 a (which will be described below) installed at a sidewall of the reaction pipe 203 , as seen from a plan view.
- the two buffer chambers 237 b and 237 c are disposed such that straight lines connecting the gas supply holes 238 b of the buffer chamber 237 b , the gas supply holes 238 c of the buffer chamber 237 c , and the center of the exhaust port 231 a may form an isosceles triangle. Accordingly, the flow of a gas to the wafers 200 from the two buffer chambers 237 b and 237 c may be equalized. That is, the flow of the gas to the wafers 20 from the two buffer chambers 237 b and 237 c may be linearly symmetrical with respect to the straight line connecting the center of the wafers 200 and the center of the exhaust port 231 a.
- dichlorosilane (SiH 2 Cl 2 , abbreviated to ‘DCS’) gas is supplied as a source gas containing a specific element, e.g., silicon (Si) (a silicon-containing gas), into the process chamber 201 via the MFC 241 a , the valve 243 a , and the first nozzle 233 a .
- a specific element e.g., silicon (Si) (a silicon-containing gas
- an inert gas may be supplied into the first gas supply pipe 232 a via the MFC 241 j and the valve 243 j.
- ammonia (NH 3 ) gas is supplied as a gas containing nitrogen (a nitrogen-containing gas), i.e., a nitriding gas, into the process chamber 201 via the MFC 241 b , the valve 243 b , the second nozzle 233 b , and the buffer chamber 237 b .
- a nitrogen-containing gas i.e., a nitrogen-containing gas
- an inert gas may be supplied into the second gas supply pipe 232 b via the MFC 241 k and the valve 243 k.
- ammonia (NH 3 ) gas is supplied as a gas containing nitrogen (a nitrogen-containing gas), i.e., a nitriding gas, into the process chamber 201 via the MFC 241 c , the valve 243 c , the third nozzle 233 c , and the buffer chamber 237 c .
- an inert gas may be supplied into the third gas supply pipe 232 c through the third inert gas supply pipe 232 l via the MFC 241 l and the valve 243 l.
- hydrogen (H 2 ) gas is supplied as a gas containing hydrogen which is a modifying gas (a hydrogen-containing gas), i.e., a reducing gas, into the process chamber 201 via the MFC 241 d , the valve 243 d , the second gas supply pipe 232 b , the second nozzle 233 b , and the buffer chamber 237 b .
- an inert gas may be supplied into the fourth gas supply pipe 232 d through the fourth inert gas supply pipe 232 m via the MFC 241 m and the valve 243 m.
- hydrogen (H 2 ) gas is supplied as a gas containing hydrogen which is a modifying gas (a hydrogen-containing gas), i.e., a reducing gas, into the process chamber 201 via the MFC 241 e , the valve 243 e , the third gas supply pipe 232 c , the third nozzle 233 c , and the buffer chamber 237 c .
- an inert gas may be supplied into the fifth gas supply pipe 232 e through the fifth inert gas supply pipe 232 n via the MFC 241 n and the valve 243 n.
- argon (Ar) gas is supplied as a rare gas which is a modifying gas into the process chamber 201 via the MFC 241 f , the valve 243 f , the second gas supply pipe 232 b , the second nozzle 233 b , and the buffer chamber 237 b .
- an inert gas may be supplied into the sixth gas supply pipe 232 f through the sixth inert gas supply pipe 232 o via the MFC 2410 and the valve 243 o.
- argon (Ar) gas is supplied as a rare gas which is a modifying gas into the process chamber 201 via the MFC 241 g , the valve 243 g , the third gas supply pipe 232 c , the third nozzle 233 c , and the buffer chamber 237 c .
- an inert gas may be supplied into the seventh gas supply pipe 232 through the seventh inert gas supply pipe 232 p via the MFC 241 p and the valve 243 p.
- nitrogen (N 2 ) is supplied as a modifying gas into the process chamber 201 via the MFC 241 h , the valve 243 h , the second gas supply pipe 232 b , the second nozzle 233 b , and the buffer chamber 237 b.
- nitrogen (N 2 ) gas is supplied as a modifying gas into the process chamber 201 via the MFC 241 i , the valve 243 i , the third gas supply pipe 232 c , the third nozzle 233 c , and the buffer chamber 237 c.
- a first gas supply system which supplies a source gas (DCS gas) to the wafers 200 in the process chamber 201 , i.e., a silicon-containing gas supply system (DCS gas supply system), mainly includes the first gas supply pipe 232 a , the MFC 241 a , and the valve 243 a .
- the first nozzle 233 a may be further included in the first gas supply system.
- a first inert gas supply system mainly includes the first inert gas supply pipe 232 j , the MFC 241 j , and the valve 243 j .
- the first inert gas supply system may also act as a purge gas supply system.
- a second gas supply system which supplies a nitriding gas (NH 3 gas) to the wafers 200 in the process chamber 201 , i.e., a nitrogen-containing gas supply system (an NH 3 gas supply system)
- a nitrogen-containing gas supply system an NH 3 gas supply system
- a second inert gas supply system mainly includes the second inert gas supply pipe 232 k , the third inert gas supply pipe 232 l , the MFCs 241 k and 241 l , and the valves 243 k and 243 l .
- the second inert gas supply system also acts as a purge gas supply system.
- a third gas supply system which supplies a hydrogen-containing gas (H 2 gas) to the wafers 200 in the process chamber 201 , i.e., a hydrogen-containing gas supply system (a H 2 gas supply system)
- a hydrogen-containing gas supply system mainly includes the fourth gas supply pipe 232 d , the fifth gas supply pipe 232 e , the MFCs 241 d and 241 e , and the valves 243 d and 243 e .
- a downstream side of a portion of the second gas supply pipe 232 b connected to the fourth gas supply pipe 232 d , and a downstream side of a portion of the third gas supply pipe 232 c connected to the fifth gas supply pipe 232 e , the second nozzle 233 b , the third nozzle 233 c , and the buffer chambers 237 b and 237 c may be further included in the third gas supply system.
- a third inert gas supply system mainly includes the fourth inert gas supply pipe 232 m , the fifth inert gas supply pipe 232 n , the MFCs 241 m and 241 n , and the valves 243 m and 243 n .
- the third inert gas supply system may also act as a purge gas supply system.
- a rare gas supply system which supplies a rare gas (Ar gas) to the wafers 200 in the process chamber 201 mainly includes the sixth gas supply pipe 232 f , the seventh gas supply pipe 232 g , the MFCs 241 f and 241 g , and the valves 243 f and 243 g .
- a downstream side of a portion of the second gas supply pipe 232 b connected to the sixth gas supply pipe 232 f , and a downstream side of a portion of the third gas supply pipe 232 c connected to the seventh gas supply pipe 232 g , the second nozzle 233 b , the third nozzle 233 c , and the buffer chambers 237 b and 237 c may further be included in the rare gas supply system.
- a fourth inert gas supply system mainly includes the sixth inert gas supply pipe 232 o , the seventh inert gas supply pipe 232 p , the MFCs 2410 and 241 p , and the valves 243 o and 243 p .
- the fourth inert gas supply system may also act as a purge gas supply system.
- a nitrogen gas supply system which supplies nitrogen gas (N 2 gas) to the wafers 200 in the process chamber 201 mainly includes the eighth gas supply pipe 232 h , the ninth gas supply pipe 232 i , the MFCs 241 h and 241 i , and the valves 243 h and 243 i .
- a downstream side of a portion of the second gas supply pipe 232 b connected to the eighth gas supply pipe 232 h , and a downstream side of a portion of the third gas supply pipe 232 c connected to the ninth gas supply pipe 232 i , the second nozzle 233 b , the third nozzle 233 c , and the buffer chambers 237 b and 237 c may further be included in the nitrogen gas supply system.
- a fourth gas supply system which supplies at least one of nitrogen gas (N 2 gas) and a rare gas (Ar gas) to the wafers 200 in the process chamber 201 mainly includes the rare gas supply system and the nitrogen gas supply system described above.
- the fourth gas supply system may also act as a purge gas supply system.
- each of the third gas supply system (reducing gas supply system) and the fourth gas supply system (nitrogen gas supply system and rare gas supply system) may also be referred to as a modifying gas supply system.
- a nitriding gas (NH 3 ) acts as a reactive gas
- the second gas supply system (nitriding gas supply system) may also be referred to as a reactive gas supply system.
- a first rod-shaped electrode 269 b serving as a first electrode and a second rod-shaped electrode 270 b serving as a second electrode, both of which are slender and long electrodes, are provided from the lower portion of the reaction pipe 203 to the upper portion thereof, in the direction in which the wafers 200 are stacked.
- the first rod-shaped electrode 269 b and the second rod-shaped electrode 270 b are disposed in parallel with the second nozzle 233 b .
- Each of the first rod-shaped electrode 269 b and the second rod-shaped electrode 270 b is covered with an electrode protection pipe 275 b which is configured to protect these electrodes from an upper portion to a lower portion thereof.
- One of the first rod-shaped electrode 269 b and the second rod-shaped electrode 270 b is connected to a high-frequency power source 273 via an impedance matching unit 272 , and the other electrode is connected to a ground that has a reference electric potential.
- Plasma is generated in a plasma generating region 224 b between the first and second rod-shaped electrodes 269 b and 270 b by supplying high-frequency power between the first and second rod-shaped electrodes 269 b and 270 b from the high-frequency power source 273 via the impedance matching unit 272 .
- a first rod-shaped electrode 269 c serving as a first electrode and a second rod-shaped electrode 270 c serving as a second electrode, both of which are slender and long electrodes, are provided from the lower portion of the reaction pipe 203 to the upper portion thereof, in the direction in which the wafers 200 are stacked.
- the first rod-shaped electrode 269 c and the second rod-shaped electrode 270 c are disposed in parallel with the third nozzle 233 c .
- Each of the first rod-shaped electrode 269 b and the second rod-shaped electrode 270 b is covered with an electrode protection pipe 275 c which is configured to protect these electrodes from an upper portion to a lower portion thereof.
- One of the first rod-shaped electrode 269 c and the second rod-shaped electrode 270 c is connected to the high-frequency power source 273 via the impedance matching unit 272 , and the other electrode is connected to the ground that has the reference electric potential.
- Plasma is generated in a plasma generating region 224 c between the first and second rod-shaped electrodes 269 c and 270 c by supplying high-frequency power between the first and second rod-shaped electrodes 269 c and 270 c from the high-frequency power source 273 via the impedance matching unit 272 .
- a first plasma source is mainly configured as a plasma generator (plasma generation unit) by the first rod-shaped electrode 269 b , the second rod-shaped electrode 270 b , and the electrode protection pipe 275 b .
- the impedance matching unit 272 and the high-frequency power source 273 may further be included in the first plasma source.
- a second plasma source is mainly configured as a plasma generator (plasma generation unit) by the first rod-shaped electrode 269 c , the second rod-shaped electrode 270 c , and the electrode protection pipe 275 c .
- the impedance matching unit 272 and the high-frequency power source 273 may be further included in the second plasma source.
- Each of the first and second plasma sources may also act as an activating mechanism that activates a gas to a plasma state, as will be described below.
- a plurality of excitation units (two excitation units in the present embodiment) are installed.
- the plurality of the excitation units are disposed in a distributed fashion, similar to the buffer chambers 237 b and 237 c.
- the electrode protection pipe 275 b is configured such that the first and second rod-shaped electrodes 269 b and 270 b may be inserted into the buffer chamber 237 b in a state in which the first and second rod-shaped electrodes 269 b and 270 b are isolated from an atmosphere in the buffer chamber 237 b .
- the electrode protection pipe 275 c is configured such that the first and second rod-shaped electrodes 269 c and 270 c may be inserted into the buffer chamber 237 c in a state in which the first and second rod-shaped electrodes 269 c and 270 c are isolated from an atmosphere in the buffer chamber 237 c .
- the concentration of oxygen in the electrode protection pipes 275 b and 275 c is substantially the same as that of oxygen in the external air (the atmosphere)
- the first and second rod-shaped electrodes 269 b and 270 b inserted into the electrode protection pipe 275 b and the first and second rod-shaped electrodes 269 c and 270 c inserted into the electrode protection pipe 275 c are oxidized by heat from the heater 207 .
- the concentrations of the oxygen in the electrode protection pipes 275 b and 275 c are reduced by filling the insides of the electrode protection pipes 275 b and 275 c with an inert gas, e.g., nitrogen gas, or by purging the insides of the electrode protection pipes 275 b and 275 c with an inert gas, e.g., nitrogen gas, through an inert gas purging mechanism, thereby preventing oxidation of the first rod-shaped electrodes 269 b and 269 c or the second rod-shaped electrodes 270 b and 270 c.
- an inert gas e.g., nitrogen gas
- the exhaust port 231 a described above is installed at the reaction pipe 203 .
- the exhaust pipe 231 that exhausts the atmosphere in the process chamber 201 is connected to the exhaust port 231 a .
- a vacuum pump 246 which is a vacuum exhaust device is connected to the exhaust pipe 231 via a pressure sensor 245 which is a pressure detector (pressure detection unit) that detects pressure in the process chamber 201 and an auto pressure controller (APC) valve 244 which is a pressure adjustor (pressure adjustment unit).
- the APC valve 244 is configured to perform or suspend vacuum-exhaust in the process chamber 201 by opening/closing the APC valve 244 while the vacuum pump 246 is operated, and to adjust pressure in the process chamber 201 by controlling the degree of opening the APC valve 244 while the vacuum pump 246 is operated.
- An exhaust system mainly includes the exhaust pipe 231 , the APC valve 244 , and the pressure sensor 245 .
- the vacuum pump 246 may be further included in the exhaust system.
- the exhaust system is configured to perform vacuum-exhaust such that the pressure in the process chamber 210 may be equal to a predetermined pressure (degree of vacuum) by adjusting the degree of opening the APC valve 244 based on pressure information detected by the pressure sensor 245 while the vacuum pump 246 is operated.
- a seal cap 219 is installed as a furnace port lid that may air-tightly close a lower end aperture of the reaction pipe 203 .
- the seal cap 219 is configured to contact a lower end of the reaction pipe 203 in a vertical direction from a lower portion thereof.
- the seal cap 219 is formed of a metal, such as stainless steel, and has a disk shape.
- An O-ring 220 is installed as a seal member that contacts the lower end of the reaction pipe 203 on an upper surface of the seal cap 219 .
- a rotating mechanism 267 that rotates the boat 217 as a substrate retainer is installed at a side of the seal cap 219 opposite to the process chamber 201 .
- a rotation shaft 255 of the rotating mechanism 267 is connected to the boat 217 while passing through the seal cap 219 .
- the rotating mechanism 267 is configured to rotate the wafers 200 by rotating the boat 217 .
- the seal cap 219 is configured to be vertically moved upward/downward by a boat elevator 115 that is a lifting mechanism vertically installed outside the reaction pipe 203 .
- the boat elevator 115 is configured to load the boat 217 into or unload the boat 217 from the process chamber 201 by moving the seal cap 219 upward/downward. That is, the boat elevator 115 is configured as a transfer device (transfer mechanism) that transfers the boat 217 , i.e., the wafers 200 , inside or outside the process chamber 201 .
- the boat 217 serving as a substrate support is formed of a heat-resistant material, e.g., quartz or silicon carbide, and is configured to support the plurality of wafers 200 in multiple states in a state in which the wafers 200 are concentrically arranged in a horizontal posture.
- a heat-resistant material e.g., quartz or silicon carbide
- an insulating member 218 is formed of a heat-resistant material, e.g., quartz or silicon carbide, to prevent heat generated from the heater 207 from being transferred to the seal cap 219 .
- the insulating member 218 may include a plurality of insulating plates formed of a heat-resistant material, e.g., quartz or silicon carbide, and an insulating plate holder that supports the plurality of insulating plates in a multi-layered structure in a horizontal posture.
- a heat-resistant material e.g., quartz or silicon carbide
- a temperature sensor 263 is installed as a temperature detector.
- the temperature sensor 263 is configured to control an amount of current to be supplied to the heater 207 based on temperature information detected by the temperature sensor 263 , so that the temperature in the process chamber 201 may have a desired temperature distribution.
- the temperature sensor 263 has an L-shape similar to the first nozzle 233 a , and is installed along an inner wall of the reaction pipe 203 .
- a controller 121 which is a control unit (control member) is configured as a computer including a central processing unit (CPU) 121 a , a random access memory (RAM) 121 b , a memory device 121 c , and an input/output (I/O) port 121 d .
- the RAM 121 b , the memory device 121 c , and the I/O port 121 d are configured to exchange data with the CPU 121 a via an internal bus 212 e .
- An I/O device 122 configured, for example, as a touch panel is connected to the controller 121 .
- the memory device 121 c is configured, for example, as a flash memory, a hard disk drive (HDD), or the like.
- a control program for controlling an operation of the substrate processing apparatus or a process recipe instructing an order or conditions of processing a substrate which will be described below are stored to be readable.
- the program recipe is a combination of processes designed to obtain a desired result when operations of a substrate processing process, which will be described below, are performed by the controller 121 , and acts as a program.
- the RAM 221 b is configured as a work area for temporarily storing a program or data read by the CPU 221 a.
- the I/O port 121 d is connected to the MFCs 241 a , 241 b , 241 c , 241 d , 241 e , 241 f , 241 g , 241 h , 241 i , 241 j , 241 k , 241 l , 241 m , 241 n , 241 o , and 241 p , the valves 243 a , 243 b , 243 c , 243 d , 243 e , 243 f , 243 g , 243 h , 243 i , 243 j , 243 k , 243 l , 243 m , 243 n , 243 o , and 243 p , the pressure sensor 245 , the APC valve 244 , the vacuum pump 246 , the heater 207 , the temperature sensor 263 , the rotating mechanism 267
- the CPU 221 a is configured to read the process recipe from the memory device 121 c according to a manipulation command received via the I/O device 122 , and read and execute the control program from the memory device 121 c . Also, according to the read program recipe, the CPU 121 a controls flow rates of various gases via the MFCs 241 a , 241 b , 241 c , 241 d , 241 e , 241 f , 241 g , 241 h , 241 i , 241 j , 241 k , 241 l , 241 m , 241 n , 241 o , and 241 p ; controls opening/closing of the valves 243 a , 243 b , 243 c , 243 d , 243 e , 243 f , 243 g , 243 h , 243 i , 243 j , 243 k ,
- the controller 121 is not limited to a personal computer, and may be configured as a general-purpose computer.
- the controller 121 may be configured by preparing an external memory device 123 storing such programs, e.g., a magnetic disk (a magnetic tape, a flexible disk, a hard disk, etc.), an optical disc (a compact disc (CD), a digital versatile disc (DVD), etc.), a magneto-optical disc (MO), or a semiconductor memory (a universal serial bus (USB) memory, a memory card, etc.), and then installing the programs in a general-purpose computer using the external storage device 123 .
- a method of supplying a program to a computer is not limited to using the external memory device 123 .
- a communication unit e.g., the Internet or an exclusive line, may be used to supply a program to a computer without using the external memory device 123 .
- the memory device 121 c or the external memory device 123 may be configured as a non-transitory computer-readable recording medium.
- the storage device 121 c and the external storage device 123 may also be referred to together simply as a ‘recording medium.’ Also, when the term ‘recording medium’ is used in the present disclosure, it may be understood as a case in which only groups of the memory devices 121 c are included, a case in which only groups of the external memory devices 123 are included, or a case in which both groups of the memory devices 121 c and groups of the external memory devices 123 are used.
- the nitride film is formed on the substrate by performing a cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying a plasma-excited hydrogen-containing gas to the substrate.
- a cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying a plasma-excited hydrogen-containing gas to the substrate.
- FIG. 5 is a flowchart illustrating a method of forming a film according to the first embodiment of the present invention.
- FIG. 10 is a diagram illustrating timing of supplying a gas and plasma power in a film-forming sequence according to the first embodiment of the present invention.
- a silicon nitride (Si 3 N 4 ) film (hereinafter referred to simply as ‘SiN film’) is formed as an insulating film on a wafer 200 using a DCS gas as a source gas and NH 3 gas as a nitrogen-containing gas, and alternately and repeatedly performing a process of supplying the DCS gas to the wafer 200 in the process chamber 201 (DCS gas supply process) and a process of supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 (NH 3 gas supply process).
- DCS gas supply process DCS gas supply process
- NH 3 gas supply process plasma-excited NH 3 gas
- the inside of the process chamber 201 is purged using N 2 gas as a purge gas (first purging process) after the DCS gas is supplied into the process chamber 201 , and the inside of the process chamber 201 is purged with N 2 gas (second purging process) after NH 3 gas is supplied into the process chamber 201 .
- a process of plasma-exciting and supplying H 2 gas to the wafer 200 in the process chamber 201 is performed both after the DCS gas is supplied using H 2 gas as a modifying gas and before NH 3 gas is supplied, and after NH 3 gas is supplied and before DCS gas is supplied (first and second modifying processes).
- a SiN film is formed on the wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to the wafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 (NH 3 gas supply process), purging the process chamber 201 (second purging process), and supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 (second modifying process).
- DCS gas supply process DCS gas supply process
- purging the process chamber 201 first purging process
- purging the process chamber 201 second purging process
- wafer When the term ‘wafer’ is used in the present disclosure, it should be understood as either the wafer itself, or a stacked structure (assembly) including a wafer and a layer/film formed on the wafer (i.e., the wafer having the layer/film formed a surface thereof may also be referred to as the ‘wafer’). Also, when the expression ‘surface of the wafer’ is used in the present disclosure, it should be understood as either a surface (exposed surface) of the wafer itself or a surface of a layer/film formed on the wafer, i.e., an uppermost surface of the wafer as a stacked structure.
- the expression ‘specific gas is supplied to a wafer’ should be understood to mean that the specific gas is directly supplied to a surface (exposed surface) of the wafer or that the specific gas is supplied to a surface of a layer/film on the wafer, i.e., the uppermost surface of the wafer including a stacked structure.
- the expression ‘a layer (or film) is formed on the wafer’ should be understood to mean that the layer (or film) is directly formed on a surface (exposed surface) of the wafer itself or that the layer (or film) is formed on a layer/film on the wafer, i.e., on the uppermost surface of the wafer including the stacked structure.
- the term ‘substrate’ has the same meaning as the term ‘wafer.’
- the term ‘wafer’ in the above-described description may be interchangeable with the term ‘substrate.’
- the boat 217 supporting the plurality of wafers 200 is lifted by the boat elevator 115 to be loaded into the process chamber 201 (boat loading), as illustrated in FIG. 1 .
- the lower end of the reaction pipe 203 is air-tightly closed by the seal cap 219 via the 0-ring 220 .
- the inside of the process chamber 201 is vacuum-exhausted to have a desired pressure (degree of vacuum) by the vacuum pump 246 .
- the pressure in the process chamber 201 is measured by the pressure sensor 245 , and the APC valve 244 is feedback-controlled based on information regarding the measured pressure (pressure control).
- the vacuum pump 246 is kept operated at least until processing of the wafers 200 is completed.
- the inside of the process chamber 201 is heated to a desired temperature by the heater 207 . In this case, an amount of current supplied to the heater 207 is feedback-controlled based on temperature information detected by the temperature sensor 263 , so that the inside of the process chamber 201 may have a desired temperature distribution (temperature control).
- the heating of the inside of the process chamber 201 by the heater 207 is continuously performed at least until the processing of the wafers 200 is completed. Then, rotation of the boat 217 and the wafers 200 begins by the rotating mechanism 267 (wafer rotation). Also, the rotation of the boat 217 and the wafers 200 by the rotating mechanism 267 is continuously performed at least until the processing of the wafers 200 is completed. Thereafter, six steps described below are sequentially performed.
- DCS gas is supplied to the first gas supply pipe 232 a and N 2 gas is supplied to the first inert gas supply pipe 232 j by opening the valve 243 a of the first gas supply pipe 232 a and the valve 243 j of the first inert gas supply pipe 232 j .
- the DCS gas flows through the first gas supply pipe 232 a and the flow rate of the DCS gas is then adjusted by the MFC 241 a .
- the N 2 gas flows through the first inert gas supply pipe 232 j and the flow rate of the N 2 gas is then adjusted by the MFC 241 j .
- the DCS gas having the adjusted flow rate is mixed with the N 2 gas having the adjusted flow rate in the first gas supply pipe 232 a , and the mixed gas of the DCS gas and the N 2 gas is supplied into the heated and reduced-pressure process chamber 201 via the gas supply holes 248 a of the first nozzle 233 a and exhausted via the exhaust pipe 231 .
- the DCS gas is supplied to the wafer 200 (DCS gas supply process).
- N 2 gas is supplied into the second inert gas supply pipe 232 k , the third inert gas supply pipe 232 l , the fourth inert gas supply pipe 232 m , the fifth inert gas supply pipe 232 n , the sixth inert gas supply pipe 232 o , the seventh inert gas supply pipe 232 p , the eighth gas supply pipe 232 h , and the ninth gas supply pipe 232 i by opening the valves 243 k , 243 l , 243 m , 243 n , 243 o , 243 p , 243 h , and 243 i .
- the N 2 gas is supplied into the process chamber 201 via the second gas supply pipe 232 b , the third gas supply pipe 232 c , the fourth gas supply pipe 232 d , the fifth gas supply pipe 232 e , the sixth gas supply pipe 232 f , the seventh gas supply pipe 232 g , the eighth gas supply pipe 232 h , the ninth gas supply pipe 232 i , the second nozzle 233 b , the third nozzle 233 c , and the buffer chambers 237 b and 237 c , and is exhausted via the exhaust pipe 231 .
- the pressure in the process chamber 201 is maintained constant to be less than atmospheric pressure, e.g., to fall within a range from 10 to 1,000 Pa, by appropriately controlling the APC valve 244 .
- the flow rate of the DCS gas is controlled by the MFC 241 a , for example, to fall within a range of 100 to 2,000 sccm (0.01 to 2 slm).
- the flow rate of the N 2 gas is controlled by each of the MFCs 241 j , 241 k , 241 l , 241 m , 241 n , 241 o , 241 p , 241 h , and 241 i , for example, to fall within a range of 100 to 2,000 sccm (0.1 to 2 slm).
- a time period in which the DCS gas is supplied to the wafer 200 i.e., a gas supply time (irradiation time)
- the temperature of the heater 207 is set to generate a CVD reaction in the process chamber 201 under the pressure described above. That is, the temperature of the heater 207 is set in such a manner that the wafer 200 may have a temperature ranging from, for example, 300 to 650° C., preferably 300 to 600° C., and more preferably, 300 to 550° C.
- the temperature of the wafer 200 is less than 300° C., then it is difficult for the DCS gas to be decomposed on or adsorbed onto the wafer 200 , thereby reducing a film-forming speed. Also, if the temperature of the wafer 200 is less than 300° C., then even when the DCS gas is decomposed on or adsorbed onto the wafer 200 , the amount of decomposition or the amount of adsorption may vary according to a region in a plane of the wafer 200 or the position of the wafer 200 . Thus, the DCS gas is not evenly decomposed or adsorbed in the plane of the wafer 200 or between adjacent wafers 200 . Accordingly, the temperature of the wafer 200 may be set to be equal to or greater than 300° C.
- a vapor-phase reaction may prevail.
- film thickness uniformity is likely to be degraded, thereby preventing the film thickness uniformity from being controlled.
- the film thickness uniformity may be controlled not to be degraded and the vapor-phase reaction may be prevented from prevailing by controlling the temperature of the wafer 200 to be 600° C. or less.
- a surface reaction may prevail and the film thickness uniformity may thus be easily secured and controlled.
- the temperature of the wafer 200 may be set to 300 to 650° C., preferably to 300 to 600° C., and more preferably, to 300 to 550° C.
- the DCS gas is supplied into the process chamber 201 to form a silicon-containing layer on the wafer 200 (an underlying film formed on the wafer 200 ) to a thickness of less than one atomic layer to several atomic layers.
- the silicon-containing layer may include at least one of an adsorption layer of DCS gas and a silicon (Si) layer.
- the silicon-containing layer may preferably include silicon (Si) and chlorine (Cl).
- the silicon layer generally refers to all layers including continuous layers formed of silicon (Si), discontinuous layers formed of silicon (Si), or a silicon thin film formed by overlapping the continuous layers and the discontinuous layers.
- the continuous layers formed of silicon (Si) may also be referred to together as a silicon thin film.
- silicon (Si) used to form the silicon layer should be understood as including silicon (Si) from which a bond with chlorine (Cl) or hydrogen (H) is not completely separated.
- Examples of the adsorption layer of DCS gas include not only continuous chemical adsorption layers including gas molecules of DCS gas but also discontinuous chemical adsorption layers including gas molecules of DCS gas. That is, the adsorption layer of DCS gas includes a chemical adsorption layer formed of DCS molecules to a thickness of one or less than one molecular layer. Also, examples of DCS (SiH 2 Cl 2 ) molecules of the adsorption layer of DCS gas may include molecules, e.g., SiH x Cl y molecules, in which a bond between silicon (Si) and chlorine (Cl) or between silicon (Si) and hydrogen (H) is partially separated.
- examples of the adsorption layer of DCS gas include continuous or discontinuous chemical adsorption layers including SiH 2 Cl 2 molecules and/or SiH x Cl y molecules.
- a layer having a thickness of less than one atomic layer means a discontinuously formed atomic layer, and a layer having a thickness of one atomic layer means a continuously formed atomic layer.
- a layer having a thickness of less than one molecular layer means a discontinuously formed molecular layer, and a layer having a thickness of one molecular layer means a continuously formed molecular layer.
- Silicon (Si) is deposited on the wafer 200 to form a silicon layer on the wafer 200 under conditions in which DCS gas is self-decomposed (pyrolyzed), i.e., conditions causing a pyrolysis reaction of the DCS gas.
- the DCS gas is adsorbed onto the wafer 200 to form an adsorption layer of DCS gas on the wafer 200 under conditions in which DCS gas is not self-decomposed (pyrolyzed), i.e., conditions that do not cause a pyrolysis reaction of the DCS gas.
- a film-forming rate may be higher when the silicon layer is formed on the wafer 200 than when the adsorption layer of DCS gas is formed on the wafer 200 .
- the thickness of the silicon-containing layer formed on the wafer 200 exceeds a thickness of several atomic layers, then a desorption action of chlorine (Cl) does not have an effect on the entire silicon-containing layer in Step 3a which will be described below, a nitriding action or a desorption action of chlorine (Cl) does not have an effect on the entire silicon-containing layer in Step 4a which will be described below, and a desorption action of chlorine (Cl) does not have an effect on the entire silicon-containing layer in Step 6a which will be described below.
- the silicon-containing layer that may be formed on the wafer 200 may have a minimum thickness of less than one atomic layer.
- the silicon-containing layer may be set to have a thickness of less than one atomic layer to several atomic layers.
- the silicon-containing layer by controlling the silicon-containing layer to have a thickness not more than one atomic layer, i.e., a thickness of less than one atomic layer or of one atomic layer, the nitriding action or the desorption action of chlorine (Cl) in Steps 3a, 4a, and 6a (which will be described below) may be relatively increased, and a time required for the nitriding action or the desorption action of chlorine (Cl) in Steps 3a, 4a, and 6a may thus be reduced. Also, a time required to form the silicon-containing layer in Step 1a may be reduced. Accordingly, a process time required to perform each cycle may be reduced, and a process time required to perform a total of cycles may thus be reduced. That is, a film-forming rate may be increased. Also, film thickness uniformity may be controlled to be increased by controlling the silicon-containing layer to have a thickness of one atomic layer or less.
- a chlorosilane-based material e.g., monochlorosilane (SiH 3 Cl, abbreviated to MCS), hexachlorodisilane (Si 2 Cl 6 , abbreviated to HCD), tetrachlorosilane, i.e., silicon tetrachloride (SiCl 4 , abbreviated to STC), trichlorosilane (SiHCl 3 , abbreviated to TCS); an inorganic material, e.g., trisilane (Si 3 H 8 , abbreviated to TS), disilane (Si 2 H 6 , abbreviated to DS), monosilane (SiH 4 , abbreviated to MS); or an organic material, such as an aminosilane-based material, e.g., tetrakisdi
- a chlorosilane-based material including chlorine (Cl) is used
- a material having a composition formula having a small number of chlorine (Cl) atoms is preferably used.
- DCS or MCS may be used.
- a rare gas e.g., Ar gas, He gas, Ne gas, or Xe gas, may be used as the inert gas.
- the valve 243 a of the first gas supply pipe 232 a is closed to suspend supplying of the DCS gas.
- the inside of the process chamber 201 is exhausted via the vacuum pump 246 while the APC valve 244 of the exhaust pipe 231 is open, so as to exclude an unreacted or residual DCS gas remaining in the process chamber 201 after the silicon-containing layer is formed, from the process chamber 201 .
- the N 2 gas is continuously supplied as an inert gas into the process chamber 201 while the valves 243 j , 243 k , 243 l , 243 m , 243 n , 243 o , 243 p , 243 h , and 243 i are open.
- the N 2 gas acts as a purge gas to guarantee the excluding of the unreacted or residual DCS gas remaining in the process chamber 201 after the silicon-containing layer is formed, from the process chamber 201 (first purging process).
- the residual gas may not be completely excluded from the process chamber 201 and the inside of the process chamber 201 may not be completely purged.
- Step 3a performed thereafter may not be negatively influenced by the residual gas.
- the flow rate of the N 2 gas supplied into the process chamber 201 need not be high.
- the inside of the process chamber 201 may be purged by supplying an amount of N 2 gas that corresponds to the capacity of the reaction pipe 203 (or the process chamber 201 ) without causing negative influence in Step 3a.
- the inside of the process chamber 201 may not be completely purged to reduce a purging time, thereby improving the throughput. Also, unnecessary consumption of the N 2 gas may be suppressed.
- the temperature of the heater 207 is set such that the temperature of the wafer 200 may fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., similar to the temperature of the wafer 200 when the DCS gas is supplied thereto.
- the supply flow rate of the N 2 gas supplied as a purge gas via each inert gas supply system may range, for example, from 100 to 2,000 sccm (0.1 to 2 slm).
- a rare gas e.g., Ar gas, He gas, Ne gas, or Xe gas, may be used as the purge gas, instead of N 2 gas.
- H 2 gas is simultaneously excited into a plasma state by the two plasma generation units (excitation units) and the results of plasma-exciting H 2 gas are then simultaneously supplied into the process chamber 201 from the two plasma generation units (excitation units), thereby modifying the silicon-containing layer (first modifying process)
- H 2 gas is supplied into the fourth gas supply pipe 232 d by opening the valve 243 d of the fourth gas supply pipe 232 d .
- the H 2 gas flows through the fourth gas supply pipe 232 d and the flow rate of the H 2 gas is then adjusted by the MFC 241 d .
- the H 2 gas having the adjusted flow rate passes through the second gas supply pipe 232 b and is then supplied into the buffer chamber 237 b via the gas supply holes 248 b of the second nozzle 233 b .
- the H 2 gas supplied into the buffer chamber 237 b is excited to a plasma state by supplying high-frequency power between the first rod-shaped electrode 269 b and the second rod-shaped electrode 270 b from the high-frequency power source 273 via the impedance matching unit 272 , is supplied as an excited species, i.e., an active species of hydrogen (H 2 *) into the process chamber 201 via the gas supply holes 238 b , and is exhausted via the exhaust pipe 231 .
- the plasma-excited H 2 gas is supplied to the wafer 200 .
- N 2 gas is supplied into the fourth inert gas supply pipe 232 m by opening the valve 243 m .
- the N 2 gas is supplied into the process chamber 201 together with the H 2 gas, and is exhausted via the exhaust pipe 231 .
- H 2 gas is supplied into the fifth gas supply pipe 232 e by opening the valve 243 e of the fifth gas supply pipe 232 e .
- the H 2 gas flows through the fifth gas supply pipe 232 e and the flow rate of H 2 gas is adjusted by the MFC 241 e .
- the H 2 gas having the adjusted flow rate passes through the third gas supply pipe 232 c , and is then supplied into the buffer chamber 237 c via the gas supply holes 248 c of the third nozzle 233 c .
- the H 2 gas supplied into the buffer chamber 237 c is excited to a plasma state by supplying high-frequency power between the first rod-shaped electrode 269 c and the second rod-shaped electrode 270 c from the high-frequency power source 273 via the impedance matching unit 272 , is supplied as an excited species (H 2 *) into the process chamber 201 via the gas supply holes 238 c , and is exhausted via the exhaust pipe 231 .
- the plasma-excited H 2 gas is supplied to the wafer 200 .
- N 2 gas is supplied into the fifth inert gas supply pipe 232 n by opening the valve 243 n .
- the N 2 gas is supplied into the process chamber 201 together with the H 2 gas, and is exhausted via the exhaust pipe 231 .
- N 2 gas is supplied into the first inert gas supply pipe 232 j , the second inert gas supply pipe 232 k , the third inert gas supply pipe 232 l , the sixth inert gas supply pipe 232 o , the seventh inert gas supply pipe 232 p , the eighth gas supply pipe 232 h , and the ninth gas supply pipe 232 i by opening the valves 243 j , 243 k , 243 l , 243 o , 243 p , 243 h , and 243 i .
- the N 2 gas is supplied into the process chamber 201 via the first gas supply pipe 232 a , the second gas supply pipe 232 b , the third gas supply pipe 232 c , the sixth gas supply pipe 232 f , the seventh gas supply pipe 232 g , the eighth gas supply pipe 232 h , the ninth gas supply pipe 232 i , the first nozzle 233 a , the second nozzle 233 b , the third nozzle 233 c , and the buffer chambers 237 b and 237 c , and is exhausted via the exhaust pipe 231 .
- the pressure in the process chamber 201 is set, e.g., to fall within a range from 10 to 1,000 Pa, by appropriately controlling the APC valve 244 .
- the supply flow rate of the H 2 gas is adjusted by each of the MFCs 241 d and 241 e to range, for example, from 100 to 10,000 sccm (0.1 to 10 slm).
- the supply flow rate of the N 2 gas is adjusted by each of the MFCs 241 m , 241 n , 241 j , 241 k , 241 l , 241 o , 241 p , 241 h and 241 i to range, for example, from 100 to 2,000 sccm (0.1 to 2 slm).
- a time period in which the excited species obtained by plasma-exciting the H 2 gas are supplied to the wafer 200 i.e., a gas supply time (irradiation time) is set to range, for example, from 1 to 120 seconds.
- the temperature of the heater 207 may be preferably set to be the same as when the DCS gas is supplied in step 1a, that is, the temperature in the process chamber 201 in Steps 1a through 3a may be preferably maintained to be the same as when the DCS gas is supplied in step 1a.
- the temperature of the heater 207 may be preferably set so that the temperature of the wafer 200 , i.e., the temperature in the process chamber 201 , in Steps 1a through 3a may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, 300 to 550° C.
- the temperature of the heater 207 may be more preferably set so that the temperature in the process chamber 201 may be maintained constant as described above from Step 1a through Step 6a (which will be described below).
- the high-frequency power supplied between the first and second rod-shaped electrode 269 b and 270 b and between the first and second rod-shaped electrode 269 c and 270 c from the high-frequency power source 273 is set to, for example, fall within a range of 50 to 1,000 W.
- impurities contained in the silicon-containing layer e.g., hydrogen (H) or chlorine (Cl)
- H hydrogen
- chlorine (Cl) may be efficiently desorbed from the silicon-containing layer, thereby forming the silicon-containing layer having a very low concentration of impurities.
- the efficiency of a nitriding process in Step 4a which will be described below may be improved.
- the efficiency of the nitriding process in Step 4a may be improved by efficiently desorbing chlorine (Cl), which is a factor degrading the performance of the nitriding process, from the silicon-containing layer.
- a process of modifying the silicon-containing layer is performed as described above.
- the impurities, e.g., hydrogen (H) or chlorine (Cl) desorbed from the silicon-containing layer are exhausted outside the process chamber 201 via the exhaust pipe 231 .
- Step 3a by using the plurality of plasma generation units (excitation units), the supply rate of the excited species to the wafer 200 may be increased while reducing plasma outputs of respective plasma generation units (excitation units) by reducing the amounts of high-frequency power to be supplied to the plasma generation units (excitation units).
- the supply rate of the excited species to the wafer 200 may be increased while suppressing plasma damage to the wafer 200 or the silicon-containing layer.
- the supply rate of the excited species to the wafer 200 may be increased while suppressing plasma damage to the wafer 200 or the silicon-containing layer, the efficiency of removing impurities may be increased, and the concentration of impurities in the silicon-containing layer may be lowered.
- a process time may be reduced.
- the concentration of impurities in a plane of the wafer 200 may be uniformly lowered.
- the excited species may be more evenly supplied to all regions in the plane of the wafer 200 .
- the difference between the concentration of impurities near the circumference of the wafer 200 and the concentration of impurities at the center of the wafer 200 may be controlled not to be large.
- NH 3 gas is simultaneously excited to a plasma state by the two plasma generation units (excitation units) and the results of plasma-exciting the NH 3 gas are simultaneously supplied into the process chamber 201 from the two plasma generation units (excitation units), thereby nitriding the modified silicon-containing layer (NH 3 gas supply process).
- NH 3 is supplied into the second gas supply pipe 232 b by opening the valve 243 b of the second gas supply pipe 232 b .
- the NH 3 gas flows through the second gas supply pipe 232 b and the flow rate of the NH 3 gas is adjusted by the MFC 241 b .
- the NH 3 gas having the adjusted flow rate is supplied into the buffer chamber 237 b via the gas supply holes 248 b of the second nozzle 233 b .
- the NH 3 gas supplied into the buffer chamber 237 b is excited to a plasma state by supplying high-frequency power between the first rod-shaped electrode 269 b and the second rod-shaped electrode 270 b from the high-frequency power source 273 via the impedance matching unit 272 , is supplied as an excited species (NH 3 *) into the process chamber 201 via the gas supply holes 238 b , and is exhausted via the exhaust pipe 231 .
- the plasma-excited NH 3 gas is supplied to the wafer 200 .
- N 2 gas is supplied into the second inert gas supply pipe 232 k by opening the valve 243 k .
- the N 2 gas is supplied into the process chamber 201 together with the NH 3 gas, and is exhausted via the exhaust pipe 231 .
- NH 3 gas is supplied into the third gas supply pipe 232 c by opening the valve 243 c of the third gas supply pipe 232 c .
- the NH 3 gas flows through the third gas supply pipe 232 c and the flow rate of the NH 3 gas is adjusted by the MFC 241 c .
- the NH 3 gas having the adjusted flow rate is supplied into the buffer chamber 237 c via the gas supply holes 248 c of the third nozzle 233 c .
- the NH 3 gas supplied into the buffer chamber 237 c is excited to a plasma state by supplying high-frequency power between the first rod-shaped electrode 269 c and the second rod-shaped electrode 270 c from the high-frequency power source 273 via the impedance matching unit 272 , is supplied as an excited species (NH 3 *) into the process chamber 201 via the gas supply holes 238 c , and is exhausted via the exhaust pipe 231 .
- the plasma-excited NH 3 gas is supplied to the wafer 200 .
- N 2 gas is supplied into the third inert gas supply pipe 232 l by opening the valve 243 l .
- the N 2 gas is supplied into the process chamber 201 together with the NH 3 gas, and is exhausted via the exhaust pipe 231 .
- N 2 gas is supplied into the first inert gas supply pipe 232 j , the fourth inert gas supply pipe 232 m , the fifth inert gas supply pipe 232 n , the sixth inert gas supply pipe 232 o , the seventh inert gas supply pipe 232 p , the eighth gas supply pipe 232 h , and the ninth gas supply pipe 232 i by opening the valves 243 j , 243 m , 243 n , 243 o , 243 p , 243 h , and 243 i .
- the N 2 gas is supplied into the process chamber 201 via the first gas supply pipe 232 a , the fourth gas supply pipe 232 d , the fifth gas supply pipe 232 e , the sixth gas supply pipe 232 f , the seventh gas supply pipe 232 g , the eighth gas supply pipe 232 h , the ninth gas supply pipe 232 i , the first nozzle 233 a , the second nozzle 233 b , the third nozzle 233 c , and the buffer chambers 237 b and 237 c , and is exhausted via the exhaust pipe 231 .
- the pressure in the process chamber 201 is set, e.g., to fall within a range of 10 to 1,000 Pa, by appropriately controlling the APC valve 244 .
- the supply flow rate of the NH 3 gas is adjusted by each of the MFCs 241 b and 241 c to range, for example, from 1,000 to 10,000 sccm (1 to 10 slm).
- the supply flow rate of the N 2 gas is adjusted by each of the MFCs 241 k , 241 l , 241 j , 241 m , 241 n , 241 o , 241 p , 241 h , and 241 i to range, for example, from 100 to 2,000 sccm (0.1 to 2 slm).
- a time period in which the excited species obtained by plasma-exciting the NH 3 gas is supplied to the wafer 200 i.e., a gas supply time (irradiation time) is set to range, for example, from 1 to 120 seconds.
- the temperature of the heater 207 may be a temperature at which the silicon-containing layer is nitrided, and may be preferably set to be the same as when the DCS gas is supplied in step 1a, that is, the temperature in the process chamber 201 in Steps 1a through 4a may be preferably maintained to be the same.
- the temperature of the heater 207 may be preferably set so that the temperature of the wafer 200 , i.e., the temperature in the process chamber 201 , in Steps 1a through 4a may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, 300 to 550° C.
- the temperature of the heater 207 may be more preferably set so that the temperature in the process chamber 201 may be maintained to be the same from Step 1a through Step 6a (which will be described below), as described above.
- the high-frequency power supplied between the first and second rod-shaped electrode 269 b and 270 b and between the first and second rod-shaped electrode 269 c and 270 c from the high-frequency power source 273 is set, for example, to fall within a range of 50 to 1,000 W.
- the NH 3 gas may be thermally excited, i.e., activated by heat, and may then be supplied.
- the pressure in the process chamber 201 should be relatively high, for example, to fall within a range of 10 to 3,000 Pa, and the temperature of the wafer 200 should be 550° C. or higher so as to obtain a sufficient nitriding power.
- a sufficient nitriding power may be obtained even when the temperature in the process chamber 201 is, for example, 300° C. or higher.
- a sufficient nitriding power may be obtained even when the temperature in the process chamber 201 is set to room temperature.
- the temperature in the process chamber 201 is less than 150° C., reacted by-products, such as ammonium chloride (NH 4 Cl), are adhered into the process chamber 201 or onto the wafer 200 .
- the temperature in the process chamber 201 is preferably 150° C. or higher, and is set to be 300° C. or higher in the present embodiment.
- the silicon-containing layer is nitrided to be changed (modified) into a silicon nitride (Si 3 N 4 ) layer (hereinafter referred to simply as ‘SiN layer’).
- Step 4a by using a plurality of plasma generation units (excitation units), the supply rate of the excited species to the wafer 200 may be increased while reducing plasma outputs of the respective plasma generation units (excitation units) by reducing the amounts of high-frequency power supplied to each of the plasma generation units (excitation units).
- the supply rate of the excited species to the wafer 200 may be increased while suppressing plasma damage to the wafer 200 or the silicon-containing layer.
- the supply rate of the excited species to the wafer 200 may be increased while suppressing plasma damage to the wafer 200 or the silicon-containing layer, and the nitriding power may be increased to promote the nitriding of the silicon-containing layer.
- the efficiency of nitriding may be increased.
- the nitriding of the silicon-containing layer may saturate to be rapidly changed to a self-limiting state (nitrided state), thereby reducing a nitriding time.
- a process time may be reduced, and uniformity of the result of nitriding the silicon-containing layer in a plane of the wafer 200 may be improved.
- the excited species may be uniformly supplied to all regions in the plane of the wafer 200 .
- the difference between the degrees of nitriding performed near the circumference of the wafer 200 and at the center of the wafer 200 may be controlled not to be large.
- the plurality of plasma generation units may be used to increase the supply rate of the excited species to the wafer 200 while suppressing plasma damage to the wafer 200 or the silicon-containing layer, and chlorine (Cl) may be more effectively desorbed from the silicon-containing layer having a low concentration of chlorine (Cl), which is formed in Step 1a and from which impurities are removed in Step 3a. Therefore, a SiN layer having very low concentration of chlorine (Cl) may be formed. Also, the efficiency of nitriding the silicon-containing layer may be greatly improved by effectively desorbing chlorine (Cl) from the silicon-containing layer.
- the efficiency of the nitriding may be greatly improved by effectively desorbing chlorine (Cl), which is a factor degrading the performance of the nitriding process, from the silicon-containing layer.
- the chlorine (Cl) desorbed from the silicon-containing layer is exhausted from the process chamber 201 via the exhaust pipe 231 .
- Diazene (N 2 H 2 ) gas, hydrazine (N 2 H 4 ) gas, N 3 H 8 gas, or the like may be used as a nitrogen-containing gas, instead of NH 3 gas.
- an amine-based gas such as ethylamine or methylamine, may be used as the nitrogen-containing gas, instead of NH 3 gas.
- the supply of the NH 3 gas is suspended by closing the valve 243 b of the second gas supply pipe 232 b and the valve 243 c of the third gas supply pipe 232 c .
- the inside of the process chamber 201 is vacuum-exhausted by the vacuum pump 246 while the APC valve 244 of the exhaust pipe 231 is open, so as to exclude unreacted or residual NH 3 gas remaining in the process chamber 201 after the SiN layer is formed, from the process chamber 201 .
- the N 2 gas is continuously supplied as an inert gas into the process chamber 201 while the valves 243 k , 243 l , 243 j , 243 m , 243 n , 243 o , 243 p , 243 h , and 243 i are open.
- the N 2 gas acts as a purge gas to guarantee the exclusion of the unreacted or residual NH 3 gas remaining in the process chamber 201 after the SiN layer is formed, from the process chamber 201 (second purging process).
- the residual gas may not be completely excluded from the process chamber 201 and the inside of the process chamber 201 may not be completely purged.
- Step 6a performed thereafter may not be negatively influenced by the residual gas.
- the flow rate of the N 2 gas supplied into the process chamber 201 need not be high.
- the inside of the process chamber 201 may be purged by supplying an amount of N 2 gas that corresponds to the capacity of the reaction pipe 203 (or the process chamber 201 ) without causing negative influence in Step 6a.
- the inside of the process chamber 201 may not be completely purged to reduce a purging time, thereby improving the throughput. Also, unnecessary consumption of the N 2 gas may be suppressed.
- the temperature of the heater 207 is set such that the temperature of the wafer 200 may fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., similar to the temperature of the wafer 200 when the NH 3 gas is supplied thereto.
- the supply flow rate of the N 2 gas supplied as a purge gas via each inert gas supply system may range, for example, from 100 to 2,000 sccm (0.1 to 2 slm).
- a rare gas e.g., Ar gas, He gas, Ne gas, or Xe gas, may be used as the purge gas, instead of N 2 gas.
- H 2 gas is simultaneously excited to a plasma state by the two plasma generation units (excitation units) according to the same order and conditions as in Step 3a (first modifying process) described above, and the plasma-excited H 2 gas is simultaneously supplied into the process chamber 201 from the two plasma generation units (excitation units), thereby modifying the SiN layer (second modifying process).
- impurities contained in the SiN layer e.g., hydrogen (H) or chlorine (Cl)
- hydrogen or chlorine may be efficiently desorbed from the SiN layer. That is, hydrogen or chlorine may be more efficiently desorbed from the SiN layer having a low concentration of hydrogen/chlorine, which is formed by desorbing impurities therefrom in Steps 3a and 4a.
- the SiN layer having a very low concentration of impurities may be formed. Accordingly, the SiN layer is modified as described above.
- the impurities, e.g., hydrogen or chlorine, which are desorbed from the SiN layer are exhausted from the process chamber 201 via the exhaust pipe 231 .
- Step 6a by using a plurality of plasma generation units (excitation units), the supply rate of the excited species to the wafer 200 may be increased while reducing plasma outputs of respective plasma generation units (excitation units) by reducing the amounts of high-frequency power supplied to each of the plasma generation units (excitation units).
- the supply rate of the excited species to the wafer 200 may be increased while suppressing plasma damage to the wafer 200 or the SiN layer.
- the supply rate of the excited species to the wafer 200 may be increased while suppressing plasma damage to the wafer 200 or the SiN layer, the efficiency of removing impurities may be increased, and the concentration of impurities in the SiN layer may be lowered. As a result, a process time may be reduced. Also, the concentration of impurities in a plane of the wafer 200 may be uniformly lowered. In other words, the excited species may be more evenly supplied to all regions in the plane of the wafer 200 . For example, the difference between the concentration of impurities near the circumference of the wafer 200 and the concentration of impurities at the center of the wafer 200 may be controlled not to be large.
- a silicon nitride (Si 3 N 4 ) film (hereinafter referred to simply as ‘SiN film’) may be formed on the wafer 200 to a desired thickness by performing one cycle including Steps 1a through 6a described above a predetermined number of times, and preferably, several times.
- the expression ‘when the cycle described above is repeatedly performed, a specific gas is supplied to the wafer 200 in each step after the cycle is performed at least twice’ means ‘a specific gas is supplied to a layer formed on the wafer 200 , i.e., on the uppermost surface of the wafer 200 as a stacked structure.’
- the expression ‘a specific layer is formed on the wafer 200 ’ means ‘a specific layer is formed on a layer formed on the wafer 200 , i.e., on the uppermost surface of the wafer 200 as a stacked structure. This also applies to the other embodiments which will be described below.
- N 2 gas is supplied as an inert gas from each inert gas supply system into the process chamber 201 by opening the valves 243 j , 243 k , 243 l , 243 m , 243 n , 243 o , 243 p , 243 h , and 243 i , and is exhausted via the exhaust pipe 231 .
- the N 2 gas acts as a purge gas to purge the inside of the process chamber 201 with an inert gas, and the residual gas remaining in the process chamber 201 is thus removed (purged) from the process chamber 201 . Thereafter, an atmosphere in the process chamber 201 is replaced with the inert gas, and the pressure in the process chamber 201 is returned to a normal pressure (atmosphere pressure recovery).
- a silicon-containing layer may be efficiently nitrided at a low temperature by supplying an excited species, which is obtained by plasma-exciting NH 3 gas, to the silicon-containing layer, thereby forming a SiN film at a low temperature.
- impurities, such as hydrogen or chlorine, contained in the silicon-containing layer may be efficiently desorbed from the silicon-containing layer.
- a SiN film having a low concentration of impurities, i.e., having a high film density may be formed, and the resistance of the SiN film to hydrogen fluoride may be improved.
- the insulating properties of the SiN film may be improved.
- Step 3a impurities, such as hydrogen or chlorine, contained in a silicon-containing layer may be efficiently desorbed from the silicon-containing layer by supplying an excited species obtained by plasma-exciting H 2 gas to the silicon-containing layer.
- impurities such as hydrogen or chlorine
- a SiN film having a lower concentration of impurities i.e., having higher film density, may be formed at a low temperature, and the resistance of the SiN film to hydrogen fluoride may be greatly improved.
- the insulating properties of the SiN film may be greatly improved.
- Step 6a impurities, such as hydrogen or chlorine, contained in a SiN layer may be efficiently desorbed from the SiN layer by supplying an excited species, which is obtained by plasma-exciting H 2 gas, to the SiN layer.
- an excited species which is obtained by plasma-exciting H 2 gas
- a SiN film having a lower concentration of impurities i.e., having higher film density, may be formed at a low temperature, and the resistance of the SiN film to hydrogen fluoride may be greatly improved.
- the insulating properties of the SiN film may be greatly improved.
- the efficiency of the nitriding process performed in Step 4a may be improved by efficiently desorbing chlorine from the silicon-containing layer or the SiN layer.
- the efficiency of the nitriding process performed in Step 4a may be improved by efficiently desorbing chlorine, which is a factor degrading the performance of the nitriding process, from the silicon-containing layer or the SiN layer. Accordingly, a time needed to form the SiN film can be reduced, thereby increasing the yield.
- Steps 3a, 4a, and 6a by using a plurality of plasma generation units, the supply rate of an excited species to the wafer 200 may be increased while reducing plasma outputs of the respective plasma generation units (excitation units) by reducing the amounts of high-frequency power supplied to each of the plasma generation units (excitation units).
- the supply rate of an excited species to the wafer 200 may be increased while suppressing plasma damage to the wafer 200 , the silicon-containing layer, or the SiN layer.
- nitriding power may be increased, and nitriding of the silicon-containing layer may be promoted. That is, the efficiency of the nitriding may be increased.
- the nitriding of the silicon-containing layer may saturate to be rapidly changed to a self-limiting state (nitrided state), thereby reducing a nitriding time. As a result, a process time may be reduced.
- uniformity of the result of nitriding the silicon-containing layer in a plane of the wafer 200 may be improved. That is, the excited species may be uniformly supplied to all regions in the plane of the wafer 200 using the plasma generation units.
- the difference between the degrees of nitriding performed near the circumference of the wafer 200 and at the center of the wafer 200 may be controlled not to be large.
- chlorine may be further efficiently desorbed from the silicon-containing layer having a low concentration of chlorine, which is formed in Step 1a and from which impurities are removed in Step 3a.
- a SiN layer having very a low concentration of chlorine may be formed.
- the efficiency of nitriding the silicon-containing layer may be greatly improved by efficiently desorbing chlorine therefrom. That is, the efficiency of nitriding the silicon-containing layer may be greatly improved by efficiently desorbing chlorine, which is a factor degrading the nitriding, from the silicon-containing layer.
- the efficiency of removing impurities from the silicon-containing layer or the SiN layer may be greatly improved, and the concentration of impurities in the SiN film may be greatly lowered.
- the concentration of impurities in the SiN film in a plane of the wafer 200 may be improved. That is, an excited species may be greatly uniformly supplied to all regions in the plane of the wafer 200 using the plasma generation units. For example, the difference between the concentrations of impurities in the SiN film near the circumference of the wafer 200 and at the center of the wafer 200 may be controlled not to be large.
- a plasma output of the plasma generation unit should be increased to increase the supply rate of excited species to the wafer 200 .
- a range of plasmification becomes too large, even the wafer 200 may thus be exposed to plasma.
- serious damage may be caused to the wafer 200 or the SiN film formed on the wafer 200 .
- sputtering may occur on the wafer 200 or the periphery of the wafer 200 due to plasma, thereby causing particles to be generated or degrading the quality of the SiN film.
- the quality of the SiN film formed on the wafer 200 may be remarkably different near the circumference of the wafer 200 exposed to plasma than at the center of the wafer 200 that is not exposed to plasma.
- the supply rate of an excited species to the wafer 200 may be increased while reducing plasma outputs of the respective plasma generation units.
- the same effect as when a number of times of rotating the wafer 200 (rotation speed thereof) is increased during forming of a film may be achieved using the plasma generation units, and thickness uniformity of the SiN film in a plane of the wafer 200 may be improved.
- DCS gas, NH 3 gas, or H 2 gas is intermittently supplied while rotating the wafer 200 .
- a certain relationship is present between the number of times of rotating the wafer 200 and the thickness uniformity of the SiN film in a plane of the wafer 200 .
- the upper limit of the number of times of rotating the wafer 200 is limited due to a vibration-preventing effect of the wafer 200 .
- the number of times of rotating the wafer 200 cannot be set to be greater than 3 rpm.
- two plasma generation units are used, the same effect as when the number of times of rotating the wafer 200 doubles may be achieved, and the thickness uniformity of the SiN film in the plane of the wafer 200 may be improved. This effect is particularly effective when the SiN film is formed as a thin film having a thickness of, for example, 50 ⁇ or less.
- a SiN film having a very low concentration of impurities, such as hydrogen or chlorine, i.e., having very high film density may be formed at a low temperature, for example, 550° C. or less.
- impurities such as hydrogen or chlorine
- the resistance of the SiN film to hydrogen fluoride, and the insulating properties and quality of the SiN film may be improved.
- a time needed to nitride and process the silicon-containing layer may be reduced by increasing the efficiency of nitriding the silicon-containing layer while suppressing plasma damage to the wafer 200 , the silicon-containing layer, or the SiN layer, thereby increasing the throughput.
- the quality and thickness uniformity of the SiN film in a plane of the wafer 200 may be improved by removing impurities from the SiN film or uniformly improving the degree of nitriding the SiN film in the plane of the wafer 200 . Also, a probability that sterically hindered dangling bonds will occur during forming of a film may be reduced. Furthermore, natural oxidation of the SiN film may be suppressed due to a low concentration of chlorine in the SiN film, during transfer of the wafer 200 , e.g., boat unloading.
- a hydrogen-containing gas e.g., H 2 gas
- a hydrogen-containing gas e.g., H 2 gas
- a rare gas e.g., Ar gas or He gas
- N 2 gas may be used as a modifying gas in the second modifying process.
- a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to a substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
- a SiN film is formed on the wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to the wafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 (NH 3 gas supply process), purging the process chamber 201 (second purging process), and supplying at least one of plasma-excited N 2 gas and plasma-excited Ar gas to the wafer 200 in the process chamber 201 (second modifying process).
- DCS gas supply process DCS gas supply process
- purging the process chamber 201 first purging process
- FIG. 6 is a flowchart illustrating a method of forming a film according to the second embodiment of the present invention.
- FIG. 11 is a diagram illustrating timing of supplying a gas and plasma power according to the second embodiment of the present invention.
- FIGS. 6 and 11 illustrate cases in which H 2 gas is used as a modifying gas in a first modifying process, and Ar gas or N 2 gas is used as a modifying gas in a second modifying process.
- the film-forming sequence according to the present embodiment is the same as the film-forming sequence according to the first embodiment, except that Ar gas or N 2 gas is used as a modifying gas in the second modifying process.
- the second modifying process (Step 6b) according to the present embodiment that is different from that in the first embodiment is described below.
- the second modifying process if Ar gas is used as a modifying gas, then a SiN layer is performed on the wafer 200 by performing Steps 1b through 5b and residual gases remaining in the process chamber 201 are removed, similar to Steps 1a through 5a according to the first embodiment. Thereafter, the Ar gas is simultaneously excited to a plasma state by two plasma generation units (excitation units), and the plasma-excited Ar gas is simultaneously supplied into the process chamber 201 from the two plasma generation units (excitation units) to modify the SiN layer (second modifying process).
- Ar gas is supplied into the sixth gas supply pipe 232 f by opening the valve 243 f of the sixth gas supply pipe 232 f .
- the Ar gas flows through the sixth gas supply pipe 232 f , and the flow rate of the Ar gas is adjusted by the MFC 241 f .
- the Ar gas having the adjusted flow rate passes through the second gas supply pipe 232 b , and is then supplied into the buffer chamber 237 b via the gas supply holes 248 b of the second nozzle 233 b .
- the Ar gas supplied into the buffer chamber 237 b is plasma-excited as an excited species (Ar*) by supplying high-frequency power between the first and second rod-shaped electrodes 269 b and 270 b from the high-frequency power source 273 via the impedance matching unit 272 , and the excited species (Ar*) is supplied into the process chamber 201 via the gas supply holes 238 b and exhausted via the exhaust pipe 231 .
- the plasma-excited Ar gas is supplied to the wafer 200 .
- Ar gas is supplied into the seventh gas supply pipe 232 g by opening the valve 243 g of the seventh gas supply pipe 232 g .
- the Ar gas flows through the seventh gas supply pipe 232 g , and the flow rate of the Ar gas is adjusted by the MFC 241 g .
- the Ar gas having the adjusted flow rate passes through the third gas supply pipe 232 c , and is then supplied into the buffer chamber 237 c via the gas supply holes 248 c of the third nozzle 233 c .
- the Ar gas supplied into the buffer chamber 237 c is plasma-excited as an excited species (Ar*) by supplying high-frequency power between the first and second rod-shaped electrodes 269 c and 270 c from the high-frequency power source 273 via the impedance matching unit 272 , and the excited species (Ar*) is supplied into the process chamber 201 via the gas supply holes 238 c and exhausted via the exhaust pipe 231 .
- the plasma-excited Ar gas is supplied to the wafer 200 .
- N 2 gas is supplied into the first inert gas supply pipe 232 j by opening the valve 243 j .
- the N 2 gas is supplied into the process chamber 201 via the first gas supply pipe 232 a and the first nozzle 233 a , and is exhausted via the exhaust pipe 231 .
- the pressure in the process chamber 201 is controlled, e.g., to fall within a range of 10 to 1,000 Pa, by appropriately controlling the APC valve 244 .
- the supply flow rate of the Ar gas is controlled by each of the MFCs 241 f and 241 g , for example, to fall within a range of 100 to 10,000 sccm (0.1 to 10 slm).
- the supply flow rate of the N 2 gas is controlled by the MFC 241 j , for example, to fall within a range of 100 to 2,000 sccm (0.1 to 2 slm).
- a time period in which the excited species obtained by plasma-exciting the Ar gas is supplied to the wafer 200 is set to range, for example, from 1 to 120 seconds.
- the temperature of the heater 207 is set to be the same as when the DCS gas is supplied in Step 1b, that is, the temperature of the wafer 200 (or the temperature in the process chamber 201 ) in Steps 1b through 6b may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., as in the first embodiment.
- the high-frequency power supplied from the high-frequency power source 273 between the first and second rod-shaped electrodes 269 b and 270 b and between the first and second rod-shaped electrodes 269 c and 270 c is set, for example, to fall within a range of 50 to 1,000 W.
- a rare gas other than Ar gas e.g., He gas, Ne gas, or Xe gas
- Ar gas e.g., He gas, Ne gas, or Xe gas
- Ar gas is more preferably used.
- N 2 gas is used as a modifying gas
- a SiN layer is formed on the wafer 200 by performing Steps 1b through 5b, similar to Steps 1a through 5a according to the first embodiment, and residual gases remaining in the process chamber 201 are removed.
- the N 2 gas is simultaneously excited to a plasma state by two plasma generation units (excitation units), and the plasma-excited N 2 gas is simultaneously supplied into the process chamber 201 from the two plasma generation units (excitation units) to modify the SiN layer (second modifying process).
- N 2 gas is supplied into the eighth gas supply pipe 232 h by opening the valve 243 h of the eighth gas supply pipe 232 h .
- the N 2 gas flows through the eighth gas supply pipe, and the flow rate of the N 2 gas is adjusted by the MFC 241 h .
- the N 2 gas having the adjusted flow rate flows through the second gas supply pipe 232 b , and is then supplied into the buffer chamber 237 b via the gas supply holes 248 b of the second nozzle 233 b .
- the N 2 gas supplied into the buffer chamber 237 b is plasma-excited as an excited species (N 2 *) by supplying high-frequency power between the first and second rod-shaped electrodes 269 b and 270 b from the high-frequency power source 273 via the impedance matching unit 272 , and the excited species (Ar*) is supplied into the process chamber 201 via the gas supply holes 238 b and exhausted via the exhaust pipe 231 .
- the plasma-excited N 2 gas is supplied to the wafer 200 .
- N 2 gas is supplied into the ninth gas supply pipe 232 i by opening the valve 243 i of the ninth gas supply pipe 232 i .
- the N 2 gas flows through the ninth gas supply pipe 232 i , and the flow rate of the N 2 gas is adjusted by the MFC 241 g .
- the N 2 gas having the adjusted flow rate passes through the third gas supply pipe 232 c , and is then supplied into the buffer chamber 237 c via the gas supply holes 248 c of the third nozzle 233 c .
- the N 2 gas supplied into the buffer chamber 237 c is plasma-excited by supplying high-frequency power between the first and second rod-shaped electrodes 269 c and 270 c from the high-frequency power source 273 via the impedance matching unit 272 , and supplied as an excited species (N 2 *) into the process chamber 201 via the gas supply holes 238 c and then exhausted via the exhaust pipe 231 .
- the plasma-excited N 2 gas is supplied to the wafer 200 .
- N 2 gas is supplied into the first inert gas supply pipe 232 j by opening the valve 243 j .
- the N 2 gas is supplied into the process chamber 201 via the first gas supply pipe 232 a and the first nozzle 233 a , and is exhausted via the exhaust pipe 231 .
- the pressure in the process chamber 201 is controlled, e.g., to fall within a range of 10 to 1,000 Pa, by appropriately controlling the APC valve 244 .
- the supply flow rate of the N 2 gas is controlled by each of the MFCs 241 h and 241 i , for example, to fall within a range of 100 to 10,000 sccm (0.1 to 10 slm).
- the supply flow rate of the N 2 gas is controlled by the MFC 241 j , for example, to fall within a range of 100 to 2,000 sccm (0.1 to 2 slm).
- a time period in which the excited species obtained by plasma-exciting the N 2 gas is supplied to the wafer 200 is set to range, for example, from 1 to 120 seconds.
- the temperature of the heater 207 is set to be the same as when the DCS gas is supplied in Step 1b, that is, the temperature of the wafer 200 (or the temperature in the process chamber 201 ) in Steps 1b through 6b may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., as in the first embodiment.
- the high-frequency power supplied from the high-frequency power source 273 between the first and second rod-shaped electrodes 269 b and 270 b and between the first and second rod-shaped electrodes 269 c and 270 c is set, for example, to fall within a range of 50 to 1,000 W.
- Impurities may be removed from the SiN layer by performing the second modifying process (Step 6b) described above using Ar gas or N 2 gas as a modifying gas. Thereafter, a SiN film may be formed on the wafer 200 to a desired thickness by repeatedly performing one cycle including Steps 1b through 6b a predetermined number of times, and preferably, several times.
- Thickness uniformity of the SiN film in a plane of the wafer 200 may be more improved when Ar gas or N 2 gas is used as a modifying gas than when H 2 gas is used as a modifying gas. This seems to be because excited species obtained by plasma-exciting Ar gas or N 2 gas are heavier than those obtained by plasma-exciting H 2 gas, and the elements of the SiN film may thus be decomposed or desorbed near an edge portion of the wafer 200 at which a film is likely to have be thick, when Ar gas or N 2 gas is used as a modifying gas.
- an etching rate of the SiN film i.e., the quality of the SiN film, in a plane of the wafer 200 may be more improved when H 2 gas is used as a modifying gas than when Ar gas or N 2 gas is used as a modifying gas.
- an excited species obtained by plasma-exciting H 2 gas has a longer lifespan than excited species obtained by plasma-exciting Ar gas or N 2 gas.
- excited species may be more efficiently supplied to a central part of the wafer 200 when H 2 gas is used as a modifying gas.
- desorbing of impurities from a silicon-containing layer or the SiN layer at the central part of the wafer 200 may be greatly promoted.
- H 2 gas is used as a modifying gas in the first modifying process and Ar gas or N 2 gas is used as a modifying gas in the second modifying process.
- Ar gas or N 2 gas may be used as a modifying gas in the first modifying process
- H 2 gas may be used as a modifying gas in the second modifying process.
- the first and second modifying processes are not limited to a case in which H 2 gas, N 2 gas, or Ar gas is used as a modifying gas, and instead, an arbitrary combination of H 2 gas, N 2 gas, and Ar gas may be used as a modifying gas.
- a process of plasma-exciting and supplying a modifying gas is performed after a source gas is supplied and before a nitrogen-containing gas is supplied, and after a nitrogen-containing gas is supplied and before a source gas is supplied, but the present invention is not limited thereto.
- the process of plasma-exciting and supplying a modifying gas may be performed only after a source gas is supplied and before a nitrogen-containing gas is supplied. That is, although in the first embodiment, both the first and second modifying processes are performed, the present invention is not limited thereto, and only the first modifying process may be performed and the second modifying process may be skipped.
- a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, and supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate.
- a SiN film is formed on the wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to the wafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 (NH 3 gas supply process), and purging the process chamber 201 (second purging process).
- DCS gas supply process DCS gas supply process
- purging the process chamber 201 first purging process
- supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 first modifying process
- supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 NH 3 gas supply process
- second purging process chamber 201 second purging process.
- FIG. 7 is a flowchart illustrating a method of forming a film according to the third embodiment of the present invention.
- FIG. 12 is a diagram illustrating timing of supplying a gas and plasma power according to the third embodiment of the present invention.
- the present embodiment is substantially the same as the first embodiment, except that a process of plasma-exciting and supplying a modifying gas is performed only after a source gas is supplied and before a nitrogen-containing gas is supplied (that is, the second modifying process is skipped). As illustrated in FIGS.
- a SiN film may be formed on the wafer 200 to a desired thickness by performing one cycle a predetermined number of times, and preferably, several times, the cycle including Steps 1c through 5c, similar to Steps 1a through 5a in the first embodiment.
- a time needed to perform each cycle may be reduced by skipping the second modifying process, thereby increasing a film-forming rate.
- a process of plasma-exciting and supplying a modifying gas is performed after a source gas is supplied and before a nitrogen-containing gas is supplied, and after a nitrogen-containing gas and before a source gas is supplied, but the present invention is not limited thereto.
- the process of plasma-exciting and supplying a modifying gas may be performed only after a nitrogen-containing gas is supplied and before a source gas is supplied. That is, although in the first embodiment, both the first and second modifying processes are performed, the present invention is not limited thereto, and the first modifying process may be skipped and only the second modifying process may be performed.
- a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying a plasma-excited hydrogen-containing gas to the substrate.
- a SiN film is formed on the wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to the wafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 (NH 3 gas supply process), purging the process chamber 201 (second purging process), and supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 (second modifying process).
- DCS gas supply process DCS gas supply process
- purging the process chamber 201 first purging process
- supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 NH 3 gas supply process
- purging the process chamber 201 second purging process
- supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 (second modifying process the film-forming sequence according to the present embodiment is described in greater detail below.
- FIG. 8 is a flowchart illustrating a method of forming a film according to the fourth embodiment of the present invention.
- FIG. 13 is a diagram illustrating timing of supplying a gas and plasma power according to the fourth embodiment of the present invention.
- the present embodiment is substantially the same as the first embodiment, except that a process of plasma-exciting and supplying a modifying gas is performed only after a nitrogen-containing gas is supplied and before a source gas is supplied (that is, the first modifying process is skipped). As illustrated in FIGS.
- a SiN film may be formed on the wafer 200 to a desired thickness by performing one cycle a predetermined number of times, and preferably, several times, the cycle including Steps 1d through 5d, similar to Steps 1a, 2a, and 4a through 6a in the first embodiment.
- a time needed to perform each cycle may be reduced by skipping the first modifying process, thereby increasing a film-forming rate.
- the process of purging the process chamber 201 is provided between the process of supplying a nitrogen-containing gas (NH 3 gas supply process) and the process of plasma-exciting and supplying a modifying gas (second modifying process), but the present invention is not limited thereto.
- the second purging process may be skipped, and the NH 3 gas supply process and the second modifying process may be continuously performed.
- a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
- a SiN film is formed on the wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to the wafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201 (NH 3 gas supply process), and a process of supplying at least one of plasma-excited H 2 gas and plasma-excited Ar gas to the wafer 200 in the process chamber 201 (second modifying process).
- DCS gas supply process DCS gas supply process
- purging the process chamber 201 first purging process
- supplying plasma-excited H 2 gas to the wafer 200 in the process chamber 201 first modifying process
- NH 3 gas supply process supplying plasma-excited NH 3 gas to the wafer 200 in the process chamber 201
- second modifying process a process of supplying at least one
- FIG. 9 is a flowchart illustrating a method of forming a film according to the fifth embodiment of the present invention.
- FIG. 14 is a diagram illustrating timing of supplying a gas and plasma power according to the fifth embodiment of the present invention.
- the present embodiment is substantially the same as the second embodiment, except that the second purging process is skipped, and the NH 3 gas supply process and the second modifying process are continuously performed.
- a SiN film may be formed on the wafer 200 to a desired thickness by performing one cycle a predetermined number of times, and preferably, several times, the cycle including Steps 1e through 5e, similar to Steps 1b through 4b and 6b a in the second embodiment.
- a time needed to perform each cycle may be reduced by skipping the second purging process, thereby increasing a film-forming rate.
- the present invention may also be applied to a case in which MCS gas is used as a source gas.
- An amount of chlorine to be supplied into the process chamber 201 may be reduced using the MCS gas having a lower chlorine (Cl) content and a higher surface adsorption rate than the DCS gas as a source gas.
- an amount of chlorine bonded with a silicon-containing layer, i.e., Si—Cl bonds may be reduced to form a silicon-containing layer having a low concentration of chlorine.
- Step 4a a SiN layer having a low concentration of chlorine may be formed.
- a SiN film having a low concentration of impurities therein i.e., a SiN film having a high film density
- the resistance of the SiN film to hydrogen fluoride may be improved.
- the insulating properties of the SiN film may be improved.
- Si—H bonds included in the silicon-containing layer may be increased by reducing Si—Cl bonds included in the silicon-containing layer using the MCS gas as a source gas.
- a Si—Cl bond has higher bonding energy than a Si—H bond, and acts to hinder formation of a Si—N bond, i.e., nitriding of the silicon-containing layer, in Step 4a.
- the Si—H bond has lower bonding energy than the Si—Cl bond, and acts to promote formation of a Si—N bond, i.e., nitriding of the silicon-containing layer, in Step 4a.
- the MCS gas when used as a source gas to form a silicon-containing layer having a small number of Si—Cl bonds and a low concentration of chlorine, factors that hinder the nitriding of the silicon-containing layer may be reduced and the nitriding of the silicon-containing layer may be promoted in Step 4a. Also, when a number of Si—H bonds in the silicon-containing layer is increased, factors promoting the nitriding of the silicon-containing layer may increase and the nitriding of the silicon-containing layer may be promoted in Step 4a.
- the efficiency of the nitriding of the silicon-containing layer in Step 4a may be increased, and a time needed for the nitriding of the silicon-containing layer may be reduced, thereby reducing a process time. Accordingly, a time needed to form the SiN film may be reduced, thereby increasing the yield.
- a temperature adjustment mechanism that maintains stored MCS gas at a constant temperature, e.g., of about 30° C., may be installed either in an MCS gas source that supplies MCS gas to the first gas supply pipe 232 a or at an upstream side of the first gas supply pipe 232 a , i.e., a gas storage place or a cylinder cabinet, etc.
- MCS gas has a high decomposition rate and is likely to be decomposed at a temperature at which a general special high-pressure gas is stored.
- SiH 4 monosilane
- thickness uniformity of the SiN film may be degraded or the yield may become worse.
- the temperature at which MCS gas is stored is too low, the MCS gas is not easily vaporized and the supply flow rate of the MCS gas into the process chamber 201 may be reduced.
- the temperature adjustment mechanism may be installed to solve such problems.
- Step 1a when a source gas is supplied into the process chamber 201 (Step 1a), the source gas is supplied into the process chamber 201 by continuously exhausting the inside of the process chamber 201 while the APC valve 244 is open, but the present invention is not limited thereto. For example, as illustrated in FIG.
- a gas storage unit (or tank) 250 a may be installed at the first gas supply pipe 232 a at a downstream side of the valve 243 a , a high-pressure source gas collected in the gas storage unit 250 a may be supplied at once (to a pulse state) into the reduced-pressure process chamber 201 while the APC valve 244 is closed, and then the inside of the process chamber 201 which is in an increased pressure by the supply of the source gas may be maintained for a predetermined time.
- the source gas is collected in the gas storage unit 250 a by closing a valve 243 a ′ installed at the first gas supply pipe 232 a at a downstream side of the gas storage unit 250 a and opening the valve 243 a installed at an upstream side of the gas storage unit 250 a . Then, when a desired amount of the source gas having a specific pressure is collected in the gas storage unit 250 a , the valve 243 a installed at the upstream side of the gas storage unit 250 a is closed. In the gas storage unit 250 a , the source gas is collected such that pressure in the gas storage unit 250 a may be equal to or greater than, e.g., 20,000 Pa.
- the amount of the source gas collected in the gas storage unit 250 a may range, for example, from 100 to 1,000 cc. Also, an apparatus is configured such that a conductance between the gas storage unit 250 a and the process chamber 201 may be equal to or greater than 1.5 ⁇ 10 ⁇ 3 m 3 /s. When a ratio between the capacity of the process chamber 201 and the capacity of the gas storage unit 250 a therefor is considered, if the capacity of the process chamber 201 is, for example, 100 liters, then the capacity of the gas storage unit 250 a may be 100 to 300 cc and may be 1/1,000 to 3/1,000 of the capacity of the process chamber 201 .
- the inside of the gas storage unit 250 a is filled with the source gas
- the inside of the process chamber 201 is exhausted using the vacuum pump 246 such that pressure in the process chamber 201 may be less than or equal to 20 Pa.
- the APC valve 244 is closed to discontinue the exhausting of the process chamber 201 , and then the valve 243 a ′ of the first gas supply pipe 232 a is opened.
- the high-pressure source gas collected in the gas storage unit 250 a is supplied at once (to a pulse state) into the process chamber 201 .
- the pressure in the process chamber 201 sharply increases to, for example, 931 Pa (7 Torr). Then, an increased-pressure state in the process chamber 201 is maintained for a predetermined time, e.g., 1 to 10 seconds, and the wafer 200 is exposed to a high-pressure atmosphere of DCS gas so as to form a silicon-containing layer on the wafer 200 .
- the speed of the source gas ejected from the first nozzle 233 a into the process chamber 201 is accelerated, for example, up to the speed of sound (340 m/sec) due to the difference between pressures in the gas storage unit 250 a and the process chamber 201 , thereby increasing the speed of the source gas supplied to the wafer 200 to about several tens msec.
- the source gas is efficiently supplied to the entire wafer 200 including the central part of the wafer 200 .
- the thickness and quality of the SiN film in a plane of the wafer 200 may be uniformly improved.
- the method of supplying the source gas described above will be referred to as a ‘flash flow.’
- the present invention is not limited thereto.
- the present invention may also be applied to a case in which one plasma generation unit (excitation unit) is installed.
- the performance of a nitriding process or a modifying process in a plane of the wafer 200 may be greatly improved, and the quality and thickness of the SiN film in the plane of the wafer 200 may be more uniformly improved, as described above.
- the present invention may be applied to a case in which three or more plasma generation units (excitation units) are installed.
- the process of supplying a plasma-excited hydrogen-containing gas is performed during a specific time period after the process of supplying a source gas, i.e., while supply of a plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas, and the process of supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas is performed during a specific time period after the process of supplying a plasma-excited or thermally excited nitriding gas, i.e., while supply of a source gas is suspended after the process of supplying a plasma-excited or thermally excited nitriding gas, but the present invention is not limited thereto.
- the process of supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas may be performed during a specific time period after the process of supplying a source gas, i.e., while supply of a plasma-excited or thermally excited nitriding gas is suspended after the process of supplying a source gas
- the process of supplying a plasma-excited hydrogen-containing gas may be performed during a specific time period after the process of supplying a plasma-excited or thermally excited nitriding gas, i.e., while supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas.
- the process of supplying a plasma-excited hydrogen-containing gas is performed during the specific time period after the process of supplying the source gas or during the specific time period after the process of supplying the plasma-excited or thermally excited nitriding gas.
- the process of supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas may be performed during the specific time period after the process of supplying the source gas or during the specific time period after the process of supplying the plasma-excited or thermally excited nitriding gas, in which the process of supplying a plasma-excited hydrogen-containing gas is not performed.
- the process of supplying the plasma-excited hydrogen-containing gas may be performed while the supply of the plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas or while the supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas.
- the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed while the supply of the plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas or while the supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas, in which the process of supplying the plasma-excited hydrogen-containing gas is not performed.
- the process of supplying the plasma-excited hydrogen-containing gas is performed after the process of supplying the source gas and before the process of supplying the plasma-excited or thermally excited nitriding gas, and after the process of supplying the plasma-excited or thermally excited nitriding gas and before the process of supplying the source gas.
- the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed after the process of supplying the source gas and before the process of supplying the plasma-excited or thermally excited nitriding gas; and after the process of supplying the plasma-excited or thermally excited nitriding gas and before the process of supplying the source gas, in which the process of supplying the plasma-excited hydrogen-containing gas is not performed.
- a layer (silicon-containing layer) is formed on a substrate during the process of supplying the source gas, a first modifying process is performed to the layer during the process of supplying the plasma-excited hydrogen-containing gas, the layer to which the first modifying process is performed is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas, and a second modifying process is performed to the nitride layer during the process of supplying the at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas.
- a layer is formed on the substrate during the process of supplying the source gas, a first modifying process is performed to the layer during the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas, the layer to which the first modifying process is performed is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas, and a second modifying process is performed to the nitride layer during the process of supplying the plasma-excited hydrogen-containing gas.
- both the process of supplying the plasma-excited hydrogen-containing gas and the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed during a specific time period after the process of supplying the plasma-excited or thermally excited nitriding gas, i.e., while the supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas, i.e., after the process of supplying the plasma-excited or thermally excited nitriding gas and before the process of supplying the source gas.
- both the process of supplying the plasma-excited hydrogen-containing gas and the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed during a specific time period after the process of supplying the source gas, i.e., while the supply of the plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas, i.e., after the process of supplying the source and before the process of supplying the plasma-excited or thermally excited nitriding gas.
- a layer (silicon-containing layer) is formed on the substrate during the process of supplying the source gas, the layer is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas, the first modifying process is performed to the nitride layer during the process of supplying the plasma-excited hydrogen-containing gas, and the second modifying process is performed to the nitride layer during the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas.
- a layer is formed on the substrate during the process of supplying the source gas, the first modifying process is performed to the layer during the process of supplying the plasma-excited hydrogen-containing gas, the second modifying process is performed to the layer during the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas, and the layer to which the first and second modifying processes are performed is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas.
- the effects of the first and second modifying processes may be maximized.
- the SiN films formed according to the embodiments described above have a low concentration of chlorine therein and a high film density, and are highly resistant to hydrogen fluoride.
- the SiN films formed according to the embodiments described above may be preferably used as a gate insulating film, a capacitive insulating film, sidewall spacers, an etching stopper layer, or the like.
- the SiN film may be preferably used as a hard mask during a process of forming a silicon trench isolation (STI) layer.
- STI silicon trench isolation
- a method of forming a SiN film containing silicon (a semiconductor element) as a nitride film has been described above, but the present invention is not limited thereto.
- the present invention may also be applied to a case in which a metal nitride film including a metallic element, such as titanium (Ti), zirconium (Zr), hafnium (Hf), tantalum (Ta), aluminum (Al), or molybdenum (Mo), is formed.
- the present invention may also be applied to a case in which a titanium nitride (TiN) film is formed, a zirconium nitride (ZrN) film is formed, a hafnium nitride (HfN) film is formed, a tantalum nitride (TaN) film is formed, an aluminum nitride (AlN) film is formed, or a molybdenum nitride (MoN) film is formed.
- TiN titanium nitride
- ZrN zirconium nitride
- HfN hafnium nitride
- TaN tantalum nitride
- AlN aluminum nitride
- MoN molybdenum nitride
- such films may be formed using a material including metal elements as a source gas according to the same film-forming sequence as in the embodiments described above.
- a liquid source that is in a liquid state at normal temperature and pressure
- the liquid source is vaporized by a vaporizing system, such as a vaporizer or a bubbler, and is then supplied as the source gas.
- a vaporizing system such as a vaporizer or a bubbler
- nitrogen-containing gas and modifying gas as in the embodiments described above may be used.
- the same process conditions as in the embodiments described above may also be used.
- titanium tetrachloride TiCl 4
- TiCl 4 tetrakis(ethylmethylamino)titanium
- TEMAT tetrakis(dimethylamino)titanium
- TDMAT tetrakis(diethylamino)titanium
- TDEAT tetrakis(diethylamino)titanium
- zirconium tetrachloride ZrCl 4
- tetrakis(ethylmethylamino)zirconium Zr[N(C 2 H 5 (CH 3 )] 4 , abbreviated to TEMAZ
- tetrakis(dimethylamino)zirconium Zr[N(CH 3 ) 2 ] 4
- TDMAZ tetrakis(diethylamino)zirconium
- TDEAZ tetrakis(diethylamino)zirconium
- hafnium tetrachloride HfCl 4
- tetrakis(ethylmethylamino)hafnium Hf[N(C 2 H 5 (CH 3 )] 4 , abbreviated to TEMAH
- tetrakis(dimethylamino)hafnium Hf[N(CH 3 ) 2 ] 4
- TDMAH tetrakis(diethylamino)hafnium
- TDEAH tetrakis(diethylamino)hafnium
- tantalum pentachloride TaCl 5
- tantalum pentafluoride TaF 5
- pentaethoxy tantalum Ta(OC 2 H 5 ) 5
- PET pentaethoxy tantalum
- tert-butylimino tris(diethylamino)tantalum Ta(NC(CH 3 ) 3 )(N(C 2 H 5 ) 2 ) 3 , abbreviated to: TBTDET
- AlN film when an AlN film is formed, aluminum trichloride (AlCl 3 ), aluminum trifluoride (AlF 3 ), or trimethyl aluminum (Al(CH 3 ) 3 , abbreviated to: TMA) may be used as a source element.
- AlCl 3 aluminum trichloride
- AlF 3 aluminum trifluoride
- TMA trimethyl aluminum
- molybdenum pentachloride MoCl 5
- MoF 5 molybdenum pentafluoride
- the present invention may be applied not only a case in which a SiN film is formed but also a case in which a metal nitride film is formed. In this case, the same effects as in the embodiments described above may also be achieved. That is, the present invention may also be applied to formation of a nitride film including a specific element, such as a semiconductor element or a metal element.
- a thin film is formed using a batch-type substrate processing apparatus capable of processing a plurality of substrates at a time
- a thin film may be formed using a single-wafer type substrate processing apparatus capable of processing one or several substrates at a time.
- the present invention may also be realized by changing, for example, a program recipe of the existing substrate processing apparatus.
- a program recipe according to the present invention may be installed in the existing substrate processing apparatus via an electric communication line or a recording medium storing the program recipe according to the present invention, or the program recipe of the existing substrate processing apparatus may be replaced with the program recipe according to the present invention by manipulating an input/output device of the existing substrate processing apparatus.
- Example 1 of the present invention Sample 1 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the third embodiment (wherein only a first modifying process is performed and a second modifying process is skipped).
- DCS gas was used as a source gas
- NH 3 gas was used as a nitrogen-containing gas
- Ar gas was used as a modifying gas during the first modifying process.
- Example 2 Sample 2 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to a film-forming sequence as described with respect to the fourth embodiment (wherein the first modifying process is skipped and only the second modifying process is performed).
- DCS gas was used as a source gas
- NH 3 gas was used as a nitrogen-containing gas
- Ar gas was used as a modifying gas during the second modifying process.
- Sample 3 was obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence.
- the cycle included supplying DCS gas to the wafer, purging the process chamber, supplying plasma-excited NH 3 gas to the wafer in the process chamber, and purging the process chamber.
- FIG. 15A illustrates only one cycle of a sequence of supplying a gas during the forming of the SiN film to obtain each of Samples 1 to 3. All of Samples 1 to 3 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated in FIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow. The temperature of the wafer was set to 550° C. when the SiN film was formed. The other process conditions were set to be substantially the same as those in the embodiments described above.
- wet-etching rates (WERs) of the SiN films were measured.
- WERs wet-etching rates
- FIG. 15B is a graph illustrating results of measuring the WERs of the SiN films (Samples 1 to 3).
- a horizontal axis denotes Samples 1 to 3
- a vertical axis denotes the WERs thereof ( ⁇ /min).
- WER means an average of wet-etching rates in a plane of the wafer.
- the SiN film had low WERs and was highly resistant to hydrogen fluoride in Samples 1 and 2 (Example 1) to which a modifying process of supplying plasma-excited Ar gas to a silicon-containing layer or a SiN layer was performed, compared to in Sample 3 (Comparative Example) to which the modifying process was not performed.
- Samples 1 and 2 Example 1 to which a modifying process of supplying plasma-excited Ar gas to a silicon-containing layer or a SiN layer was performed
- Sample 3 Comparative Example
- Sample 1 obtained by performing only the first modifying process and skipping the second modifying process had a lower WER and a higher resistance to hydrogen fluoride than Sample 2 obtained by skipping the first modifying process and performing only the second modifying process.
- impurities, such as hydrogen or chlorine, in the silicon-containing layer are more efficiently desorbed from the silicon-containing layer through the first modifying process performed immediately after the silicon-containing layer is formed than through the second modifying process performed after the silicon-containing layer is modified into a SiN layer, due to desorbing reaction of DCS gas.
- Example 1 Samples 4 to 7 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the third embodiment (wherein only a first modifying process is performed and a second modifying process is skipped).
- DCS gas was used as a source gas
- NH 3 gas was used as a nitrogen-containing gas
- Ar gas was used as a modifying gas during the first modifying process.
- pressures in the process chamber during the first modifying process were sequentially set to 85 Pa, 44.5 Pa, 21.5 Pa, and 12 Pa.
- FIG. 16A illustrates only one cycle of a sequence of supplying a gas during the forming of the SiN film to obtain each of Samples 4 to 7. All Samples 4 to 7 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated in FIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow. The temperature of the wafer was set to 550° C. when the SiN film was formed. The other process conditions were set to be substantially the same as those in the embodiments described above.
- FIG. 16B is a graph illustrating a result of measuring the WERs of the SiN films (Samples 4 to 7).
- a horizontal axis denotes Samples 4 to 7
- a vertical axis denotes the WERs thereof ( ⁇ /min).
- WER means an average of the wet-etching rates in the plane of the wafer.
- FIG. 17A is a graph illustrating a result of measuring a range of the WERs of the SiN films (Samples 4 to 7) in a plane of a wafer according to Example 1 of the present invention.
- a horizontal axis denotes Samples 4 to 7
- a vertical axis denotes the WERs thereof ( ⁇ /min).
- WER means an average of the wet-etching rates in the plane of the wafer.
- the range of WERs in the plane of the wafer means the difference between a maximum WER and minimum WER in the plane of the wafer.
- FIG. 17B is a graph illustrating a result of measuring a distribution of the WERs of the SiN films (Samples 4 to 7) in a plane of a wafer according to Example 1 of the present invention.
- a horizontal axis denotes measurement positions in Samples 4 to 7
- a vertical axis denotes WERs thereof ( ⁇ /min).
- the WERs were measured along the diameter of the wafer.
- ‘0 mm’ means a result of measuring the distribution of WERs at a central portion of the wafer
- ‘ ⁇ 150 mm’ means a result of measuring the distribution of WERs at an edge portion of the wafer.
- Example 2 of the present invention Sample 1 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the third embodiment (wherein only a first modifying process is performed and a second modifying process is skipped).
- DCS gas was used as a source gas
- NH 3 gas was used as a nitrogen-containing gas
- Ar gas was used as a modifying gas during the first modifying process.
- Example 2 of the present invention Samples 2 to 4 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the first embodiment (wherein both a first modifying process and a second modifying process are performed using the same modifying gas).
- DCS gas was used as a source gas and NH 3 gas was used as a nitrogen-containing gas.
- Ar gas was used as a modifying gas during the first and second modifying processes to obtain Sample 2.
- H 2 gas was used as a modifying gas during the first and second modifying processes to obtain Sample 3.
- N 2 gas was used as a modifying gas during the first and second modifying processes to obtain Sample 4.
- Example 2 of the present invention Sample 5 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the second embodiment (wherein different kinds of modifying gases are used during a first modifying process and a second modifying process).
- DCS gas was used as a source gas and NH 3 gas was used as a nitrogen-containing gas.
- H 2 gas was used as a modifying gas during the first modifying process.
- N 2 gas was used as a modifying gas during the second modifying process.
- Sample 6 was obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence.
- the cycle includes supplying DCS gas, purging the process chamber, supplying plasma-excited NH 3 gas to the wafer in the process chamber, and purging the process chamber.
- FIG. 18A illustrates only one cycle included in a sequence of supplying a gas during the forming of the SiN film to obtain each of Samples 1 to 6. All of Samples 1 to 6 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated in FIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow. The temperature of the wafer was set to 550° C. when the SiN film was formed. The other process conditions were set to be substantially the same as those in the embodiments described above.
- FIG. 18B is a graph illustrating a result of measuring the WERs of the SiN films (Samples 1 to 5).
- a horizontal axis denotes Samples 1 to 5
- a vertical axis denotes the WERs thereof ( ⁇ /min).
- WER means an average of the WERs in the plane of the wafer.
- the results of measuring a WER of the SiN film (Sample 6) was the same as that of the SiN film (Sample 3) in Example 1 and is thus not illustrated here.
- FIG. 19A is a graph comparing results of measuring a range of WERs of the SiN films (Samples 1 to 6) in a plane of a wafer according to Example 2 of the present invention and the Comparative Example.
- a horizontal axis denotes Samples 1 to 6
- a vertical axis denotes the ranges of WERs thereof ( ⁇ /min) in the plane of the wafer.
- FIG. 19B is a graph illustrating a result of measuring distributions of WERs of the SiN films (Samples 1 to 5) in a plane of a wafer according to Example 2 of the present invention and the Comparative Example.
- a horizontal axis denotes measurement positions on Samples 1 to 5
- a horizontal axis denotes the WERs thereof ( ⁇ /min).
- the WERs were measured along the diameter of the wafer.
- ‘0 mm’ means a result of measuring the distribution of WERs at a central portion of the wafer
- ‘ ⁇ 150 mm’ means a result of measuring the distribution of WERs at an edge portion of the wafer.
- FIG. 20 is a graph illustrating results of measuring thickness uniformity of the SiN films (Samples 1 to 6) in a plane of the wafer.
- a horizontal axis denotes Samples 1 to 6
- a vertical axis denotes the thickness uniformity ( ⁇ %) of the SiN films (Samples 1 to 6) in the plane of the wafer.
- FIG. 20 shows that the smaller the number on the vertical axis, the higher the thickness uniformity of the SiN film.
- an excited species obtained by plasma-exciting H 2 gas has a longer lifespan than excited species obtained by plasma-exciting Ar gas or N 2 gas.
- an excited species may be more efficiently supplied to a central part of the wafer 200 when H 2 gas is used as a modifying gas.
- desorbing of impurities from the SiN film at the central part of the wafer 200 may be greatly promoted.
- thickness uniformity of the SiN film in the plane of the wafer was high in the case of Sample 2 obtained using Ar gas as a modifying gas during the first and second modifying processes or Sample 4 obtained using N 2 gas as a modifying gas during the first and second modifying processes.
- thickness uniformity of the SiN film in the plane of the wafer was low in the case of Sample 3 obtained using H 2 gas as a modifying gas during the first and second modifying processes.
- WERs i.e., film quality
- thickness of a SiN film in the plane of the wafer were uniformly improved when the SiN film was formed using H 2 gas as a modifying gas during the first modifying process and using N 2 gas as a modifying gas during the second modifying process, i.e., using H 2 gas as a modifying gas during one modifying process and using N 2 gas or Ar gas as a modifying gas during another modifying process.
- Example 3 of the present invention Samples 1 to 4 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the second embodiment (wherein different kinds of modifying gases are used during a first modifying process and a second modifying process).
- DCS gas was used as a source gas and NH 3 gas was used as a nitrogen-containing gas.
- H 2 gas was used as a modifying gas during the first modifying process.
- N 2 gas was used as a modifying gas during the second modifying process.
- Samples 1 to 4 were obtained by changing the durations of purging processes per cycle.
- Sample 1 was obtained by setting the durations of a first purging process and a second purging process included in each cycle to four seconds.
- Sample 2 was obtained by setting the durations of the first purging process and the second purging process included in each cycle to two seconds.
- Sample 3 was obtained by setting the durations of the first purging process and the second purging process included in each cycle to four seconds and two seconds, respectively.
- Sample 4 was obtained by setting the durations of the first purging process and the second purging process included in each cycle to two seconds and four seconds, respectively.
- Example 3 Sample 5 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the fifth embodiment (wherein a second purging process is skipped, and a process of supplying a nitrogen-containing gas and a second modifying process are continuously performed).
- DCS gas was used as a source gas and NH 3 gas was used as a nitrogen-containing gas.
- H 2 gas was used as a modifying gas during a first modifying process.
- N 2 gas was used as a modifying gas during the second modifying process.
- the duration of a first purging process included in each cycle was set to four seconds.
- FIG. 21A illustrates only one cycle of a sequence of supplying a gas during the forming of the SiN film to obtain each of Samples 1 to 5.
- each halftone part denotes the first or second purging process, in which a number means the duration of the first or second purging process.
- All Samples 1 to 5 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated in FIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow.
- the temperature of the wafer was set to 550° C. when the SiN film was formed.
- the other process conditions were set to be substantially the same as those in the embodiments described above.
- FIG. 21B is a graph illustrating a result of measuring ranges of WERs of the SiN films (Samples 1 to 5) in the plane of the wafer according to Example 3 of the present invention.
- a horizontal axis denotes Samples 1 to 5
- a vertical axis denotes the ranges of the WERs thereof ( ⁇ /min) in the plane of the wafer.
- FIG. 21C is a graph illustrating a result of measuring thickness uniformity of the SiN films (Samples 1 to 5) in the plane of the wafer according to Example 3 of the present invention.
- a horizontal axis denotes Samples 1 to 5
- a vertical axis denotes thickness uniformity ( ⁇ %) of the SiN films (Samples 1 to 5) in the plane of the wafer.
- FIG. 21C reveals that the less a value on the vertical axis, the higher the thickness uniformity of the SiN film.
- the reason for which the thickness uniformities of the SiN films in the plane of the wafer were lowered when the duration of the first purging process was insufficient seems to be that when the duration of the first purging process was insufficient, the first modifying process began while the DCS gas remained in the process chamber. That is, during the first modifying process, an excited species obtained by plasma-exciting H 2 gas may cause or promote the residual DCS gas remaining in the process chamber to be decomposed or adsorbed on an edge portion of the wafer.
- the reason for which the thickness uniformities of the SiN films in the plane of the wafer were not greatly lowered even when the duration of the second purging process was insufficient seems to be that even if the second modifying process begins while NH 3 gas remains in the process chamber, the NH 3 gas is hardly adsorbed onto the wafer. That is, even if during the second modifying process, an excited species obtained by plasma-exciting N 2 gas causes the NH 3 gas to be decomposed, the NH 3 gas is more likely to be desorbed from the wafer, rather than be adsorbed onto the wafer.
- Example 4 of the present invention Samples 1 to 5 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the fifth embodiment (wherein a second purging process is skipped, and a process of supplying a nitrogen-containing gas and a second modifying process are continuously performed).
- DCS gas was used as a source gas and NH 3 gas was used as a nitrogen-containing gas.
- H 2 gas was used as a modifying gas during a first modifying process.
- N 2 gas was used as a modifying gas during the second modifying process.
- the temperature of the wafer was sequentially set to 350° C., 400° C., 450° C., 500° C., and 550° C.
- the duration of a first purging process included in each cycle was set to four seconds.
- Samples 6 to 10 were obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence.
- the cycle included supplying DCS gas to the wafer, purging the process chamber, supplying plasma-excited NH 3 gas to the wafer in the process chamber, and purging the process chamber.
- the temperature of the wafer was sequentially set to 350° C., 400° C., 450° C., 500° C., and 550° C.
- Example 4 Samples 11 to 13 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the fifth embodiment (wherein a second purging process is skipped, and a process of supplying a nitrogen-containing gas and a second modifying process are continuously performed).
- MCS gas was used as a source gas and NH 3 gas was used as a nitrogen-containing gas.
- H 2 gas was used as a modifying gas during a first modifying process.
- N 2 gas was used as a modifying gas during the second modifying process.
- the temperature of the wafer was sequentially set to 400° C., 450° C., and 500° C.
- the duration of a first purging process included in each cycle was set to four seconds.
- Samples 14 to 16 were obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence.
- the cycle includes supplying MCS gas to the wafer, purging the process chamber, supplying plasma-excited NH 3 gas to the wafer in the process chamber, and purging the process chamber.
- the temperature of the wafer was sequentially set to 400° C., 450° C., and 500° C.
- Samples 1 to 16 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated in FIG. 3 , and a source gas (DCS gas or MCS gas) was supplied into the process chamber according to the flash flow.
- a source gas DCS gas or MCS gas
- the other process conditions were set to be substantially the same as those in the embodiments described above.
- FIG. 22A is a graph illustrating the relationship between the WER of each SiN film and a film-forming temperature according to Example 4 of the present invention.
- a horizontal axis denotes the film-forming temperature when each SiN film was formed
- a vertical axis denotes the WER ( ⁇ /min) of each SiN film.
- WER means an average of WERs in a plane of the wafer.
- FIG. 22A is a partially enlarged view of the graph of FIG. 22A , in which only a range of WERs that are less than or equal to 350 ( ⁇ /min) is shown.
- the SiN films (Samples 1 to 5) (Example 4) had low WERs and improved resistance to hydrogen fluoride, compared to the SiN films (Samples 6 to 10) (Comparative Example).
- impurities such as hydrogen or chlorine
- the SiN films (Samples 14 to 16) (Reference Example) had low WERs and improved resistance to hydrogen fluoride, compared to the SiN films (Samples 6 to 10) (Comparative Example). This seems to be because MCS gas having a lower chlorine content than DCS gas was used as a source gas, and thus the concentration of chlorine in the SiN films could be lowered, thereby improving the resistance of the SiN films to hydrogen fluoride.
- the SiN films (Samples 11 to 13) (Example 4) had lower WERs and more improved resistance to hydrogen fluoride than the SiN films (Samples 1 to 5) (Example 4).
- the resistance of the SiN films to hydrogen fluoride may be more improved using MCS gas as a source gas, and performing the modifying processes described above after the process of supplying the MCS gas and before the process of supplying the NH 3 gas and/or after the process of supplying NH 3 gas and before the process of supplying the MCS gas. Also, it could be seen that even if the durations of the modifying processes are shortened using the MCS gas as a source gas, a SiN film having a desirable quality may be formed, thereby greatly increasing the yield.
- a method of manufacturing a semiconductor device capable of forming a nitride film resistant to hydrogen fluoride at low temperatures a method of processing a substrate, a substrate processing apparatus, and a non-transitory computer-readable recording medium can be provided.
- a method of manufacturing a semiconductor device including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- the step (b) may be performed during one of a time period after the step (a) and a time period after the step (c), and
- the step (d) may be performed during one of the time period after the step (a) and the time period after the step (c) other than the time period where the step (b) is performed.
- the step (b) may be performed during one of a time period after the step (a) where a supply of the plasma-excited or thermally excited nitriding gas is suspended and a time period after the step (c) where a supply of the source gas is suspended, and
- the step (d) may be performed during one of the time period after the step (a) where the supply of the plasma-excited or thermally excited nitriding gas is suspended and the time period after the step (c) where the supply of the source gas is suspended other than the time period where the step (b) is performed.
- the step (b) may be performed during one of a time period after the step (a) and before the step (c) and a time period after the step (c) and before the step (a), and
- the step (d) may be performed during one of the time period after the step (a) and before the step (c) and the time period after the step (c) and before the step (a) other than the time period where the step (b) is performed.
- the step (b) may be performed during a time period after the step (a), and
- the step (d) may be performed during a time period after the step (c).
- the step (a) may include forming a layer on the substrate,
- the step (b) may include performing a first modifying process to the layer
- the step (c) may include changing the layer to which the first modifying process is performed into a nitride layer, and
- the step (d) may include performing a second modifying process to the nitride layer.
- the step (a) may include forming a layer on the substrate,
- the step (d) may include performing a first modifying process to the layer
- the step (c) may include changing the layer to which the first modifying process is performed into a nitride layer, and
- the step (b) may include performing a second modifying process to the nitride layer.
- the step (a) may include forming a layer on the substrate,
- the step (c) may include changing the layer into a nitride layer
- the step (b) may include performing a first modifying process to the nitride layer, and
- the step (d) may include performing a second modifying process to the nitride layer.
- the steps (a) through (d) may be performed in a state where the substrate is accommodated in a process chamber, the method further including a first purging process for purging the process chamber after the step (a), and a second purging process for purging the process chamber after the step (c).
- a duration of the first purging process may be set to be longer than a duration of the second purging process.
- step (b), the step (c) and the step (d) may be performed consecutively.
- the steps (a) through (d) may be performed while the substrate is accommodated in a process chamber, and
- step (b), the step (c) and the step (d) may be consecutively performed without purging the process chamber.
- the step (c) may include supplying the plasma-excited nitriding gas to the substrate.
- a method of manufacturing a semiconductor device including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- the step (b) may include supplying the plasma-excited hydrogen-containing gas excited by a plurality of excitation units to the substrate through each of the plurality of the excitation units.
- the step (d) may include supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas excited by a plurality of excitation units to the substrate through each of the plurality of the excitation units.
- the step (c) may include supplying the plasma-excited or thermally excited nitriding gas excited by a plurality of excitation units to the substrate through each of the plurality of the excitation units.
- a method of manufacturing a semiconductor device including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- the plurality of the excitation units may be disposed to be linearly symmetrical with respect to a straight line connecting a center of the substrate and a center of an exhaust port configured to exhaust a gas supplied into the process chamber.
- the plurality of the excitation units may be disposed to face one another via the center of the substrate,
- two excitation units may be disposed such that lines connecting the plurality of the excitation units and an exhaust port configured to exhaust a gas supplied into the process chamber form an isosceles triangle.
- the substrate may be rotated.
- the temperature of the substrate may be set to fall within a range of 300° C. to 650° C.
- the temperature of the substrate may be set to fall within a range of 300° C. to 600° C.
- the nitriding gas may include ammonia gas
- the hydrogen-containing gas may include hydrogen gas
- the rare gas may include at least one of argon gas and helium gas.
- the source gas may include a silane-based source gas.
- the source gas may include a chlorosilane-based source gas.
- the source gas may include at least one of dichlorosilane gas and monochlorosilane gas.
- a method of processing a substrate including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- a substrate processing apparatus including:
- a process chamber configured to accommodate a substrate
- a first gas supply system configured to supply a source gas to the substrate in the process chamber
- a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber
- a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber
- a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber
- an excitation unit configured to plasma-excite or thermally excite a gas
- control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a predetermined number of times, the cycle including:
- a program that causes a computer to perform a process of forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- a non-transitory computer-readable recording medium storing a program that causes a computer to perform a process of forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
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Abstract
Provided is a method of manufacturing a semiconductor device capable of forming a nitride layer having high resistance to hydrogen fluoride at low temperatures. The method includes forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas to the substrate, and supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
Description
- This U.S. non-provisional patent application claims priority under 35 U.S.C. §119 of Japanese Patent Application No. 2011-223134, filed on Oct. 7, 2011, and Japanese Patent Application No. 2012-181859, filed on Aug. 20, 2012, in the Japanese Patent Office, and is a divisional application of U.S. patent application Ser. No. 13/647,908 filed on Oct. 9, 2012, the entire contents of which are hereby incorporated by reference.
- 1. Field of the Invention
- The present invention relates to a method of manufacturing a semiconductor device, which includes a process of forming a thin film on a substrate, a method of processing a substrate, a substrate processing apparatus that may be used in the process of forming the thin film, and a non-transitory computer-readable recording medium.
- 2. Description of the Related Art
- A silicon nitride (SiN) film may be formed on a substrate, as one process of a method of manufacturing a semiconductor device, e.g., a large-scale integrated circuit (LSI), static random access memory (SRAM), dynamic random access memory (DRAM), etc. The silicon nitride (SiN) film may be formed by alternately and repeatedly performing a process of supplying, for example, a silicon-containing gas to a substrate in a process chamber and a process of supplying a plasma-excited nitrogen-containing gas to the substrate in the process chamber. The silicon nitride (SiN) film may be used, for example, as an etching stopper layer when a silicon oxide (SiO) film is etched using a solution containing hydrogen fluoride, during a process of manufacturing a semiconductor device.
- Recently, there is a growing need to lower a film-forming temperature of a silicon nitride (SiN) film when a semiconductor device is manufactured. However, when the film-forming temperature of the silicon nitride (SiN) film is low, the quality of the silicon nitride (SiN) film may be degraded, thereby increasing an etching rate with respect to a solution containing hydrogen fluoride.
- The present invention is directed to provide a method of manufacturing a semiconductor device capable of forming a nitride film resistant to hydrogen fluoride at low temperatures, a method of processing a substrate, a substrate processing apparatus, and a non-transitory computer-readable recording medium.
- According to one aspect of the present invention, there is provided a substrate processing apparatus comprising: a process chamber configured to accommodate a substrate; a first gas supply system configured to supply a source gas to the substrate in the process chamber; a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber; a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber; a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber; an excitation unit configured to plasma-excite or thermally excite a gas; and a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including: (a) supplying the source gas to the substrate in the process chamber; (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber; (c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and (d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate in the process chamber, wherein the step (b) is performed during a time period after the step (a) or a time period after the step (c), and the step (d) is performed during the time period after the step (a) or the time period after the step (c) other than the time period where the step (b) is performed.
- According to another aspect of the present invention, there is provided a substrate processing apparatus comprising: a process chamber configured to accommodate a substrate; a first gas supply system configured to supply a source gas to the substrate in the process chamber; a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber; a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber; a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber; an excitation unit configured to plasma-excite or thermally excite a gas; and a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including: (a) supplying the source gas to the substrate in the process chamber; (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber; (c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and (d) supplying a plasma-excited nitrogen gas or a plasma-excited rare gas to the substrate in the process chamber, wherein the step (a), the step (b), the step (c) and the step (d) in the cycle are performed in order.
- According to still another aspect of the present invention, there is provided a substrate processing apparatus comprising: a process chamber configured to accommodate a substrate; a first gas supply system configured to supply a source gas to the substrate in the process chamber; a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber; a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber; a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber; an excitation unit configured to plasma-excite or thermally excite a gas; and a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including: (a) supplying the source gas to the substrate in the process chamber; (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber; (c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and (d) supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas to the substrate in the process chamber, wherein the step (a), the step (d), the step (c) and the step (b) in the cycle are performed in order.
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FIG. 1 is a schematic configuration diagram of a vertical process furnace of a substrate processing apparatus according to an embodiment of the present invention, in which a vertical cross-sectional view of a portion of the vertical process furnace is provided. -
FIG. 2 is a schematic configuration diagram of the vertical process furnace of the substrate processing apparatus according to an embodiment of the present invention, in which a cross-sectional view taken along line A-A in the portion of the process furnace ofFIG. 1 is provided. -
FIG. 3 is a schematic configuration diagram of a vertical process furnace of a substrate processing apparatus according to a modified example of an embodiment of the present invention, in which a vertical cross-sectional view of a portion of the vertical process furnace is provided. -
FIG. 4 is a schematic configuration diagram of a controller included in a substrate processing apparatus according to an embodiment of the present invention. -
FIG. 5 is a flowchart illustrating a method of forming a film according to a first embodiment of the present invention. -
FIG. 6 is a flowchart illustrating a method of forming a film according to a second embodiment of the present invention. -
FIG. 7 is a flowchart illustrating a method of forming a film according to a third embodiment of the present invention. -
FIG. 8 is a flowchart illustrating a method of forming a film according to a fourth embodiment of the present invention. -
FIG. 9 is a flowchart illustrating a method of forming a film according to a fifth embodiment of the present invention. -
FIG. 10 is a diagram illustrating timing of supplying a gas and plasma power according to the first embodiment of the present invention. -
FIG. 11 is a diagram illustrating timing of supplying a gas and plasma power according to the second embodiment of the present invention. -
FIG. 12 is a diagram illustrating timing of supplying a gas and plasma power according to the third embodiment of the present invention. -
FIG. 13 is a diagram illustrating timing of supplying a gas and plasma power according to the fourth embodiment of the present invention. -
FIG. 14 is a diagram illustrating timing of supplying a gas and plasma power according to the fifth embodiment of the present invention. -
FIG. 15A is a diagram comparing sequences of supplying a gas during forming of a silicon nitride (SiN) film according to Example 1 of the present invention and a Comparative Example. -
FIG. 15B is a graph illustrating a result of measuring wet-etching rates (WERs) of SiN films according to Example 1 of the present invention and the Comparative Example. -
FIG. 16A illustrates a sequence of supplying a gas during forming of each of the SiN films according to Example 1 of the present invention. -
FIG. 16B is a graph illustrating a result of measuring the WERs of the SiN films according to Example 1 of the present invention. -
FIG. 17A is a graph illustrating a result of measuring a range of the WERs of the SiN films in a plane of a wafer according to Example 1 of the present invention. -
FIG. 17B is a graph illustrating a result of measuring a distribution of the WERs of the SiN films in the plane of the wafer according to Example 1 of the present invention. -
FIG. 18A is a diagram illustrating a sequence of supplying a gas during forming of each of SiN films according to Example 2 of the present invention and a Comparative Example. -
FIG. 18B is a graph illustrating a result of measuring the WERs of the SiN films according to Example 2 of the present invention. -
FIG. 19A is a graph illustrating a result of measuring a range of the WERs of the SiN films in the plane of the wafer according to Example 2 of the present invention and the Comparative Example. -
FIG. 19B is a graph illustrating a result of measuring a distribution of the WERs of the SiN films in the plane of the wafer according to Example 2 of the present invention and the Comparative Example. -
FIG. 20 is a graph illustrating the relationship between the thickness uniformity of the SiN films in a plane of a wafer and gas species used in a modifying process according to Example 2 of the present invention. -
FIG. 21A illustrates a sequence of supplying a gas during forming of each of SiN films according to Example 3 of the present invention. -
FIG. 21B is a graph illustrating a result of measuring a range of the WERs of the SiN films in the plane of the wafer according to Example 3 of the present invention. -
FIG. 21C is a graph illustrating a result of measuring the thickness uniformity of the SiN films in the plane of the wafer according to Example 3 of the present invention. -
FIG. 22A is a graph illustrating the relationship between the WER of a SiN film and a film-forming temperature according to Example 4 of the present invention. -
FIG. 22B is a partially enlarged view of the graph ofFIG. 22A . -
FIG. 23 is a graph illustrating the relationship between the WER of a SiN film and a film-forming temperature. - As described above, when a film-forming temperature of a silicon nitride (SiN) film is low, the quality of the silicon nitride (SiN) film may be degraded, thereby increasing an etching rate with respect to a solution containing hydrogen fluoride.
FIG. 23 is a graph illustrating the relationship between the wet-etching rate (WER) of a silicon nitride (SiN) film and a film-forming temperature. InFIG. 23 , a horizontal axis denotes a film-forming temperature when the silicon nitride (SiN) film was formed, and a vertical axis denotes a WER (Å/min) when the silicon nitride (SiN) film was etched using a solution containing hydrogen fluoride. Referring toFIG. 23 , the lower the film-forming temperature is, the higher the WER of the silicon nitride (SiN) film is. - Much research has been conducted on a method of forming a nitride film at low temperatures by, among others, the inventor of the present invention. As a result, it was concluded that a nitride film highly resistant to hydrogen fluoride may be formed at low temperatures by plasma-exciting and supplying a modifying gas including at least one element among hydrogen, nitrogen, and argon to a substrate in a process chamber either before a nitrogen-containing gas is supplied and after a source gas is supplied or before the source gas is supplied and after the nitrogen-containing gas is supplied, when the nitride film is formed on the substrate by alternately and repeatedly performing a process of supplying the source gas to the substrate accommodated in the process chamber and a process of supplying a plasma-excited nitrogen-containing gas to the substrate in the process chamber.
- The process of plasma-exciting and supplying the modifying gas may be performed only before the nitrogen-containing gas is supplied and after the source gas is supplied, may be performed only before the source gas is supplied and after the nitrogen-containing gas is supplied, and may be performed both before the nitrogen-containing gas is supplied and after the source gas is supplied, and before the source gas is supplied and after the nitrogen-containing gas is supplied.
- The present invention has been derived based on the results of the research conducted by the inventors. Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.
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FIG. 1 is a schematic configuration diagram of avertical process furnace 202 of a substrate processing apparatus according to an embodiment of the present invention, in which a vertical cross-sectional view of a portion of thevertical process furnace 202 is provided.FIG. 2 is a schematic configuration diagram of thevertical process furnace 202 of the substrate processing apparatus according to an embodiment of the present invention, in which a cross-sectional view taken along line A-A in the portion of theprocess furnace 202 ofFIG. 1 is provided. However, the present invention is not limited to the substrate processing apparatus according to the present embodiment and may also be applied to a substrate processing apparatus including a single-wafer type, a hot-wall type, or a cold-wall type process furnace. - As illustrated in
FIG. 1 , theprocess furnace 202 includes aheater 207 serving as a heating unit (heating mechanism). Theheater 207 has a cylindrical shape, and is vertically installed by being supported by a heater base (not shown) serving as a retaining plate. Also, theheater 207 acts as an activating mechanism that activates a gas with heat, as will be described below. - In the
heater 207, areaction pipe 203 forming a reaction container (process container) in a concentric shape with respect to theheater 207 is provided. Thereaction pipe 203 is formed of a heat-resistant material, e.g., quartz (SiO2) or silicon carbide (SiC), and has a cylindrical shape, an upper end of which is closed and a lower end of which is open. Aprocess chamber 201 is formed in a hollow tubular portion of thereaction pipe 203, and is configured such thatwafers 200 may be accommodated as substrates in a horizontal posture to be arranged in multiple stages in a vertical direction by means of aboat 217 which will be described below. - A
first nozzle 233 a serving as a first gas introduction port, asecond nozzle 233 b serving as a second gas introduction port, and athird nozzle 233 c serving as a third gas introduction port are installed in theprocess chamber 201 to pass through lower sidewalls of thereaction pipe 203. A firstgas supply pipe 232 a is connected to thefirst nozzle 233 a. A secondgas supply pipe 232 b, a fourthgas supply pipe 232 d, a sixthgas supply pipe 232 f, and an eighthgas supply pipe 232 h are connected to thesecond nozzle 233 b. A thirdgas supply pipe 232 c, a fifthgas supply pipe 232 e, a seventhgas supply pipe 232 g, and a ninthgas supply pipe 232 i are connected to thethird nozzle 233 c. As described above, the threenozzles gas supply pipes reaction pipe 203 so that a plurality of types of gases (five types of gases in the present embodiment) may be supplied into theprocess chamber 201. - Also, a manifold formed of metal may be installed below the
reaction pipe 203 to support thereaction pipe 203, and the first tothird nozzles 233 a through 233 c may be installed to pass through sidewalls of the manifold. In this case, anexhaust pipe 231 which will be described below may be further installed in the manifold. Alternatively, theexhaust pipe 231 may be installed below thereaction pipe 203 rather than in the manifold. As described above, a furnace port portion of theprocess furnace 202 may be formed of metal and nozzles may be installed at the furnace port portion formed of metal. - A mass flow controller (MFC) 241 a which is a flow rate control device (flow rate control unit) and a
valve 243 a which is a switch valve are sequentially installed at the firstgas supply pipe 232 a in an upstream direction. Also, a first inertgas supply pipe 232 j is connected to the firstgas supply pipe 232 a at a downstream side of thevalve 243 a. AnMFC 241 j which is a flow rate control device (flow rate control unit) and avalve 243 j which is a switch valve are sequentially installed at the first inertgas supply pipe 232 j in an upstream direction. Also, thefirst nozzle 233 a is connected to a front end of the firstgas supply pipe 232 a. Thefirst nozzle 233 a is installed in an arc-shaped space between inner walls of thereaction pipe 203 and thewafers 200 to move upward from lower inner walls of thereaction pipe 203 in a direction in which thewafers 200 are stacked. In other words, thefirst nozzle 233 a is installed along a wafer arrangement region in which thewafers 200 are arranged, in a region that horizontally surrounds the wafer arrangement region at sides of the wafer arrangement region. Thefirst nozzle 233 a is configured as an L-shaped long nozzle, and includes a horizontal portion passing through lower sidewalls of thereaction pipe 203 and a vertical portion vertically moving at least from one end of the wafer arrangement region toward the other end thereof. A plurality of gas supply holes 248 a are formed in a side surface of thefirst nozzle 233 a to supply a gas. The gas supply holes 248 a may be opened toward a center of thereaction pipe 203 to supply a gas toward thewafers 200. The gas supply holes 248 a are formed from a lower portion of thereaction pipe 203 to an upper portion thereof, and the gas supply holes 248 a each have the same opening area and are also provided at the same opening pitch. - An
MFC 241 b which is a flow rate control device (flow rate control unit) and avalve 243 b which is a switch valve are sequentially installed at the secondgas supply pipe 232 b in an upstream direction. A second inertgas supply pipe 232 k is connected to the secondgas supply pipe 232 b at a downstream side of thevalve 243 b. AnMFC 241 k which is a flow rate control device (flow rate control unit) and avalve 243 k which is a switch valve are sequentially installed at the second inert gas supply pipe 233 k in an upstream direction. Also, thesecond nozzle 233 b is connected to a front end of the secondgas supply pipe 232 b. Thesecond nozzle 233 b is installed in abuffer chamber 237 b which is a gas dispersion space. - The
buffer chamber 237 b is installed in the arc-shaped space between the inner walls of thereaction pipe 203 and thewafers 200 and at a portion covering from the lower inner walls of thereaction pipe 203 to upper inner walls thereof, in the direction in which thewafers 200 are stacked. In other words, thebuffer chamber 237 b is installed along the wafer arrangement region in which thewafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at the sides of the wafer arrangement region. A plurality of gas supply holes 238 b are formed at an end portion of a wall of thebuffer chamber 237 b adjacent to thewafers 200 so as to supply a gas. The gas supply holes 238 b may be opened toward the center of thereaction pipe 203 to supply a gas toward thewafers 200. The gas supply holes 238 b are formed from the lower portion of thereaction pipe 203 to the upper portion thereof, and each have the same opening area and are also provided at the same opening pitch. - The
second nozzle 233 b is installed at another end portion of thebuffer chamber 237 b opposite to the end portion in which the gas supply holes 238 b are formed, so as to move upward from the lower inner walls of thereaction pipe 203 in the direction in which thewafers 200 are stacked. In other words, thesecond nozzle 233 b is installed along the wafer arrangement region in which thewafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at the sides of the wafer arrangement region. Thesecond nozzle 233 b is configured as an L-shaped long nozzle, and includes a horizontal portion passing through the lower sidewalls of thereaction pipe 203 and a vertical portion vertically moving at least from one end of the wafer arrangement region toward the other end thereof. A plurality of gas supply holes 248 b are formed in a side surface of thesecond nozzle 233 b to supply a gas. The gas supply holes 248 b open toward the center of thebuffer chamber 237 b. The gas supply holes 248 b are formed from the lower portion of thereaction pipe 203 to the upper portion thereof, similar to the gas supply holes 238 b in thebuffer chamber 237 b. The gas supply holes 248 b may be formed to each have the same opening area at the same opening pitch from an upstream side (lower portion thereof) to a downstream side (upper portion thereof) when a difference between pressures in thebuffer chamber 237 b and theprocess chamber 201 is small. However, the opening areas of the gas supply holes 248 b may increase or the opening pitch between the gas supply holes 248 b may decrease from the upstream side (lower portion) thereof to the downstream side (upper portion) thereof when the difference between the pressures in thebuffer chamber 237 b and theprocess chamber 201 is large. - In the present embodiment, gases, the flow velocities of which are different and the flow rates of which are substantially the same, are ejected through each of the gas supply holes 248 b by adjusting the opening areas or the opening pitch of the gas supply holes 248 b of the
second nozzle 233 b from the upstream side to the downstream side as described above. Then, the gases ejected through the gas supply holes 248 b are introduced into thebuffer chamber 237 b, and then the different flow velocities of the gases are equalized in thebuffer chamber 237 b. In other words, the speeds of particles of the gases ejected through the gas supply holes 248 b of thesecond nozzle 233 b into thebuffer chamber 237 b are reduced in thebuffer chamber 237 b, and the gases are then ejected into theprocess chamber 201 through the gas supply holes 238 b of thebuffer chamber 237 b. Thus, when the gases ejected into thebuffer chamber 237 b through the gas supply holes 248 b of thesecond nozzle 233 b are ejected into theprocess chamber 201 through the gas supply holes 238 b of thebuffer chamber 237 b, the gases each have a uniform flow rate and flow velocity. - An
MFC 241 c which is a flow rate control device (flow rate control unit) and avalve 243 c which is a switch valve are sequentially installed at the thirdgas supply pipe 232 c in an upstream direction. A third inert gas supply pipe 232 l is connected to the thirdgas supply pipe 232 c at a downstream side of thevalve 243 c. An MFC 241 l which is a flow rate control device (flow rate control unit) and a valve 243 l which is a switch valve are sequentially installed at the third inert gas supply pipe 232 l in an upstream direction. Thethird nozzle 233 c is connected to a front end of the thirdgas supply pipe 232 c. Thethird nozzle 233 c is installed in abuffer chamber 237 c which is a gas dispersion space. - The
buffer chamber 237 c is installed in the arc-shaped space between the inner walls of thereaction pipe 203 and thewafers 200 and at the portion covering from the lower inner walls of thereaction pipe 203 to the upper inner walls thereof, in the direction in which thewafers 200 are stacked. In other words, thebuffer chamber 237 c is installed along the wafer arrangement region in which thewafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at the sides of the wafer arrangement region. A plurality of gas supply holes 238 c are formed at an end portion of a wall of thebuffer chamber 237 c adjacent to thewafers 200 so as to supply a gas. The gas supply holes 238 c open toward the center of thereaction pipe 203 to supply a gas toward thewafers 200. The gas supply holes 238 c are formed from the lower portion of thereaction pipe 203 to the upper portion thereof, and each have the same opening area and are also provided at the same opening pitch. - The
third nozzle 233 c is installed at another end portion of thebuffer chamber 237 c opposite to an end portion of thebuffer chamber 237 c in which the gas supply holes 238 c are formed so as to move upward from the lower inner walls of thereaction pipe 203, in the direction in which thewafers 200 are stacked. That is, thethird nozzle 233 c is installed along the wafer arrangement region in which thewafers 200 are arranged, in the region that horizontally surrounds the wafer arrangement region at sides of the wafer arrangement region. Thethird nozzle 233 c is configured as an L-shaped long nozzle, and includes a horizontal portion passing through the lower sidewalls of thereaction pipe 203, and a vertical portion vertically moving at least from one end of the wafer arrangement region toward another end thereof. A plurality of gas supply holes 248 c are formed in a side surface of thefirst nozzle 233 a to supply a gas. The gas supply holes 248 c open toward the center of the buffer chamber 237. The gas supply holes 248 c are formed from the lower portion of thereaction pipe 203 to the upper portion thereof, similar to the gas supply holes 238 c of the buffer chamber 237. The gas supply holes 248 c may be formed to each have the same opening area at the same opening pitch from an upstream side (lower portion thereof) to a downstream side (upper portion thereof) when a difference between pressures in the buffer chamber 237 and theprocess chamber 201 is small. However, the opening areas of the gas supply holes 248 c may increase or the opening pitch between the gas supply holes 248 c may decrease from the upstream side (lower portion) thereof to the downstream side (upper portion) thereof when the difference between the pressures in the buffer chamber 237 and theprocess chamber 201 is large. - In the present embodiment, gases, the flow velocities of which are different and the flow rates of which are substantially the same, are ejected through each of the gas supply holes 248 c by adjusting the opening areas or the opening pitch of the gas supply holes 248 c of the
third nozzle 233 c from the upstream side to the downstream side as described above. Then, the gases ejected through the gas supply holes 248 c are introduced into thebuffer chamber 237 c, and then the different flow velocities of the gases are equalized in thebuffer chamber 237 c. In other words, the speeds of particles of the gases ejected through the gas supply holes 248 c of thethird nozzle 233 c into thebuffer chamber 237 c are reduced in thebuffer chamber 237 c, and the gases are then ejected into theprocess chamber 201 through the gas supply holes 238 c of the buffer chamber 237. Thus, when the gases ejected into thebuffer chamber 237 c through the gas supply holes 248 c of thethird nozzle 233 c are ejected into theprocess chamber 201 through the gas supply holes 238 c of thebuffer chamber 237 c, the gases each have the same flow rate and flow velocity. - An
MFC 241 d which is a flow rate control device (flow rate control unit) and avalve 243 d which is a switch valve are sequentially installed at the fourthgas supply pipe 232 d in an upstream direction. A fourth inert gas supply pipe 232 m is connected to the fourthgas supply pipe 232 d at a downstream side of thevalve 243 d. An MFC 241 m which is a flow rate control device (flow rate control unit) and a valve 243 m which is a switch valve are sequentially installed at the fourth inert gas supply pipe 232 m in an upstream direction. A front end of the fourthgas supply pipe 232 d is connected to the secondgas supply pipe 232 b at a downstream side of thevalve 243 b. - An
MFC 241 e which is a flow rate control device (flow rate control unit) and avalve 243 e which is a switch valve are sequentially installed at the fifthgas supply pipe 232 e in an upstream direction. A fifth inertgas supply pipe 232 n is connected to the fifthgas supply pipe 232 e at a downstream side of thevalve 243 e. AnMFC 241 n which is a flow rate control device (flow rate control unit) and avalve 243 n which is a switch valve are sequentially installed at the fifth inertgas supply pipe 232 n in an upstream direction. A front end of the fifthgas supply pipe 232 e is connected to the thirdgas supply pipe 232 c at a downstream side of thevalve 243 c. - An
MFC 241 f which is a flow rate control device (flow rate control unit) and avalve 243 f which is a switch valve are sequentially installed at the sixthgas supply pipe 232 f in an upstream direction. A sixth inert gas supply pipe 232 o is connected to the sixthgas supply pipe 232 f at a downstream side of thevalve 243 f. AnMFC 2410 which is a flow rate control device (flow rate control unit) and a valve 243 o which is a switch valve are sequentially installed at the sixth inert gas supply pipe 232 o in an upstream direction. A front end of the sixthgas supply pipe 232 f is connected to the secondgas supply pipe 232 b at a downstream side of thevalve 243 b. - An
MFC 241 g which is a flow rate control device (flow rate control unit) and avalve 243 g which is a switch valve are sequentially installed at the seventhgas supply pipe 232 g in an upstream direction. A seventh inertgas supply pipe 232 p is connected to the seventhgas supply pipe 232 g at a downstream side of thevalve 243 g. AnMFC 241 p which is a flow rate control device (flow rate control unit) and avalve 243 p which is a switch valve are sequentially installed at the seventh inertgas supply pipe 232 p in an upstream direction. A front end of the seventhgas supply pipe 232 g is connected to the thirdgas supply pipe 232 c at a downstream side of thevalve 243 c. - An
MFC 241 h which is a flow rate control device (flow rate control unit) and avalve 243 h which is a switch valve are sequentially installed at the eighthgas supply pipe 232 h in an upstream direction. A front end of the eighthgas supply pipe 232 h is connected to the secondgas supply pipe 232 b at a downstream side of thevalve 243 b. - An MFC 241 i which is a flow rate control device (flow rate control unit) and a valve 243 i which is a switch valve are sequentially installed at the ninth
gas supply pipe 232 i in an upstream direction. A front end of the ninthgas supply pipe 232 i is connected to the thirdgas supply pipe 232 c at a downstream side of thevalve 243 c. - As described above, in a method of supplying a gas according to the present embodiment, a main flow of a gas within the
reaction pipe 203 is controlled to be parallel to, i.e., to be horizontal with respect to, a surface of each of thewafers 200 by carrying the gas via thenozzles buffer chambers reaction pipe 203 and ends of a plurality of stackedwafers 200, and then first ejecting the gas into thereaction pipe 203 near thewafers 200 through the gas supply holes 248 a, 248 b, 248 c, 283 b and 238 c which are formed in thenozzles buffer chambers wafers 200, thereby uniformizing the thickness of a thin film to be formed on each of thewafers 200. Also, a residual gas remaining after a reaction flows toward theexhaust pipe 231, i.e., in the direction of theexhaust pipe 231 which will be described below, but a flowing direction of the residual gas may be appropriately defined by a location of the exhaust port and is not limited to the vertical direction. - The two
buffer chambers wafers 200, i.e., the center of thereaction pipe 203. Specifically, as illustrated inFIG. 2 , the twobuffer chambers wafers 200 and the center of theexhaust port 231 a (which will be described below) installed at a sidewall of thereaction pipe 203, as seen from a plan view. Also, the twobuffer chambers buffer chamber 237 b, the gas supply holes 238 c of thebuffer chamber 237 c, and the center of theexhaust port 231 a may form an isosceles triangle. Accordingly, the flow of a gas to thewafers 200 from the twobuffer chambers wafers 20 from the twobuffer chambers wafers 200 and the center of theexhaust port 231 a. - Through the first
gas supply pipe 232 a, for example, dichlorosilane (SiH2Cl2, abbreviated to ‘DCS’) gas is supplied as a source gas containing a specific element, e.g., silicon (Si) (a silicon-containing gas), into theprocess chamber 201 via theMFC 241 a, thevalve 243 a, and thefirst nozzle 233 a. At the same time, through the first inertgas supply pipe 232 j, an inert gas may be supplied into the firstgas supply pipe 232 a via theMFC 241 j and thevalve 243 j. - Through the second
gas supply pipe 232 b, for example, ammonia (NH3) gas is supplied as a gas containing nitrogen (a nitrogen-containing gas), i.e., a nitriding gas, into theprocess chamber 201 via theMFC 241 b, thevalve 243 b, thesecond nozzle 233 b, and thebuffer chamber 237 b. At the same time, through the second inertgas supply pipe 232 k, an inert gas may be supplied into the secondgas supply pipe 232 b via theMFC 241 k and thevalve 243 k. - Through the third
gas supply pipe 232 c, for example, ammonia (NH3) gas is supplied as a gas containing nitrogen (a nitrogen-containing gas), i.e., a nitriding gas, into theprocess chamber 201 via theMFC 241 c, thevalve 243 c, thethird nozzle 233 c, and thebuffer chamber 237 c. At the same time, an inert gas may be supplied into the thirdgas supply pipe 232 c through the third inert gas supply pipe 232 l via the MFC 241 l and the valve 243 l. - Through the fourth
gas supply pipe 232 d, for example, hydrogen (H2) gas is supplied as a gas containing hydrogen which is a modifying gas (a hydrogen-containing gas), i.e., a reducing gas, into theprocess chamber 201 via theMFC 241 d, thevalve 243 d, the secondgas supply pipe 232 b, thesecond nozzle 233 b, and thebuffer chamber 237 b. At the same time, an inert gas may be supplied into the fourthgas supply pipe 232 d through the fourth inert gas supply pipe 232 m via the MFC 241 m and the valve 243 m. - Through the fifth
gas supply pipe 232 e, for example, hydrogen (H2) gas is supplied as a gas containing hydrogen which is a modifying gas (a hydrogen-containing gas), i.e., a reducing gas, into theprocess chamber 201 via theMFC 241 e, thevalve 243 e, the thirdgas supply pipe 232 c, thethird nozzle 233 c, and thebuffer chamber 237 c. At the same time, an inert gas may be supplied into the fifthgas supply pipe 232 e through the fifth inertgas supply pipe 232 n via theMFC 241 n and thevalve 243 n. - Through the sixth
gas supply pipe 232 f, for example, argon (Ar) gas is supplied as a rare gas which is a modifying gas into theprocess chamber 201 via theMFC 241 f, thevalve 243 f, the secondgas supply pipe 232 b, thesecond nozzle 233 b, and thebuffer chamber 237 b. At the same time, an inert gas may be supplied into the sixthgas supply pipe 232 f through the sixth inert gas supply pipe 232 o via theMFC 2410 and the valve 243 o. - Through the seventh
gas supply pipe 232 e, for example, argon (Ar) gas is supplied as a rare gas which is a modifying gas into theprocess chamber 201 via theMFC 241 g, thevalve 243 g, the thirdgas supply pipe 232 c, thethird nozzle 233 c, and thebuffer chamber 237 c. At the same time, an inert gas may be supplied into the seventh gas supply pipe 232 through the seventh inertgas supply pipe 232 p via theMFC 241 p and thevalve 243 p. - Through the eighth
gas supply pipe 232 h, for example, nitrogen (N2) is supplied as a modifying gas into theprocess chamber 201 via theMFC 241 h, thevalve 243 h, the secondgas supply pipe 232 b, thesecond nozzle 233 b, and thebuffer chamber 237 b. - Through the ninth
gas supply pipe 232 i, for example, nitrogen (N2) gas is supplied as a modifying gas into theprocess chamber 201 via the MFC 241 i, the valve 243 i, the thirdgas supply pipe 232 c, thethird nozzle 233 c, and thebuffer chamber 237 c. - When a gas is supplied via the first
gas supply pipe 232 a as described above, a first gas supply system (source gas supply system) which supplies a source gas (DCS gas) to thewafers 200 in theprocess chamber 201, i.e., a silicon-containing gas supply system (DCS gas supply system), mainly includes the firstgas supply pipe 232 a, theMFC 241 a, and thevalve 243 a. Thefirst nozzle 233 a may be further included in the first gas supply system. A first inert gas supply system mainly includes the first inertgas supply pipe 232 j, theMFC 241 j, and thevalve 243 j. The first inert gas supply system may also act as a purge gas supply system. - When a gas is supplied via the second
gas supply pipe 232 b and the thirdgas supply pipe 232 c as described above, a second gas supply system (nitriding gas supply system) which supplies a nitriding gas (NH3 gas) to thewafers 200 in theprocess chamber 201, i.e., a nitrogen-containing gas supply system (an NH3 gas supply system), mainly includes the secondgas supply pipe 232 b, the thirdgas supply pipe 232 c, theMFCs valves second nozzle 233 b, thethird nozzle 233 c, and thebuffer chambers gas supply pipe 232 k, the third inert gas supply pipe 232 l, theMFCs 241 k and 241 l, and thevalves 243 k and 243 l. The second inert gas supply system also acts as a purge gas supply system. - When a gas is supplied via the fourth
gas supply pipe 232 d and the fifthgas supply pipe 232 e as described above, a third gas supply system (reducing gas supply system) which supplies a hydrogen-containing gas (H2 gas) to thewafers 200 in theprocess chamber 201, i.e., a hydrogen-containing gas supply system (a H2 gas supply system), mainly includes the fourthgas supply pipe 232 d, the fifthgas supply pipe 232 e, theMFCs valves gas supply pipe 232 b connected to the fourthgas supply pipe 232 d, and a downstream side of a portion of the thirdgas supply pipe 232 c connected to the fifthgas supply pipe 232 e, thesecond nozzle 233 b, thethird nozzle 233 c, and thebuffer chambers gas supply pipe 232 n, theMFCs 241 m and 241 n, and thevalves 243 m and 243 n. The third inert gas supply system may also act as a purge gas supply system. - When a gas is supplied via the sixth
gas supply pipe 232 f and the seventhgas supply pipe 232 g as described above, a rare gas supply system (Ar gas supply system) which supplies a rare gas (Ar gas) to thewafers 200 in theprocess chamber 201 mainly includes the sixthgas supply pipe 232 f, the seventhgas supply pipe 232 g, theMFCs valves gas supply pipe 232 b connected to the sixthgas supply pipe 232 f, and a downstream side of a portion of the thirdgas supply pipe 232 c connected to the seventhgas supply pipe 232 g, thesecond nozzle 233 b, thethird nozzle 233 c, and thebuffer chambers gas supply pipe 232 p, theMFCs valves 243 o and 243 p. The fourth inert gas supply system may also act as a purge gas supply system. - When a gas is supplied via the eighth
gas supply pipe 232 h and the ninthgas supply pipe 232 i as described above, a nitrogen gas supply system (N2 gas supply system) which supplies nitrogen gas (N2 gas) to thewafers 200 in theprocess chamber 201 mainly includes the eighthgas supply pipe 232 h, the ninthgas supply pipe 232 i, theMFCs 241 h and 241 i, and thevalves 243 h and 243 i. A downstream side of a portion of the secondgas supply pipe 232 b connected to the eighthgas supply pipe 232 h, and a downstream side of a portion of the thirdgas supply pipe 232 c connected to the ninthgas supply pipe 232 i, thesecond nozzle 233 b, thethird nozzle 233 c, and thebuffer chambers - A fourth gas supply system which supplies at least one of nitrogen gas (N2 gas) and a rare gas (Ar gas) to the
wafers 200 in theprocess chamber 201 mainly includes the rare gas supply system and the nitrogen gas supply system described above. The fourth gas supply system may also act as a purge gas supply system. - Since, in the present embodiment, a reducing gas (H2 gas), nitrogen gas (N2 gas), and a rare gas (Ar gas) are used as modifying gases, each of the third gas supply system (reducing gas supply system) and the fourth gas supply system (nitrogen gas supply system and rare gas supply system) may also be referred to as a modifying gas supply system. Since a nitriding gas (NH3) acts as a reactive gas, the second gas supply system (nitriding gas supply system) may also be referred to as a reactive gas supply system.
- As illustrated in
FIG. 2 , in thebuffer chamber 237 b, a first rod-shapedelectrode 269 b serving as a first electrode and a second rod-shapedelectrode 270 b serving as a second electrode, both of which are slender and long electrodes, are provided from the lower portion of thereaction pipe 203 to the upper portion thereof, in the direction in which thewafers 200 are stacked. The first rod-shapedelectrode 269 b and the second rod-shapedelectrode 270 b are disposed in parallel with thesecond nozzle 233 b. Each of the first rod-shapedelectrode 269 b and the second rod-shapedelectrode 270 b is covered with anelectrode protection pipe 275 b which is configured to protect these electrodes from an upper portion to a lower portion thereof. One of the first rod-shapedelectrode 269 b and the second rod-shapedelectrode 270 b is connected to a high-frequency power source 273 via animpedance matching unit 272, and the other electrode is connected to a ground that has a reference electric potential. Plasma is generated in aplasma generating region 224 b between the first and second rod-shapedelectrodes electrodes frequency power source 273 via theimpedance matching unit 272. - Similarly, in the
buffer chamber 237 c, a first rod-shapedelectrode 269 c serving as a first electrode and a second rod-shapedelectrode 270 c serving as a second electrode, both of which are slender and long electrodes, are provided from the lower portion of thereaction pipe 203 to the upper portion thereof, in the direction in which thewafers 200 are stacked. The first rod-shapedelectrode 269 c and the second rod-shapedelectrode 270 c are disposed in parallel with thethird nozzle 233 c. Each of the first rod-shapedelectrode 269 b and the second rod-shapedelectrode 270 b is covered with anelectrode protection pipe 275 c which is configured to protect these electrodes from an upper portion to a lower portion thereof. One of the first rod-shapedelectrode 269 c and the second rod-shapedelectrode 270 c is connected to the high-frequency power source 273 via theimpedance matching unit 272, and the other electrode is connected to the ground that has the reference electric potential. Plasma is generated in aplasma generating region 224 c between the first and second rod-shapedelectrodes electrodes frequency power source 273 via theimpedance matching unit 272. - A first plasma source is mainly configured as a plasma generator (plasma generation unit) by the first rod-shaped
electrode 269 b, the second rod-shapedelectrode 270 b, and theelectrode protection pipe 275 b. Theimpedance matching unit 272 and the high-frequency power source 273 may further be included in the first plasma source. A second plasma source is mainly configured as a plasma generator (plasma generation unit) by the first rod-shapedelectrode 269 c, the second rod-shapedelectrode 270 c, and theelectrode protection pipe 275 c. Theimpedance matching unit 272 and the high-frequency power source 273 may be further included in the second plasma source. Each of the first and second plasma sources may also act as an activating mechanism that activates a gas to a plasma state, as will be described below. As described above, in the substrate processing apparatus according to the present embodiment, a plurality of excitation units (two excitation units in the present embodiment) are installed. The plurality of the excitation units are disposed in a distributed fashion, similar to thebuffer chambers - The
electrode protection pipe 275 b is configured such that the first and second rod-shapedelectrodes buffer chamber 237 b in a state in which the first and second rod-shapedelectrodes buffer chamber 237 b. Theelectrode protection pipe 275 c is configured such that the first and second rod-shapedelectrodes buffer chamber 237 c in a state in which the first and second rod-shapedelectrodes buffer chamber 237 c. Here, if the concentration of oxygen in theelectrode protection pipes electrodes electrode protection pipe 275 b and the first and second rod-shapedelectrodes electrode protection pipe 275 c are oxidized by heat from theheater 207. Thus, the concentrations of the oxygen in theelectrode protection pipes electrode protection pipes electrode protection pipes electrodes electrodes - The
exhaust port 231 a described above is installed at thereaction pipe 203. Theexhaust pipe 231 that exhausts the atmosphere in theprocess chamber 201 is connected to theexhaust port 231 a. Avacuum pump 246 which is a vacuum exhaust device is connected to theexhaust pipe 231 via apressure sensor 245 which is a pressure detector (pressure detection unit) that detects pressure in theprocess chamber 201 and an auto pressure controller (APC)valve 244 which is a pressure adjustor (pressure adjustment unit). TheAPC valve 244 is configured to perform or suspend vacuum-exhaust in theprocess chamber 201 by opening/closing theAPC valve 244 while thevacuum pump 246 is operated, and to adjust pressure in theprocess chamber 201 by controlling the degree of opening theAPC valve 244 while thevacuum pump 246 is operated. An exhaust system mainly includes theexhaust pipe 231, theAPC valve 244, and thepressure sensor 245. Thevacuum pump 246 may be further included in the exhaust system. The exhaust system is configured to perform vacuum-exhaust such that the pressure in the process chamber 210 may be equal to a predetermined pressure (degree of vacuum) by adjusting the degree of opening theAPC valve 244 based on pressure information detected by thepressure sensor 245 while thevacuum pump 246 is operated. - Below the
reaction pipe 203, aseal cap 219 is installed as a furnace port lid that may air-tightly close a lower end aperture of thereaction pipe 203. Theseal cap 219 is configured to contact a lower end of thereaction pipe 203 in a vertical direction from a lower portion thereof. Theseal cap 219 is formed of a metal, such as stainless steel, and has a disk shape. An O-ring 220 is installed as a seal member that contacts the lower end of thereaction pipe 203 on an upper surface of theseal cap 219. Arotating mechanism 267 that rotates theboat 217 as a substrate retainer is installed at a side of theseal cap 219 opposite to theprocess chamber 201. Arotation shaft 255 of therotating mechanism 267 is connected to theboat 217 while passing through theseal cap 219. Therotating mechanism 267 is configured to rotate thewafers 200 by rotating theboat 217. Theseal cap 219 is configured to be vertically moved upward/downward by aboat elevator 115 that is a lifting mechanism vertically installed outside thereaction pipe 203. Theboat elevator 115 is configured to load theboat 217 into or unload theboat 217 from theprocess chamber 201 by moving theseal cap 219 upward/downward. That is, theboat elevator 115 is configured as a transfer device (transfer mechanism) that transfers theboat 217, i.e., thewafers 200, inside or outside theprocess chamber 201. - The
boat 217 serving as a substrate support is formed of a heat-resistant material, e.g., quartz or silicon carbide, and is configured to support the plurality ofwafers 200 in multiple states in a state in which thewafers 200 are concentrically arranged in a horizontal posture. Below theboat 217, an insulatingmember 218 is formed of a heat-resistant material, e.g., quartz or silicon carbide, to prevent heat generated from theheater 207 from being transferred to theseal cap 219. Also, the insulatingmember 218 may include a plurality of insulating plates formed of a heat-resistant material, e.g., quartz or silicon carbide, and an insulating plate holder that supports the plurality of insulating plates in a multi-layered structure in a horizontal posture. - In the
reaction pipe 203, atemperature sensor 263 is installed as a temperature detector. Thetemperature sensor 263 is configured to control an amount of current to be supplied to theheater 207 based on temperature information detected by thetemperature sensor 263, so that the temperature in theprocess chamber 201 may have a desired temperature distribution. Thetemperature sensor 263 has an L-shape similar to thefirst nozzle 233 a, and is installed along an inner wall of thereaction pipe 203. - As illustrated in
FIG. 4 , acontroller 121 which is a control unit (control member) is configured as a computer including a central processing unit (CPU) 121 a, a random access memory (RAM) 121 b, amemory device 121 c, and an input/output (I/O)port 121 d. TheRAM 121 b, thememory device 121 c, and the I/O port 121 d are configured to exchange data with theCPU 121 a via an internal bus 212 e. An I/O device 122 configured, for example, as a touch panel is connected to thecontroller 121. - The
memory device 121 c is configured, for example, as a flash memory, a hard disk drive (HDD), or the like. In thememory device 121 c, a control program for controlling an operation of the substrate processing apparatus or a process recipe instructing an order or conditions of processing a substrate which will be described below are stored to be readable. The program recipe is a combination of processes designed to obtain a desired result when operations of a substrate processing process, which will be described below, are performed by thecontroller 121, and acts as a program. Hereinafter, such a process recipe and a control program will be referred to together simply as a ‘program.’ Also, when the term ‘program’ is used in the present disclosure, it should be understood as including only program recipe groups, only control program groups, or both program recipe groups and control program groups. The RAM 221 b is configured as a work area for temporarily storing a program or data read by the CPU 221 a. - The I/
O port 121 d is connected to theMFCs valves pressure sensor 245, theAPC valve 244, thevacuum pump 246, theheater 207, thetemperature sensor 263, therotating mechanism 267, theboat elevator 115, the high-frequency power source 273, theimpedance matching unit 272, and the like. - The CPU 221 a is configured to read the process recipe from the
memory device 121 c according to a manipulation command received via the I/O device 122, and read and execute the control program from thememory device 121 c. Also, according to the read program recipe, theCPU 121 a controls flow rates of various gases via theMFCs valves APC valve 244; controls the degree of pressure using theAPC valve 244, based on thepressure sensor 245; controls temperature using theheater 207, based on thetemperature sensor 263; controls driving/suspending of thevacuum pump 246; controls rotation and rotation speed of theboat 217 using therotating mechanism 267; controls upward/downward movement of theboat 217 using theboat elevator 115; controls supply of power from the high-frequency power source 273; and controls an impedance by theimpedance matching unit 272. - The
controller 121 is not limited to a personal computer, and may be configured as a general-purpose computer. For example, thecontroller 121 according to the present embodiment may be configured by preparing anexternal memory device 123 storing such programs, e.g., a magnetic disk (a magnetic tape, a flexible disk, a hard disk, etc.), an optical disc (a compact disc (CD), a digital versatile disc (DVD), etc.), a magneto-optical disc (MO), or a semiconductor memory (a universal serial bus (USB) memory, a memory card, etc.), and then installing the programs in a general-purpose computer using theexternal storage device 123. Also, a method of supplying a program to a computer is not limited to using theexternal memory device 123. For example, a communication unit, e.g., the Internet or an exclusive line, may be used to supply a program to a computer without using theexternal memory device 123. Thememory device 121 c or theexternal memory device 123 may be configured as a non-transitory computer-readable recording medium. Hereinafter, thestorage device 121 c and theexternal storage device 123 may also be referred to together simply as a ‘recording medium.’ Also, when the term ‘recording medium’ is used in the present disclosure, it may be understood as a case in which only groups of thememory devices 121 c are included, a case in which only groups of theexternal memory devices 123 are included, or a case in which both groups of thememory devices 121 c and groups of theexternal memory devices 123 are used. - Next, a method of forming a nitride film as an insulating film on a substrate according to the present embodiment, which is one process of a manufacturing process of a semiconductor apparatus (device), using the
process furnace 202 of the substrate processing apparatus as described above will be described. In the following description, operations of the elements of the substrate processing apparatus are controlled by thecontroller 121. - In the present embodiment, the nitride film is formed on the substrate by performing a cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying a plasma-excited hydrogen-containing gas to the substrate. A film-forming sequence according to the present embodiment will now be described in detail.
-
FIG. 5 is a flowchart illustrating a method of forming a film according to the first embodiment of the present invention.FIG. 10 is a diagram illustrating timing of supplying a gas and plasma power in a film-forming sequence according to the first embodiment of the present invention. In the film-forming sequence according to the present embodiment, a silicon nitride (Si3N4) film (hereinafter referred to simply as ‘SiN film’) is formed as an insulating film on awafer 200 using a DCS gas as a source gas and NH3 gas as a nitrogen-containing gas, and alternately and repeatedly performing a process of supplying the DCS gas to thewafer 200 in the process chamber 201 (DCS gas supply process) and a process of supplying plasma-excited NH3 gas to thewafer 200 in the process chamber 201 (NH3 gas supply process). In this case, the inside of theprocess chamber 201 is purged using N2 gas as a purge gas (first purging process) after the DCS gas is supplied into theprocess chamber 201, and the inside of theprocess chamber 201 is purged with N2 gas (second purging process) after NH3 gas is supplied into theprocess chamber 201. - In this case, a process of plasma-exciting and supplying H2 gas to the
wafer 200 in theprocess chamber 201 is performed both after the DCS gas is supplied using H2 gas as a modifying gas and before NH3 gas is supplied, and after NH3 gas is supplied and before DCS gas is supplied (first and second modifying processes). - In other words, in the film-forming sequence according to the present embodiment, a SiN film is formed on the
wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to thewafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H2 gas to thewafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH3 gas to thewafer 200 in the process chamber 201 (NH3 gas supply process), purging the process chamber 201 (second purging process), and supplying plasma-excited H2 gas to thewafer 200 in the process chamber 201 (second modifying process). The film-forming sequence according to the present embodiment will now be described in greater detail. - When the term ‘wafer’ is used in the present disclosure, it should be understood as either the wafer itself, or a stacked structure (assembly) including a wafer and a layer/film formed on the wafer (i.e., the wafer having the layer/film formed a surface thereof may also be referred to as the ‘wafer’). Also, when the expression ‘surface of the wafer’ is used in the present disclosure, it should be understood as either a surface (exposed surface) of the wafer itself or a surface of a layer/film formed on the wafer, i.e., an uppermost surface of the wafer as a stacked structure.
- Thus, in the present disclosure, the expression ‘specific gas is supplied to a wafer’ should be understood to mean that the specific gas is directly supplied to a surface (exposed surface) of the wafer or that the specific gas is supplied to a surface of a layer/film on the wafer, i.e., the uppermost surface of the wafer including a stacked structure. Also, in the present disclosure, the expression ‘a layer (or film) is formed on the wafer’ should be understood to mean that the layer (or film) is directly formed on a surface (exposed surface) of the wafer itself or that the layer (or film) is formed on a layer/film on the wafer, i.e., on the uppermost surface of the wafer including the stacked structure.
- Also, in the present disclosure, the term ‘substrate’ has the same meaning as the term ‘wafer.’ Thus, the term ‘wafer’ in the above-described description may be interchangeable with the term ‘substrate.’
- (Wafer Charging and Boat Loading)
- When a plurality of
wafers 200 are placed in the boat 217 (wafer charging), theboat 217 supporting the plurality ofwafers 200 is lifted by theboat elevator 115 to be loaded into the process chamber 201 (boat loading), as illustrated inFIG. 1 . In this state, the lower end of thereaction pipe 203 is air-tightly closed by theseal cap 219 via the 0-ring 220. - (Pressure & Temperature Control)
- The inside of the
process chamber 201 is vacuum-exhausted to have a desired pressure (degree of vacuum) by thevacuum pump 246. In this case, the pressure in theprocess chamber 201 is measured by thepressure sensor 245, and theAPC valve 244 is feedback-controlled based on information regarding the measured pressure (pressure control). Thevacuum pump 246 is kept operated at least until processing of thewafers 200 is completed. Also, the inside of theprocess chamber 201 is heated to a desired temperature by theheater 207. In this case, an amount of current supplied to theheater 207 is feedback-controlled based on temperature information detected by thetemperature sensor 263, so that the inside of theprocess chamber 201 may have a desired temperature distribution (temperature control). The heating of the inside of theprocess chamber 201 by theheater 207 is continuously performed at least until the processing of thewafers 200 is completed. Then, rotation of theboat 217 and thewafers 200 begins by the rotating mechanism 267 (wafer rotation). Also, the rotation of theboat 217 and thewafers 200 by therotating mechanism 267 is continuously performed at least until the processing of thewafers 200 is completed. Thereafter, six steps described below are sequentially performed. - [
Step 1a] - DCS gas is supplied to the first
gas supply pipe 232 a and N2 gas is supplied to the first inertgas supply pipe 232 j by opening thevalve 243 a of the firstgas supply pipe 232 a and thevalve 243 j of the first inertgas supply pipe 232 j. The DCS gas flows through the firstgas supply pipe 232 a and the flow rate of the DCS gas is then adjusted by theMFC 241 a. The N2 gas flows through the first inertgas supply pipe 232 j and the flow rate of the N2 gas is then adjusted by theMFC 241 j. The DCS gas having the adjusted flow rate is mixed with the N2 gas having the adjusted flow rate in the firstgas supply pipe 232 a, and the mixed gas of the DCS gas and the N2 gas is supplied into the heated and reduced-pressure process chamber 201 via the gas supply holes 248 a of thefirst nozzle 233 a and exhausted via theexhaust pipe 231. In this case, the DCS gas is supplied to the wafer 200 (DCS gas supply process). - In this case, in order to prevent the DCS gas from being supplied into the
buffer chambers second nozzle 233 b, or thethird nozzle 233 c, N2 gas is supplied into the second inertgas supply pipe 232 k, the third inert gas supply pipe 232 l, the fourth inert gas supply pipe 232 m, the fifth inertgas supply pipe 232 n, the sixth inert gas supply pipe 232 o, the seventh inertgas supply pipe 232 p, the eighthgas supply pipe 232 h, and the ninthgas supply pipe 232 i by opening thevalves process chamber 201 via the secondgas supply pipe 232 b, the thirdgas supply pipe 232 c, the fourthgas supply pipe 232 d, the fifthgas supply pipe 232 e, the sixthgas supply pipe 232 f, the seventhgas supply pipe 232 g, the eighthgas supply pipe 232 h, the ninthgas supply pipe 232 i, thesecond nozzle 233 b, thethird nozzle 233 c, and thebuffer chambers exhaust pipe 231. - In this case, the pressure in the
process chamber 201 is maintained constant to be less than atmospheric pressure, e.g., to fall within a range from 10 to 1,000 Pa, by appropriately controlling theAPC valve 244. The flow rate of the DCS gas is controlled by theMFC 241 a, for example, to fall within a range of 100 to 2,000 sccm (0.01 to 2 slm). The flow rate of the N2 gas is controlled by each of theMFCs wafer 200, i.e., a gas supply time (irradiation time), is set to range, for example, from 1 to 120 seconds. The temperature of theheater 207 is set to generate a CVD reaction in theprocess chamber 201 under the pressure described above. That is, the temperature of theheater 207 is set in such a manner that thewafer 200 may have a temperature ranging from, for example, 300 to 650° C., preferably 300 to 600° C., and more preferably, 300 to 550° C. - If the temperature of the
wafer 200 is less than 300° C., then it is difficult for the DCS gas to be decomposed on or adsorbed onto thewafer 200, thereby reducing a film-forming speed. Also, if the temperature of thewafer 200 is less than 300° C., then even when the DCS gas is decomposed on or adsorbed onto thewafer 200, the amount of decomposition or the amount of adsorption may vary according to a region in a plane of thewafer 200 or the position of thewafer 200. Thus, the DCS gas is not evenly decomposed or adsorbed in the plane of thewafer 200 or betweenadjacent wafers 200. Accordingly, the temperature of thewafer 200 may be set to be equal to or greater than 300° C. - If the temperature of the
wafer 200 is greater than 600° C., a vapor-phase reaction may prevail. In particular, if the temperature of thewafer 200 is greater than 650° C., film thickness uniformity is likely to be degraded, thereby preventing the film thickness uniformity from being controlled. Thus, the film thickness uniformity may be controlled not to be degraded and the vapor-phase reaction may be prevented from prevailing by controlling the temperature of thewafer 200 to be 600° C. or less. In particular, when the temperature of thewafer 200 is controlled to be 550° C. or less, a surface reaction may prevail and the film thickness uniformity may thus be easily secured and controlled. - As described above, the temperature of the
wafer 200 may be set to 300 to 650° C., preferably to 300 to 600° C., and more preferably, to 300 to 550° C. - Under the conditions described above, i.e., conditions of causing a CVD reaction, the DCS gas is supplied into the
process chamber 201 to form a silicon-containing layer on the wafer 200 (an underlying film formed on the wafer 200) to a thickness of less than one atomic layer to several atomic layers. The silicon-containing layer may include at least one of an adsorption layer of DCS gas and a silicon (Si) layer. However, the silicon-containing layer may preferably include silicon (Si) and chlorine (Cl). - Here, the silicon layer generally refers to all layers including continuous layers formed of silicon (Si), discontinuous layers formed of silicon (Si), or a silicon thin film formed by overlapping the continuous layers and the discontinuous layers. The continuous layers formed of silicon (Si) may also be referred to together as a silicon thin film. Also, silicon (Si) used to form the silicon layer should be understood as including silicon (Si) from which a bond with chlorine (Cl) or hydrogen (H) is not completely separated.
- Examples of the adsorption layer of DCS gas include not only continuous chemical adsorption layers including gas molecules of DCS gas but also discontinuous chemical adsorption layers including gas molecules of DCS gas. That is, the adsorption layer of DCS gas includes a chemical adsorption layer formed of DCS molecules to a thickness of one or less than one molecular layer. Also, examples of DCS (SiH2Cl2) molecules of the adsorption layer of DCS gas may include molecules, e.g., SiHxCly molecules, in which a bond between silicon (Si) and chlorine (Cl) or between silicon (Si) and hydrogen (H) is partially separated. That is, examples of the adsorption layer of DCS gas include continuous or discontinuous chemical adsorption layers including SiH2Cl2 molecules and/or SiHxCly molecules. Also, a layer having a thickness of less than one atomic layer means a discontinuously formed atomic layer, and a layer having a thickness of one atomic layer means a continuously formed atomic layer. A layer having a thickness of less than one molecular layer means a discontinuously formed molecular layer, and a layer having a thickness of one molecular layer means a continuously formed molecular layer.
- Silicon (Si) is deposited on the
wafer 200 to form a silicon layer on thewafer 200 under conditions in which DCS gas is self-decomposed (pyrolyzed), i.e., conditions causing a pyrolysis reaction of the DCS gas. The DCS gas is adsorbed onto thewafer 200 to form an adsorption layer of DCS gas on thewafer 200 under conditions in which DCS gas is not self-decomposed (pyrolyzed), i.e., conditions that do not cause a pyrolysis reaction of the DCS gas. A film-forming rate may be higher when the silicon layer is formed on thewafer 200 than when the adsorption layer of DCS gas is formed on thewafer 200. - If the thickness of the silicon-containing layer formed on the
wafer 200 exceeds a thickness of several atomic layers, then a desorption action of chlorine (Cl) does not have an effect on the entire silicon-containing layer inStep 3a which will be described below, a nitriding action or a desorption action of chlorine (Cl) does not have an effect on the entire silicon-containing layer inStep 4a which will be described below, and a desorption action of chlorine (Cl) does not have an effect on the entire silicon-containing layer inStep 6a which will be described below. The silicon-containing layer that may be formed on thewafer 200 may have a minimum thickness of less than one atomic layer. Thus, the silicon-containing layer may be set to have a thickness of less than one atomic layer to several atomic layers. Also, by controlling the silicon-containing layer to have a thickness not more than one atomic layer, i.e., a thickness of less than one atomic layer or of one atomic layer, the nitriding action or the desorption action of chlorine (Cl) inSteps Steps Step 1a may be reduced. Accordingly, a process time required to perform each cycle may be reduced, and a process time required to perform a total of cycles may thus be reduced. That is, a film-forming rate may be increased. Also, film thickness uniformity may be controlled to be increased by controlling the silicon-containing layer to have a thickness of one atomic layer or less. - In addition to dichlorosilane (SiH2Cl2, abbreviated to DCS), a chlorosilane-based material, e.g., monochlorosilane (SiH3Cl, abbreviated to MCS), hexachlorodisilane (Si2Cl6, abbreviated to HCD), tetrachlorosilane, i.e., silicon tetrachloride (SiCl4, abbreviated to STC), trichlorosilane (SiHCl3, abbreviated to TCS); an inorganic material, e.g., trisilane (Si3H8, abbreviated to TS), disilane (Si2H6, abbreviated to DS), monosilane (SiH4, abbreviated to MS); or an organic material, such as an aminosilane-based material, e.g., tetrakisdimethylaminosilane (Si[N(CH3)2]4, abbreviated to 4DMAS), trisdimethylaminosilane (Si[N(CH3)2]3H, abbreviated to 3DMAS), bisdiethylaminosilane (Si[N(C2H5)2]2H2, abbreviated to 2DEAS), or bistertiarybutylaminosilane (SiH2[NH(C4H9)]2, abbreviated to BTBAS), may be used as a source containing silicon, i.e., a silane-based material. However, when a chlorosilane-based material including chlorine (Cl) is used, a material having a composition formula having a small number of chlorine (Cl) atoms is preferably used. For example, DCS or MCS may be used. In addition to N2 gas, a rare gas, e.g., Ar gas, He gas, Ne gas, or Xe gas, may be used as the inert gas.
- [
Step 2a] - After the silicon-containing layer is formed on the
wafer 200, thevalve 243 a of the firstgas supply pipe 232 a is closed to suspend supplying of the DCS gas. In this case, the inside of theprocess chamber 201 is exhausted via thevacuum pump 246 while theAPC valve 244 of theexhaust pipe 231 is open, so as to exclude an unreacted or residual DCS gas remaining in theprocess chamber 201 after the silicon-containing layer is formed, from theprocess chamber 201. The N2 gas is continuously supplied as an inert gas into theprocess chamber 201 while thevalves process chamber 201 after the silicon-containing layer is formed, from the process chamber 201 (first purging process). - Alternatively, the residual gas may not be completely excluded from the
process chamber 201 and the inside of theprocess chamber 201 may not be completely purged. When the amount of the residual gas remaining in theprocess chamber 201 is small,Step 3a performed thereafter may not be negatively influenced by the residual gas. In this case, the flow rate of the N2 gas supplied into theprocess chamber 201 need not be high. For example, the inside of theprocess chamber 201 may be purged by supplying an amount of N2 gas that corresponds to the capacity of the reaction pipe 203 (or the process chamber 201) without causing negative influence inStep 3a. As described above, the inside of theprocess chamber 201 may not be completely purged to reduce a purging time, thereby improving the throughput. Also, unnecessary consumption of the N2 gas may be suppressed. - In this case, the temperature of the
heater 207 is set such that the temperature of thewafer 200 may fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., similar to the temperature of thewafer 200 when the DCS gas is supplied thereto. The supply flow rate of the N2 gas supplied as a purge gas via each inert gas supply system may range, for example, from 100 to 2,000 sccm (0.1 to 2 slm). Alternatively, a rare gas, e.g., Ar gas, He gas, Ne gas, or Xe gas, may be used as the purge gas, instead of N2 gas. - [
Step 3a] - After the residual gas is removed from the
process chamber 201, H2 gas is simultaneously excited into a plasma state by the two plasma generation units (excitation units) and the results of plasma-exciting H2 gas are then simultaneously supplied into theprocess chamber 201 from the two plasma generation units (excitation units), thereby modifying the silicon-containing layer (first modifying process) - Specifically, H2 gas is supplied into the fourth
gas supply pipe 232 d by opening thevalve 243 d of the fourthgas supply pipe 232 d. The H2 gas flows through the fourthgas supply pipe 232 d and the flow rate of the H2 gas is then adjusted by theMFC 241 d. The H2 gas having the adjusted flow rate passes through the secondgas supply pipe 232 b and is then supplied into thebuffer chamber 237 b via the gas supply holes 248 b of thesecond nozzle 233 b. In this case, the H2 gas supplied into thebuffer chamber 237 b is excited to a plasma state by supplying high-frequency power between the first rod-shapedelectrode 269 b and the second rod-shapedelectrode 270 b from the high-frequency power source 273 via theimpedance matching unit 272, is supplied as an excited species, i.e., an active species of hydrogen (H2*) into theprocess chamber 201 via the gas supply holes 238 b, and is exhausted via theexhaust pipe 231. In this case, the plasma-excited H2 gas is supplied to thewafer 200. At the same time, N2 gas is supplied into the fourth inert gas supply pipe 232 m by opening the valve 243 m. The N2 gas is supplied into theprocess chamber 201 together with the H2 gas, and is exhausted via theexhaust pipe 231. - Also, at the same time, H2 gas is supplied into the fifth
gas supply pipe 232 e by opening thevalve 243 e of the fifthgas supply pipe 232 e. The H2 gas flows through the fifthgas supply pipe 232 e and the flow rate of H2 gas is adjusted by theMFC 241 e. The H2 gas having the adjusted flow rate passes through the thirdgas supply pipe 232 c, and is then supplied into thebuffer chamber 237 c via the gas supply holes 248 c of thethird nozzle 233 c. In this case, the H2 gas supplied into thebuffer chamber 237 c is excited to a plasma state by supplying high-frequency power between the first rod-shapedelectrode 269 c and the second rod-shapedelectrode 270 c from the high-frequency power source 273 via theimpedance matching unit 272, is supplied as an excited species (H2*) into theprocess chamber 201 via the gas supply holes 238 c, and is exhausted via theexhaust pipe 231. In this case, the plasma-excited H2 gas is supplied to thewafer 200. At the same time, N2 gas is supplied into the fifth inertgas supply pipe 232 n by opening thevalve 243 n. The N2 gas is supplied into theprocess chamber 201 together with the H2 gas, and is exhausted via theexhaust pipe 231. - In this case, in order to prevent the H2 gas from being supplied to the
first nozzle 233 a, an upstream side of the secondgas supply pipe 232 b, an upstream side of the thirdgas supply pipe 232 c, the sixthgas supply pipe 232 f, the seventhgas supply pipe 232 g, the eighthgas supply pipe 232 h, and the ninthgas supply pipe 232 i, N2 gas is supplied into the first inertgas supply pipe 232 j, the second inertgas supply pipe 232 k, the third inert gas supply pipe 232 l, the sixth inert gas supply pipe 232 o, the seventh inertgas supply pipe 232 p, the eighthgas supply pipe 232 h, and the ninthgas supply pipe 232 i by opening thevalves process chamber 201 via the firstgas supply pipe 232 a, the secondgas supply pipe 232 b, the thirdgas supply pipe 232 c, the sixthgas supply pipe 232 f, the seventhgas supply pipe 232 g, the eighthgas supply pipe 232 h, the ninthgas supply pipe 232 i, thefirst nozzle 233 a, thesecond nozzle 233 b, thethird nozzle 233 c, and thebuffer chambers exhaust pipe 231. - When the H2 gas is plasma-excited and is supplied as an excited species, the pressure in the
process chamber 201 is set, e.g., to fall within a range from 10 to 1,000 Pa, by appropriately controlling theAPC valve 244. The supply flow rate of the H2 gas is adjusted by each of theMFCs MFCs wafer 200, i.e., a gas supply time (irradiation time), is set to range, for example, from 1 to 120 seconds. When the throughput is considered, the temperature of theheater 207 may be preferably set to be the same as when the DCS gas is supplied instep 1a, that is, the temperature in theprocess chamber 201 inSteps 1a through 3a may be preferably maintained to be the same as when the DCS gas is supplied instep 1a. In this case, the temperature of theheater 207 may be preferably set so that the temperature of thewafer 200, i.e., the temperature in theprocess chamber 201, inSteps 1a through 3a may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, 300 to 550° C. Also, the temperature of theheater 207 may be more preferably set so that the temperature in theprocess chamber 201 may be maintained constant as described above fromStep 1a throughStep 6a (which will be described below). The high-frequency power supplied between the first and second rod-shapedelectrode electrode frequency power source 273 is set to, for example, fall within a range of 50 to 1,000 W. - The excited species of hydrogen (H2) supplied into the
process chamber 201 by exciting H2 gas to a plasma state under the conditions described above reacts with at least a portion of the silicon-containing layer formed on thewafer 200 inStep 1a. Thus, impurities contained in the silicon-containing layer, e.g., hydrogen (H) or chlorine (Cl), may be efficiently desorbed from the silicon-containing layer, thereby forming the silicon-containing layer having a very low concentration of impurities. Also, by efficiently desorbing chlorine (Cl) from the silicon-containing layer, the efficiency of a nitriding process inStep 4a which will be described below may be improved. In other words, the efficiency of the nitriding process inStep 4a may be improved by efficiently desorbing chlorine (Cl), which is a factor degrading the performance of the nitriding process, from the silicon-containing layer. A process of modifying the silicon-containing layer is performed as described above. Also, the impurities, e.g., hydrogen (H) or chlorine (Cl), desorbed from the silicon-containing layer are exhausted outside theprocess chamber 201 via theexhaust pipe 231. - In
Step 3a, by using the plurality of plasma generation units (excitation units), the supply rate of the excited species to thewafer 200 may be increased while reducing plasma outputs of respective plasma generation units (excitation units) by reducing the amounts of high-frequency power to be supplied to the plasma generation units (excitation units). Thus, the supply rate of the excited species to thewafer 200 may be increased while suppressing plasma damage to thewafer 200 or the silicon-containing layer. - Accordingly, the supply rate of the excited species to the
wafer 200 may be increased while suppressing plasma damage to thewafer 200 or the silicon-containing layer, the efficiency of removing impurities may be increased, and the concentration of impurities in the silicon-containing layer may be lowered. As a result, a process time may be reduced. Also, the concentration of impurities in a plane of thewafer 200 may be uniformly lowered. In other words, the excited species may be more evenly supplied to all regions in the plane of thewafer 200. For example, the difference between the concentration of impurities near the circumference of thewafer 200 and the concentration of impurities at the center of thewafer 200 may be controlled not to be large. - [
Step 4a] - After the silicon-containing layer is modified, NH3 gas is simultaneously excited to a plasma state by the two plasma generation units (excitation units) and the results of plasma-exciting the NH3 gas are simultaneously supplied into the
process chamber 201 from the two plasma generation units (excitation units), thereby nitriding the modified silicon-containing layer (NH3 gas supply process). - Specifically, NH3 is supplied into the second
gas supply pipe 232 b by opening thevalve 243 b of the secondgas supply pipe 232 b. The NH3 gas flows through the secondgas supply pipe 232 b and the flow rate of the NH3 gas is adjusted by theMFC 241 b. The NH3 gas having the adjusted flow rate is supplied into thebuffer chamber 237 b via the gas supply holes 248 b of thesecond nozzle 233 b. In this case, the NH3 gas supplied into thebuffer chamber 237 b is excited to a plasma state by supplying high-frequency power between the first rod-shapedelectrode 269 b and the second rod-shapedelectrode 270 b from the high-frequency power source 273 via theimpedance matching unit 272, is supplied as an excited species (NH3*) into theprocess chamber 201 via the gas supply holes 238 b, and is exhausted via theexhaust pipe 231. In this case, the plasma-excited NH3 gas is supplied to thewafer 200. At the same time, N2 gas is supplied into the second inertgas supply pipe 232 k by opening thevalve 243 k. The N2 gas is supplied into theprocess chamber 201 together with the NH3 gas, and is exhausted via theexhaust pipe 231. - Also, at the same time, NH3 gas is supplied into the third
gas supply pipe 232 c by opening thevalve 243 c of the thirdgas supply pipe 232 c. The NH3 gas flows through the thirdgas supply pipe 232 c and the flow rate of the NH3 gas is adjusted by theMFC 241 c. The NH3 gas having the adjusted flow rate is supplied into thebuffer chamber 237 c via the gas supply holes 248 c of thethird nozzle 233 c. In this case, the NH3 gas supplied into thebuffer chamber 237 c is excited to a plasma state by supplying high-frequency power between the first rod-shapedelectrode 269 c and the second rod-shapedelectrode 270 c from the high-frequency power source 273 via theimpedance matching unit 272, is supplied as an excited species (NH3*) into theprocess chamber 201 via the gas supply holes 238 c, and is exhausted via theexhaust pipe 231. In this case, the plasma-excited NH3 gas is supplied to thewafer 200. At the same time, N2 gas is supplied into the third inert gas supply pipe 232 l by opening the valve 243 l. The N2 gas is supplied into theprocess chamber 201 together with the NH3 gas, and is exhausted via theexhaust pipe 231. - In this case, in order to prevent the NH3 gas from being supplied to the
first nozzle 233 a, the fourthgas supply pipe 232 d, the fifthgas supply pipe 232 e, the sixthgas supply pipe 232 f, the seventhgas supply pipe 232 g, the eighthgas supply pipe 232 h, and the ninthgas supply pipe 232 i, N2 gas is supplied into the first inertgas supply pipe 232 j, the fourth inert gas supply pipe 232 m, the fifth inertgas supply pipe 232 n, the sixth inert gas supply pipe 232 o, the seventh inertgas supply pipe 232 p, the eighthgas supply pipe 232 h, and the ninthgas supply pipe 232 i by opening thevalves process chamber 201 via the firstgas supply pipe 232 a, the fourthgas supply pipe 232 d, the fifthgas supply pipe 232 e, the sixthgas supply pipe 232 f, the seventhgas supply pipe 232 g, the eighthgas supply pipe 232 h, the ninthgas supply pipe 232 i, thefirst nozzle 233 a, thesecond nozzle 233 b, thethird nozzle 233 c, and thebuffer chambers exhaust pipe 231. - When the NH3 gas is plasma-excited and is supplied as an excited species, the pressure in the
process chamber 201 is set, e.g., to fall within a range of 10 to 1,000 Pa, by appropriately controlling theAPC valve 244. The supply flow rate of the NH3 gas is adjusted by each of theMFCs MFCs wafer 200, i.e., a gas supply time (irradiation time), is set to range, for example, from 1 to 120 seconds. When the throughput is considered, the temperature of theheater 207 may be a temperature at which the silicon-containing layer is nitrided, and may be preferably set to be the same as when the DCS gas is supplied instep 1a, that is, the temperature in theprocess chamber 201 inSteps 1a through 4a may be preferably maintained to be the same. In this case, the temperature of theheater 207 may be preferably set so that the temperature of thewafer 200, i.e., the temperature in theprocess chamber 201, inSteps 1a through 4a may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, 300 to 550° C. Also, the temperature of theheater 207 may be more preferably set so that the temperature in theprocess chamber 201 may be maintained to be the same fromStep 1a throughStep 6a (which will be described below), as described above. The high-frequency power supplied between the first and second rod-shapedelectrode electrode frequency power source 273 is set, for example, to fall within a range of 50 to 1,000 W. In this case, the NH3 gas may be thermally excited, i.e., activated by heat, and may then be supplied. However, when the thermally activated NH3 gas is supplied under a reduced-pressure atmosphere, the pressure in theprocess chamber 201 should be relatively high, for example, to fall within a range of 10 to 3,000 Pa, and the temperature of thewafer 200 should be 550° C. or higher so as to obtain a sufficient nitriding power. In this case, when NH3 gas is plasma-excited and then supplied, a sufficient nitriding power may be obtained even when the temperature in theprocess chamber 201 is, for example, 300° C. or higher. Also, when the NH3 gas is plasma-excited and is then supplied, a sufficient nitriding power may be obtained even when the temperature in theprocess chamber 201 is set to room temperature. However, when the temperature in theprocess chamber 201 is less than 150° C., reacted by-products, such as ammonium chloride (NH4Cl), are adhered into theprocess chamber 201 or onto thewafer 200. Thus, the temperature in theprocess chamber 201 is preferably 150° C. or higher, and is set to be 300° C. or higher in the present embodiment. - The excited species (NH3*) supplied into the
process chamber 201 by exciting NH3 gas to a plasma state under the conditions described above reacts with at least a portion of the silicon-containing layer that is formed on thewafer 200 inStep 1a and from which impurities are removed inStep 3a. Thus, the silicon-containing layer is nitrided to be changed (modified) into a silicon nitride (Si3N4) layer (hereinafter referred to simply as ‘SiN layer’). - In
Step 4a, by using a plurality of plasma generation units (excitation units), the supply rate of the excited species to thewafer 200 may be increased while reducing plasma outputs of the respective plasma generation units (excitation units) by reducing the amounts of high-frequency power supplied to each of the plasma generation units (excitation units). Thus, the supply rate of the excited species to thewafer 200 may be increased while suppressing plasma damage to thewafer 200 or the silicon-containing layer. - Accordingly, the supply rate of the excited species to the
wafer 200 may be increased while suppressing plasma damage to thewafer 200 or the silicon-containing layer, and the nitriding power may be increased to promote the nitriding of the silicon-containing layer. In other words, the efficiency of nitriding may be increased. Also, the nitriding of the silicon-containing layer may saturate to be rapidly changed to a self-limiting state (nitrided state), thereby reducing a nitriding time. As a result, a process time may be reduced, and uniformity of the result of nitriding the silicon-containing layer in a plane of thewafer 200 may be improved. That is, the excited species may be uniformly supplied to all regions in the plane of thewafer 200. For example, the difference between the degrees of nitriding performed near the circumference of thewafer 200 and at the center of thewafer 200 may be controlled not to be large. - Also, the plurality of plasma generation units may be used to increase the supply rate of the excited species to the
wafer 200 while suppressing plasma damage to thewafer 200 or the silicon-containing layer, and chlorine (Cl) may be more effectively desorbed from the silicon-containing layer having a low concentration of chlorine (Cl), which is formed inStep 1a and from which impurities are removed inStep 3a. Therefore, a SiN layer having very low concentration of chlorine (Cl) may be formed. Also, the efficiency of nitriding the silicon-containing layer may be greatly improved by effectively desorbing chlorine (Cl) from the silicon-containing layer. That is, the efficiency of the nitriding may be greatly improved by effectively desorbing chlorine (Cl), which is a factor degrading the performance of the nitriding process, from the silicon-containing layer. The chlorine (Cl) desorbed from the silicon-containing layer is exhausted from theprocess chamber 201 via theexhaust pipe 231. - Diazene (N2H2) gas, hydrazine (N2H4) gas, N3H8 gas, or the like may be used as a nitrogen-containing gas, instead of NH3 gas. Otherwise, an amine-based gas, such as ethylamine or methylamine, may be used as the nitrogen-containing gas, instead of NH3 gas.
- [
Step 5a] - After the silicon-containing layer is changed into the SiN layer, the supply of the NH3 gas is suspended by closing the
valve 243 b of the secondgas supply pipe 232 b and thevalve 243 c of the thirdgas supply pipe 232 c. In this case, the inside of theprocess chamber 201 is vacuum-exhausted by thevacuum pump 246 while theAPC valve 244 of theexhaust pipe 231 is open, so as to exclude unreacted or residual NH3 gas remaining in theprocess chamber 201 after the SiN layer is formed, from theprocess chamber 201. The N2 gas is continuously supplied as an inert gas into theprocess chamber 201 while thevalves process chamber 201 after the SiN layer is formed, from the process chamber 201 (second purging process). - Alternatively, the residual gas may not be completely excluded from the
process chamber 201 and the inside of theprocess chamber 201 may not be completely purged. When the amount of the residual gas remaining in theprocess chamber 201 is small,Step 6a performed thereafter may not be negatively influenced by the residual gas. In this case, the flow rate of the N2 gas supplied into theprocess chamber 201 need not be high. For example, the inside of theprocess chamber 201 may be purged by supplying an amount of N2 gas that corresponds to the capacity of the reaction pipe 203 (or the process chamber 201) without causing negative influence inStep 6a. As described above, the inside of theprocess chamber 201 may not be completely purged to reduce a purging time, thereby improving the throughput. Also, unnecessary consumption of the N2 gas may be suppressed. - In this case, the temperature of the
heater 207 is set such that the temperature of thewafer 200 may fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., similar to the temperature of thewafer 200 when the NH3 gas is supplied thereto. The supply flow rate of the N2 gas supplied as a purge gas via each inert gas supply system may range, for example, from 100 to 2,000 sccm (0.1 to 2 slm). Alternatively, a rare gas, e.g., Ar gas, He gas, Ne gas, or Xe gas, may be used as the purge gas, instead of N2 gas. - [
Step 6a] - After the residual gas is removed from the
process chamber 201, H2 gas is simultaneously excited to a plasma state by the two plasma generation units (excitation units) according to the same order and conditions as inStep 3a (first modifying process) described above, and the plasma-excited H2 gas is simultaneously supplied into theprocess chamber 201 from the two plasma generation units (excitation units), thereby modifying the SiN layer (second modifying process). - The excited species of hydrogen (H2) supplied into the
process chamber 201 by exciting H2 gas to a plasma state react with at least a portion of the SiN layer formed on thewafer 200 inStep 4a. Thus, impurities contained in the SiN layer, e.g., hydrogen (H) or chlorine (Cl), may be efficiently desorbed from the SiN layer. That is, hydrogen or chlorine may be more efficiently desorbed from the SiN layer having a low concentration of hydrogen/chlorine, which is formed by desorbing impurities therefrom inSteps process chamber 201 via theexhaust pipe 231. - In
Step 6a, by using a plurality of plasma generation units (excitation units), the supply rate of the excited species to thewafer 200 may be increased while reducing plasma outputs of respective plasma generation units (excitation units) by reducing the amounts of high-frequency power supplied to each of the plasma generation units (excitation units). Thus, the supply rate of the excited species to thewafer 200 may be increased while suppressing plasma damage to thewafer 200 or the SiN layer. - Accordingly, the supply rate of the excited species to the
wafer 200 may be increased while suppressing plasma damage to thewafer 200 or the SiN layer, the efficiency of removing impurities may be increased, and the concentration of impurities in the SiN layer may be lowered. As a result, a process time may be reduced. Also, the concentration of impurities in a plane of thewafer 200 may be uniformly lowered. In other words, the excited species may be more evenly supplied to all regions in the plane of thewafer 200. For example, the difference between the concentration of impurities near the circumference of thewafer 200 and the concentration of impurities at the center of thewafer 200 may be controlled not to be large. - A silicon nitride (Si3N4) film (hereinafter referred to simply as ‘SiN film’) may be formed on the
wafer 200 to a desired thickness by performing onecycle including Steps 1a through 6a described above a predetermined number of times, and preferably, several times. - Here, the expression ‘when the cycle described above is repeatedly performed, a specific gas is supplied to the
wafer 200 in each step after the cycle is performed at least twice’ means ‘a specific gas is supplied to a layer formed on thewafer 200, i.e., on the uppermost surface of thewafer 200 as a stacked structure.’ The expression ‘a specific layer is formed on the wafer 200’ means ‘a specific layer is formed on a layer formed on thewafer 200, i.e., on the uppermost surface of thewafer 200 as a stacked structure. This also applies to the other embodiments which will be described below. - (Purging and Atmosphere Pressure Recovery)
- After the SiN film is formed to a desired thickness, N2 gas is supplied as an inert gas from each inert gas supply system into the
process chamber 201 by opening thevalves exhaust pipe 231. The N2 gas acts as a purge gas to purge the inside of theprocess chamber 201 with an inert gas, and the residual gas remaining in theprocess chamber 201 is thus removed (purged) from theprocess chamber 201. Thereafter, an atmosphere in theprocess chamber 201 is replaced with the inert gas, and the pressure in theprocess chamber 201 is returned to a normal pressure (atmosphere pressure recovery). - (Boat Unloading and Wafer Discharging)
- Then, when the
seal cap 219 is moved downward by theboat elevator 115, the lower end of thereaction pipe 203 is opened, and at the same time, the processedwafer 200 retained by theboat 217 is unloaded outside thereaction pipe 203 from the lower end of the reaction pipe 203 (boat unloading). Then, the processedwafer 200 is discharged by the boat 217 (wafer discharging). - According to the present embodiment, at least one of the following effects can be achieved.
- (a) In
Step 4a according to the present embodiment, a silicon-containing layer may be efficiently nitrided at a low temperature by supplying an excited species, which is obtained by plasma-exciting NH3 gas, to the silicon-containing layer, thereby forming a SiN film at a low temperature. Also, impurities, such as hydrogen or chlorine, contained in the silicon-containing layer may be efficiently desorbed from the silicon-containing layer. As a result, a SiN film having a low concentration of impurities, i.e., having a high film density, may be formed, and the resistance of the SiN film to hydrogen fluoride may be improved. Also, the insulating properties of the SiN film may be improved. - (b) In
Step 3a according to the present embodiment, impurities, such as hydrogen or chlorine, contained in a silicon-containing layer may be efficiently desorbed from the silicon-containing layer by supplying an excited species obtained by plasma-exciting H2 gas to the silicon-containing layer. As a result, a SiN film having a lower concentration of impurities, i.e., having higher film density, may be formed at a low temperature, and the resistance of the SiN film to hydrogen fluoride may be greatly improved. Also, the insulating properties of the SiN film may be greatly improved. - (c) In
Step 6a according to the present embodiment, impurities, such as hydrogen or chlorine, contained in a SiN layer may be efficiently desorbed from the SiN layer by supplying an excited species, which is obtained by plasma-exciting H2 gas, to the SiN layer. As a result, a SiN film having a lower concentration of impurities, i.e., having higher film density, may be formed at a low temperature, and the resistance of the SiN film to hydrogen fluoride may be greatly improved. Also, the insulating properties of the SiN film may be greatly improved. - (d) In
Steps Step 4a may be improved by efficiently desorbing chlorine from the silicon-containing layer or the SiN layer. In other words, the efficiency of the nitriding process performed inStep 4a may be improved by efficiently desorbing chlorine, which is a factor degrading the performance of the nitriding process, from the silicon-containing layer or the SiN layer. Accordingly, a time needed to form the SiN film can be reduced, thereby increasing the yield. - (e) In
Steps wafer 200 may be increased while reducing plasma outputs of the respective plasma generation units (excitation units) by reducing the amounts of high-frequency power supplied to each of the plasma generation units (excitation units). Thus, the supply rate of an excited species to thewafer 200 may be increased while suppressing plasma damage to thewafer 200, the silicon-containing layer, or the SiN layer. - Thus, in
Step 4a, nitriding power may be increased, and nitriding of the silicon-containing layer may be promoted. That is, the efficiency of the nitriding may be increased. Also, the nitriding of the silicon-containing layer may saturate to be rapidly changed to a self-limiting state (nitrided state), thereby reducing a nitriding time. As a result, a process time may be reduced. Also, uniformity of the result of nitriding the silicon-containing layer in a plane of thewafer 200 may be improved. That is, the excited species may be uniformly supplied to all regions in the plane of thewafer 200 using the plasma generation units. For example, the difference between the degrees of nitriding performed near the circumference of thewafer 200 and at the center of thewafer 200 may be controlled not to be large. Also, inStep 4a, chlorine may be further efficiently desorbed from the silicon-containing layer having a low concentration of chlorine, which is formed inStep 1a and from which impurities are removed inStep 3a. Thus, a SiN layer having very a low concentration of chlorine may be formed. Also, the efficiency of nitriding the silicon-containing layer may be greatly improved by efficiently desorbing chlorine therefrom. That is, the efficiency of nitriding the silicon-containing layer may be greatly improved by efficiently desorbing chlorine, which is a factor degrading the nitriding, from the silicon-containing layer. - Also, in
Steps wafer 200 may be improved. That is, an excited species may be greatly uniformly supplied to all regions in the plane of thewafer 200 using the plasma generation units. For example, the difference between the concentrations of impurities in the SiN film near the circumference of thewafer 200 and at the center of thewafer 200 may be controlled not to be large. - If only one plasma generation unit is used, a plasma output of the plasma generation unit should be increased to increase the supply rate of excited species to the
wafer 200. However, since in this case, a range of plasmification becomes too large, even thewafer 200 may thus be exposed to plasma. Furthermore, serious damage (plasma damage) may be caused to thewafer 200 or the SiN film formed on thewafer 200. Also, sputtering may occur on thewafer 200 or the periphery of thewafer 200 due to plasma, thereby causing particles to be generated or degrading the quality of the SiN film. Also, the quality of the SiN film formed on thewafer 200 may be remarkably different near the circumference of thewafer 200 exposed to plasma than at the center of thewafer 200 that is not exposed to plasma. - To solve this problem, when a plurality of plasma generation units are used as in the present embodiment, the supply rate of an excited species to the
wafer 200 may be increased while reducing plasma outputs of the respective plasma generation units. - (f) In the present embodiment, the same effect as when a number of times of rotating the wafer 200 (rotation speed thereof) is increased during forming of a film may be achieved using the plasma generation units, and thickness uniformity of the SiN film in a plane of the
wafer 200 may be improved. In other words, in the film-forming sequence according to the current embodiment, DCS gas, NH3 gas, or H2 gas is intermittently supplied while rotating thewafer 200. However, in this sequence, a certain relationship is present between the number of times of rotating thewafer 200 and the thickness uniformity of the SiN film in a plane of thewafer 200. Specifically, when the number of times of rotating the wafer 200 (rotation speed thereof) is greater, more regions of thewafer 200 are covered when a gas is supplied once, thereby improving the thickness uniformity of the SiN film in the plane of thewafer 200. However, the upper limit of the number of times of rotating thewafer 200 is limited due to a vibration-preventing effect of thewafer 200. For example, there is a case in which the number of times of rotating thewafer 200 cannot be set to be greater than 3 rpm. To solve this problem, since in the present embodiment, two plasma generation units are used, the same effect as when the number of times of rotating thewafer 200 doubles may be achieved, and the thickness uniformity of the SiN film in the plane of thewafer 200 may be improved. This effect is particularly effective when the SiN film is formed as a thin film having a thickness of, for example, 50 Å or less. - (g) As described above, in the film-forming sequence according to the present embodiment, a SiN film having a very low concentration of impurities, such as hydrogen or chlorine, i.e., having very high film density may be formed at a low temperature, for example, 550° C. or less. Thus, the resistance of the SiN film to hydrogen fluoride, and the insulating properties and quality of the SiN film may be improved. Also, a time needed to nitride and process the silicon-containing layer may be reduced by increasing the efficiency of nitriding the silicon-containing layer while suppressing plasma damage to the
wafer 200, the silicon-containing layer, or the SiN layer, thereby increasing the throughput. Also, the quality and thickness uniformity of the SiN film in a plane of thewafer 200 may be improved by removing impurities from the SiN film or uniformly improving the degree of nitriding the SiN film in the plane of thewafer 200. Also, a probability that sterically hindered dangling bonds will occur during forming of a film may be reduced. Furthermore, natural oxidation of the SiN film may be suppressed due to a low concentration of chlorine in the SiN film, during transfer of thewafer 200, e.g., boat unloading. - When a SiN film was formed according to the film-forming sequence according to the present embodiment, it was confirmed that the density of the SiN film were much higher than when a SiN film was formed by alternately supplying DCS gas and NH3 gas according to a conventional method. Thus, the density of the SiN film in a plane of the
wafer 200 was very uniformly reduced. Also, when a SiN film was formed according to the film-forming sequence according to the present embodiment, it was confirmed that the concentration of impurities, such as chlorine, in the SiN film was far less than when a SiN film was formed by alternately supplying DCS gas and NH3 gas according to a conventional method. Thus, the concentration of impurities in a plane of thewafer 200 was very uniformly reduced. Also, according to the film-forming sequence according to the present embodiment, an etching rate with respect to hydrogen fluoride was low even when a silicon source that did not contain chlorine atoms was used. - Although in the first embodiment described above, a hydrogen-containing gas, e.g., H2 gas, is used as a modifying gas during both the first and second modifying processes, the present invention is not limited thereto. For example, a hydrogen-containing gas, e.g., H2 gas, may be used as a modifying gas in the first modifying process, and at least one of a rare gas, e.g., Ar gas or He gas, and N2 gas may be used as a modifying gas in the second modifying process.
- In the second embodiment of the present invention, a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to a substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
- Specifically, in a film-forming sequence according to the present embodiment, a SiN film is formed on the
wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to thewafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H2 gas to thewafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH3 gas to thewafer 200 in the process chamber 201 (NH3 gas supply process), purging the process chamber 201 (second purging process), and supplying at least one of plasma-excited N2 gas and plasma-excited Ar gas to thewafer 200 in the process chamber 201 (second modifying process). The film-forming sequence according to the present embodiment will now be described in greater detail. -
FIG. 6 is a flowchart illustrating a method of forming a film according to the second embodiment of the present invention.FIG. 11 is a diagram illustrating timing of supplying a gas and plasma power according to the second embodiment of the present invention.FIGS. 6 and 11 illustrate cases in which H2 gas is used as a modifying gas in a first modifying process, and Ar gas or N2 gas is used as a modifying gas in a second modifying process. The film-forming sequence according to the present embodiment is the same as the film-forming sequence according to the first embodiment, except that Ar gas or N2 gas is used as a modifying gas in the second modifying process. The second modifying process (Step 6b) according to the present embodiment that is different from that in the first embodiment is described below. - (When Ar Gas is Used as a Modifying Gas)
- In the second modifying process, if Ar gas is used as a modifying gas, then a SiN layer is performed on the
wafer 200 by performingSteps 1b through 5b and residual gases remaining in theprocess chamber 201 are removed, similar toSteps 1a through 5a according to the first embodiment. Thereafter, the Ar gas is simultaneously excited to a plasma state by two plasma generation units (excitation units), and the plasma-excited Ar gas is simultaneously supplied into theprocess chamber 201 from the two plasma generation units (excitation units) to modify the SiN layer (second modifying process). - Specifically, Ar gas is supplied into the sixth
gas supply pipe 232 f by opening thevalve 243 f of the sixthgas supply pipe 232 f. The Ar gas flows through the sixthgas supply pipe 232 f, and the flow rate of the Ar gas is adjusted by theMFC 241 f. The Ar gas having the adjusted flow rate passes through the secondgas supply pipe 232 b, and is then supplied into thebuffer chamber 237 b via the gas supply holes 248 b of thesecond nozzle 233 b. In this case, the Ar gas supplied into thebuffer chamber 237 b is plasma-excited as an excited species (Ar*) by supplying high-frequency power between the first and second rod-shapedelectrodes frequency power source 273 via theimpedance matching unit 272, and the excited species (Ar*) is supplied into theprocess chamber 201 via the gas supply holes 238 b and exhausted via theexhaust pipe 231. In this case, the plasma-excited Ar gas is supplied to thewafer 200. - At the same time, Ar gas is supplied into the seventh
gas supply pipe 232 g by opening thevalve 243 g of the seventhgas supply pipe 232 g. The Ar gas flows through the seventhgas supply pipe 232 g, and the flow rate of the Ar gas is adjusted by theMFC 241 g. The Ar gas having the adjusted flow rate passes through the thirdgas supply pipe 232 c, and is then supplied into thebuffer chamber 237 c via the gas supply holes 248 c of thethird nozzle 233 c. In this case, the Ar gas supplied into thebuffer chamber 237 c is plasma-excited as an excited species (Ar*) by supplying high-frequency power between the first and second rod-shapedelectrodes frequency power source 273 via theimpedance matching unit 272, and the excited species (Ar*) is supplied into theprocess chamber 201 via the gas supply holes 238 c and exhausted via theexhaust pipe 231. In this case, the plasma-excited Ar gas is supplied to thewafer 200. - In this case, in order to prevent the plasma-excited Ar gas from being supplied into the
first nozzle 233 a, N2 gas is supplied into the first inertgas supply pipe 232 j by opening thevalve 243 j. The N2 gas is supplied into theprocess chamber 201 via the firstgas supply pipe 232 a and thefirst nozzle 233 a, and is exhausted via theexhaust pipe 231. - In this case, when the excited species obtained by plasma-exciting the Ar gas is supplied, the pressure in the
process chamber 201 is controlled, e.g., to fall within a range of 10 to 1,000 Pa, by appropriately controlling theAPC valve 244. The supply flow rate of the Ar gas is controlled by each of theMFCs MFC 241 j, for example, to fall within a range of 100 to 2,000 sccm (0.1 to 2 slm). A time period in which the excited species obtained by plasma-exciting the Ar gas is supplied to thewafer 200, i.e., a gas supply time (irradiation time), is set to range, for example, from 1 to 120 seconds. When the throughput is considered, the temperature of theheater 207 is set to be the same as when the DCS gas is supplied inStep 1b, that is, the temperature of the wafer 200 (or the temperature in the process chamber 201) inSteps 1b through 6b may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., as in the first embodiment. The high-frequency power supplied from the high-frequency power source 273 between the first and second rod-shapedelectrodes electrodes - Alternatively, a rare gas other than Ar gas, e.g., He gas, Ne gas, or Xe gas, may be used as the modifying gas. Among rare gases at least one of Ar gas and He gas is preferably used, and Ar gas is more preferably used.
- (When N2 Gas is Used as a Modifying Gas)
- In the second modifying process, if N2 gas is used as a modifying gas, then a SiN layer is formed on the
wafer 200 by performingSteps 1b through 5b, similar toSteps 1a through 5a according to the first embodiment, and residual gases remaining in theprocess chamber 201 are removed. Thereafter, the N2 gas is simultaneously excited to a plasma state by two plasma generation units (excitation units), and the plasma-excited N2 gas is simultaneously supplied into theprocess chamber 201 from the two plasma generation units (excitation units) to modify the SiN layer (second modifying process). - Specifically, N2 gas is supplied into the eighth
gas supply pipe 232 h by opening thevalve 243 h of the eighthgas supply pipe 232 h. The N2 gas flows through the eighth gas supply pipe, and the flow rate of the N2 gas is adjusted by theMFC 241 h. The N2 gas having the adjusted flow rate flows through the secondgas supply pipe 232 b, and is then supplied into thebuffer chamber 237 b via the gas supply holes 248 b of thesecond nozzle 233 b. In this case, the N2 gas supplied into thebuffer chamber 237 b is plasma-excited as an excited species (N2*) by supplying high-frequency power between the first and second rod-shapedelectrodes frequency power source 273 via theimpedance matching unit 272, and the excited species (Ar*) is supplied into theprocess chamber 201 via the gas supply holes 238 b and exhausted via theexhaust pipe 231. In this case, the plasma-excited N2 gas is supplied to thewafer 200. - At the same time, N2 gas is supplied into the ninth
gas supply pipe 232 i by opening the valve 243 i of the ninthgas supply pipe 232 i. The N2 gas flows through the ninthgas supply pipe 232 i, and the flow rate of the N2 gas is adjusted by theMFC 241 g. The N2 gas having the adjusted flow rate passes through the thirdgas supply pipe 232 c, and is then supplied into thebuffer chamber 237 c via the gas supply holes 248 c of thethird nozzle 233 c. In this case, the N2 gas supplied into thebuffer chamber 237 c is plasma-excited by supplying high-frequency power between the first and second rod-shapedelectrodes frequency power source 273 via theimpedance matching unit 272, and supplied as an excited species (N2*) into theprocess chamber 201 via the gas supply holes 238 c and then exhausted via theexhaust pipe 231. In this case, the plasma-excited N2 gas is supplied to thewafer 200. - In this case, in order to prevent the plasma-excited N2 gas from being supplied into the
first nozzle 233 a, N2 gas is supplied into the first inertgas supply pipe 232 j by opening thevalve 243 j. The N2 gas is supplied into theprocess chamber 201 via the firstgas supply pipe 232 a and thefirst nozzle 233 a, and is exhausted via theexhaust pipe 231. - When the excited species obtained by plasma-exciting the N2 gas is supplied, the pressure in the
process chamber 201 is controlled, e.g., to fall within a range of 10 to 1,000 Pa, by appropriately controlling theAPC valve 244. The supply flow rate of the N2 gas is controlled by each of theMFCs 241 h and 241 i, for example, to fall within a range of 100 to 10,000 sccm (0.1 to 10 slm). The supply flow rate of the N2 gas is controlled by theMFC 241 j, for example, to fall within a range of 100 to 2,000 sccm (0.1 to 2 slm). A time period in which the excited species obtained by plasma-exciting the N2 gas is supplied to thewafer 200, i.e., a gas supply time (irradiation time), is set to range, for example, from 1 to 120 seconds. When the throughput is considered, the temperature of theheater 207 is set to be the same as when the DCS gas is supplied inStep 1b, that is, the temperature of the wafer 200 (or the temperature in the process chamber 201) inSteps 1b through 6b may be maintained constant to fall within a range of 300 to 650° C., preferably, a range of 300 to 600° C., and more preferably, a range of 300 to 550° C., as in the first embodiment. The high-frequency power supplied from the high-frequency power source 273 between the first and second rod-shapedelectrodes electrodes - Impurities may be removed from the SiN layer by performing the second modifying process (
Step 6b) described above using Ar gas or N2 gas as a modifying gas. Thereafter, a SiN film may be formed on thewafer 200 to a desired thickness by repeatedly performing onecycle including Steps 1b through 6b a predetermined number of times, and preferably, several times. - According to the present embodiment, the same effects as in first embodiment may also be achieved.
- Thickness uniformity of the SiN film in a plane of the
wafer 200 may be more improved when Ar gas or N2 gas is used as a modifying gas than when H2 gas is used as a modifying gas. This seems to be because excited species obtained by plasma-exciting Ar gas or N2 gas are heavier than those obtained by plasma-exciting H2 gas, and the elements of the SiN film may thus be decomposed or desorbed near an edge portion of thewafer 200 at which a film is likely to have be thick, when Ar gas or N2 gas is used as a modifying gas. - Also, an etching rate of the SiN film, i.e., the quality of the SiN film, in a plane of the
wafer 200 may be more improved when H2 gas is used as a modifying gas than when Ar gas or N2 gas is used as a modifying gas. This seems to be because an excited species obtained by plasma-exciting H2 gas has a longer lifespan than excited species obtained by plasma-exciting Ar gas or N2 gas. Thus, excited species may be more efficiently supplied to a central part of thewafer 200 when H2 gas is used as a modifying gas. Thus, desorbing of impurities from a silicon-containing layer or the SiN layer at the central part of thewafer 200 may be greatly promoted. - In the film-forming sequence described above, H2 gas is used as a modifying gas in the first modifying process and Ar gas or N2 gas is used as a modifying gas in the second modifying process. Reversely, Ar gas or N2 gas may be used as a modifying gas in the first modifying process, and H2 gas may be used as a modifying gas in the second modifying process. However, the first and second modifying processes are not limited to a case in which H2 gas, N2 gas, or Ar gas is used as a modifying gas, and instead, an arbitrary combination of H2 gas, N2 gas, and Ar gas may be used as a modifying gas.
- In the first embodiment, a process of plasma-exciting and supplying a modifying gas is performed after a source gas is supplied and before a nitrogen-containing gas is supplied, and after a nitrogen-containing gas is supplied and before a source gas is supplied, but the present invention is not limited thereto. For example, the process of plasma-exciting and supplying a modifying gas may be performed only after a source gas is supplied and before a nitrogen-containing gas is supplied. That is, although in the first embodiment, both the first and second modifying processes are performed, the present invention is not limited thereto, and only the first modifying process may be performed and the second modifying process may be skipped.
- In the present embodiment, a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, and supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate.
- Specifically, in a film-forming sequence according to the present embodiment, a SiN film is formed on the
wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to thewafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H2 gas to thewafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH3 gas to thewafer 200 in the process chamber 201 (NH3 gas supply process), and purging the process chamber 201 (second purging process). The film-forming sequence according to the present embodiment will now be described in greater detail. -
FIG. 7 is a flowchart illustrating a method of forming a film according to the third embodiment of the present invention.FIG. 12 is a diagram illustrating timing of supplying a gas and plasma power according to the third embodiment of the present invention. The present embodiment is substantially the same as the first embodiment, except that a process of plasma-exciting and supplying a modifying gas is performed only after a source gas is supplied and before a nitrogen-containing gas is supplied (that is, the second modifying process is skipped). As illustrated inFIGS. 7 and 12 , in the present embodiment, a SiN film may be formed on thewafer 200 to a desired thickness by performing one cycle a predetermined number of times, and preferably, several times, thecycle including Steps 1c through 5c, similar toSteps 1a through 5a in the first embodiment. - The same effects as in the first embodiment may also be achieved according to the present embodiment. Also, compared to the first embodiment, a time needed to perform each cycle may be reduced by skipping the second modifying process, thereby increasing a film-forming rate.
- In the first embodiment, a process of plasma-exciting and supplying a modifying gas is performed after a source gas is supplied and before a nitrogen-containing gas is supplied, and after a nitrogen-containing gas and before a source gas is supplied, but the present invention is not limited thereto. For example, the process of plasma-exciting and supplying a modifying gas may be performed only after a nitrogen-containing gas is supplied and before a source gas is supplied. That is, although in the first embodiment, both the first and second modifying processes are performed, the present invention is not limited thereto, and the first modifying process may be skipped and only the second modifying process may be performed.
- In the present embodiment, a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying a plasma-excited hydrogen-containing gas to the substrate.
- Specifically, in a film-forming sequence according to the present embodiment, a SiN film is formed on the
wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to thewafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited NH3 gas to thewafer 200 in the process chamber 201 (NH3 gas supply process), purging the process chamber 201 (second purging process), and supplying plasma-excited H2 gas to thewafer 200 in the process chamber 201 (second modifying process). The film-forming sequence according to the present embodiment is described in greater detail below. -
FIG. 8 is a flowchart illustrating a method of forming a film according to the fourth embodiment of the present invention.FIG. 13 is a diagram illustrating timing of supplying a gas and plasma power according to the fourth embodiment of the present invention. The present embodiment is substantially the same as the first embodiment, except that a process of plasma-exciting and supplying a modifying gas is performed only after a nitrogen-containing gas is supplied and before a source gas is supplied (that is, the first modifying process is skipped). As illustrated inFIGS. 8 and 13 , in the present embodiment, a SiN film may be formed on thewafer 200 to a desired thickness by performing one cycle a predetermined number of times, and preferably, several times, thecycle including Steps 1d through 5d, similar toSteps - The same effects as in the first embodiment may also be achieved according to the present embodiment. Also, compared to the first embodiment, a time needed to perform each cycle may be reduced by skipping the first modifying process, thereby increasing a film-forming rate.
- In the second embodiment, the process of purging the process chamber 201 (second purging process) is provided between the process of supplying a nitrogen-containing gas (NH3 gas supply process) and the process of plasma-exciting and supplying a modifying gas (second modifying process), but the present invention is not limited thereto. For example, the second purging process may be skipped, and the NH3 gas supply process and the second modifying process may be continuously performed.
- In the present embodiment, a nitride film is formed on a substrate by performing one cycle a predetermined number of times, the cycle including supplying a source gas to the substrate, supplying a plasma-excited hydrogen-containing gas to the substrate, supplying a plasma-excited or thermally excited nitriding gas (nitrogen-containing gas) to the substrate, and supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
- Specifically, in a film-forming sequence according to the present embodiment, a SiN film is formed on the
wafer 200 by performing one cycle a predetermined number of times, the cycle including supplying DCS gas to thewafer 200 in the process chamber 201 (DCS gas supply process), purging the process chamber 201 (first purging process), supplying plasma-excited H2 gas to thewafer 200 in the process chamber 201 (first modifying process), supplying plasma-excited NH3 gas to thewafer 200 in the process chamber 201 (NH3 gas supply process), and a process of supplying at least one of plasma-excited H2 gas and plasma-excited Ar gas to thewafer 200 in the process chamber 201 (second modifying process). The film-forming sequence according to the present embodiment will be described in greater detail below. -
FIG. 9 is a flowchart illustrating a method of forming a film according to the fifth embodiment of the present invention.FIG. 14 is a diagram illustrating timing of supplying a gas and plasma power according to the fifth embodiment of the present invention. The present embodiment is substantially the same as the second embodiment, except that the second purging process is skipped, and the NH3 gas supply process and the second modifying process are continuously performed. As illustrated inFIGS. 9 and 14 , in the present embodiment, a SiN film may be formed on thewafer 200 to a desired thickness by performing one cycle a predetermined number of times, and preferably, several times, thecycle including Steps 1e through 5e, similar toSteps 1b through 4b and 6b a in the second embodiment. - The same effects as in the second embodiment may also be achieved according to the present embodiment. Also, compared to the second embodiment, a time needed to perform each cycle may be reduced by skipping the second purging process, thereby increasing a film-forming rate.
- Although various embodiments of the present invention have been described above in detail, the present invention is not limited thereto and various changes may be made with respect to the embodiments without departing from the scope of the invention.
- For example, a case in which DCS gas is used as a source gas has been described in the embodiments described above, but the present invention is not limited thereto. For example, the present invention may also be applied to a case in which MCS gas is used as a source gas. An amount of chlorine to be supplied into the
process chamber 201 may be reduced using the MCS gas having a lower chlorine (Cl) content and a higher surface adsorption rate than the DCS gas as a source gas. Thus, an amount of chlorine bonded with a silicon-containing layer, i.e., Si—Cl bonds, may be reduced to form a silicon-containing layer having a low concentration of chlorine. As a result, inStep 4a, a SiN layer having a low concentration of chlorine may be formed. Thus, a SiN film having a low concentration of impurities therein, i.e., a SiN film having a high film density, may be formed, and the resistance of the SiN film to hydrogen fluoride may be improved. Also, the insulating properties of the SiN film may be improved. - Si—H bonds included in the silicon-containing layer may be increased by reducing Si—Cl bonds included in the silicon-containing layer using the MCS gas as a source gas. A Si—Cl bond has higher bonding energy than a Si—H bond, and acts to hinder formation of a Si—N bond, i.e., nitriding of the silicon-containing layer, in
Step 4a. On the other hand, the Si—H bond has lower bonding energy than the Si—Cl bond, and acts to promote formation of a Si—N bond, i.e., nitriding of the silicon-containing layer, inStep 4a. That is, when the MCS gas is used as a source gas to form a silicon-containing layer having a small number of Si—Cl bonds and a low concentration of chlorine, factors that hinder the nitriding of the silicon-containing layer may be reduced and the nitriding of the silicon-containing layer may be promoted inStep 4a. Also, when a number of Si—H bonds in the silicon-containing layer is increased, factors promoting the nitriding of the silicon-containing layer may increase and the nitriding of the silicon-containing layer may be promoted inStep 4a. As described above, the efficiency of the nitriding of the silicon-containing layer inStep 4a may be increased, and a time needed for the nitriding of the silicon-containing layer may be reduced, thereby reducing a process time. Accordingly, a time needed to form the SiN film may be reduced, thereby increasing the yield. - Also, when MCS gas is used as a source gas, a temperature adjustment mechanism that maintains stored MCS gas at a constant temperature, e.g., of about 30° C., may be installed either in an MCS gas source that supplies MCS gas to the first
gas supply pipe 232 a or at an upstream side of the firstgas supply pipe 232 a, i.e., a gas storage place or a cylinder cabinet, etc. MCS gas has a high decomposition rate and is likely to be decomposed at a temperature at which a general special high-pressure gas is stored. When MCS gas is decomposed to generate monosilane (SiH4), thickness uniformity of the SiN film may be degraded or the yield may become worse. Also, when the temperature at which MCS gas is stored is too low, the MCS gas is not easily vaporized and the supply flow rate of the MCS gas into theprocess chamber 201 may be reduced. The temperature adjustment mechanism may be installed to solve such problems. - Also, in the embodiments described above, when a source gas is supplied into the process chamber 201 (
Step 1a), the source gas is supplied into theprocess chamber 201 by continuously exhausting the inside of theprocess chamber 201 while theAPC valve 244 is open, but the present invention is not limited thereto. For example, as illustrated inFIG. 3 , a gas storage unit (or tank) 250 a may be installed at the firstgas supply pipe 232 a at a downstream side of thevalve 243 a, a high-pressure source gas collected in thegas storage unit 250 a may be supplied at once (to a pulse state) into the reduced-pressure process chamber 201 while theAPC valve 244 is closed, and then the inside of theprocess chamber 201 which is in an increased pressure by the supply of the source gas may be maintained for a predetermined time. - In order to supply the source gas at once using the
gas storage unit 250 a, first, the source gas is collected in thegas storage unit 250 a by closing avalve 243 a′ installed at the firstgas supply pipe 232 a at a downstream side of thegas storage unit 250 a and opening thevalve 243 a installed at an upstream side of thegas storage unit 250 a. Then, when a desired amount of the source gas having a specific pressure is collected in thegas storage unit 250 a, thevalve 243 a installed at the upstream side of thegas storage unit 250 a is closed. In thegas storage unit 250 a, the source gas is collected such that pressure in thegas storage unit 250 a may be equal to or greater than, e.g., 20,000 Pa. The amount of the source gas collected in thegas storage unit 250 a may range, for example, from 100 to 1,000 cc. Also, an apparatus is configured such that a conductance between thegas storage unit 250 a and theprocess chamber 201 may be equal to or greater than 1.5×10−3 m3/s. When a ratio between the capacity of theprocess chamber 201 and the capacity of thegas storage unit 250 a therefor is considered, if the capacity of theprocess chamber 201 is, for example, 100 liters, then the capacity of thegas storage unit 250 a may be 100 to 300 cc and may be 1/1,000 to 3/1,000 of the capacity of theprocess chamber 201. - While the inside of the
gas storage unit 250 a is filled with the source gas, the inside of theprocess chamber 201 is exhausted using thevacuum pump 246 such that pressure in theprocess chamber 201 may be less than or equal to 20 Pa. After the filling of the inside of thegas storage unit 250 a with the source gas and the exhausting of theprocess chamber 201 are completed, theAPC valve 244 is closed to discontinue the exhausting of theprocess chamber 201, and then thevalve 243 a′ of the firstgas supply pipe 232 a is opened. Thus, the high-pressure source gas collected in thegas storage unit 250 a is supplied at once (to a pulse state) into theprocess chamber 201. In this case, since theAPC valve 244 of theexhaust pipe 231 is closed, the pressure in theprocess chamber 201 sharply increases to, for example, 931 Pa (7 Torr). Then, an increased-pressure state in theprocess chamber 201 is maintained for a predetermined time, e.g., 1 to 10 seconds, and thewafer 200 is exposed to a high-pressure atmosphere of DCS gas so as to form a silicon-containing layer on thewafer 200. - If the source gas is supplied at once using the
gas storage unit 250 a as described above, then the speed of the source gas ejected from thefirst nozzle 233 a into theprocess chamber 201 is accelerated, for example, up to the speed of sound (340 m/sec) due to the difference between pressures in thegas storage unit 250 a and theprocess chamber 201, thereby increasing the speed of the source gas supplied to thewafer 200 to about several tens msec. As a result, the source gas is efficiently supplied to theentire wafer 200 including the central part of thewafer 200. Thus, the thickness and quality of the SiN film in a plane of thewafer 200 may be uniformly improved. Hereinafter, the method of supplying the source gas described above will be referred to as a ‘flash flow.’ - In the embodiments described above, two plasma generation units (excitation units) are installed, but the present invention is not limited thereto. For example, the present invention may also be applied to a case in which one plasma generation unit (excitation unit) is installed. However, when a plurality of plasma generation units (excitation units) are installed, the performance of a nitriding process or a modifying process in a plane of the
wafer 200 may be greatly improved, and the quality and thickness of the SiN film in the plane of thewafer 200 may be more uniformly improved, as described above. In other words, when a plurality of plasma generation units are installed, the effects of the nitriding process, the first modifying process, and the second modifying process may be further improved. Furthermore, the present invention may be applied to a case in which three or more plasma generation units (excitation units) are installed. - In the second and fifth embodiments described above, the process of supplying a plasma-excited hydrogen-containing gas is performed during a specific time period after the process of supplying a source gas, i.e., while supply of a plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas, and the process of supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas is performed during a specific time period after the process of supplying a plasma-excited or thermally excited nitriding gas, i.e., while supply of a source gas is suspended after the process of supplying a plasma-excited or thermally excited nitriding gas, but the present invention is not limited thereto.
- For example, the process of supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas may be performed during a specific time period after the process of supplying a source gas, i.e., while supply of a plasma-excited or thermally excited nitriding gas is suspended after the process of supplying a source gas, and the process of supplying a plasma-excited hydrogen-containing gas may performed during a specific time period after the process of supplying a plasma-excited or thermally excited nitriding gas, i.e., while supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas.
- In other words, the process of supplying a plasma-excited hydrogen-containing gas is performed during the specific time period after the process of supplying the source gas or during the specific time period after the process of supplying the plasma-excited or thermally excited nitriding gas. The process of supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas may be performed during the specific time period after the process of supplying the source gas or during the specific time period after the process of supplying the plasma-excited or thermally excited nitriding gas, in which the process of supplying a plasma-excited hydrogen-containing gas is not performed.
- Specifically, the process of supplying the plasma-excited hydrogen-containing gas may be performed while the supply of the plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas or while the supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas. The process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed while the supply of the plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas or while the supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas, in which the process of supplying the plasma-excited hydrogen-containing gas is not performed.
- More specifically, the process of supplying the plasma-excited hydrogen-containing gas is performed after the process of supplying the source gas and before the process of supplying the plasma-excited or thermally excited nitriding gas, and after the process of supplying the plasma-excited or thermally excited nitriding gas and before the process of supplying the source gas. The process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed after the process of supplying the source gas and before the process of supplying the plasma-excited or thermally excited nitriding gas; and after the process of supplying the plasma-excited or thermally excited nitriding gas and before the process of supplying the source gas, in which the process of supplying the plasma-excited hydrogen-containing gas is not performed.
- In this case, a layer (silicon-containing layer) is formed on a substrate during the process of supplying the source gas, a first modifying process is performed to the layer during the process of supplying the plasma-excited hydrogen-containing gas, the layer to which the first modifying process is performed is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas, and a second modifying process is performed to the nitride layer during the process of supplying the at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas.
- Otherwise, a layer is formed on the substrate during the process of supplying the source gas, a first modifying process is performed to the layer during the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas, the layer to which the first modifying process is performed is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas, and a second modifying process is performed to the nitride layer during the process of supplying the plasma-excited hydrogen-containing gas.
- Otherwise, for example, both the process of supplying the plasma-excited hydrogen-containing gas and the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed during a specific time period after the process of supplying the plasma-excited or thermally excited nitriding gas, i.e., while the supply of the source gas is suspended after the process of supplying the plasma-excited or thermally excited nitriding gas, i.e., after the process of supplying the plasma-excited or thermally excited nitriding gas and before the process of supplying the source gas.
- Otherwise, for example, both the process of supplying the plasma-excited hydrogen-containing gas and the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas may be performed during a specific time period after the process of supplying the source gas, i.e., while the supply of the plasma-excited or thermally excited nitriding gas is suspended after the process of supplying the source gas, i.e., after the process of supplying the source and before the process of supplying the plasma-excited or thermally excited nitriding gas.
- In this case, a layer (silicon-containing layer) is formed on the substrate during the process of supplying the source gas, the layer is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas, the first modifying process is performed to the nitride layer during the process of supplying the plasma-excited hydrogen-containing gas, and the second modifying process is performed to the nitride layer during the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas.
- Otherwise, a layer is formed on the substrate during the process of supplying the source gas, the first modifying process is performed to the layer during the process of supplying the plasma-excited hydrogen-containing gas, the second modifying process is performed to the layer during the process of supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas, and the layer to which the first and second modifying processes are performed is changed into a nitride layer during the process of supplying the plasma-excited or thermally excited nitriding gas.
- Also, when a film is formed based on the film-forming sequence according to the second or fifth embodiment among the embodiments described above, the effects of the first and second modifying processes may be maximized.
- The SiN films formed according to the embodiments described above have a low concentration of chlorine therein and a high film density, and are highly resistant to hydrogen fluoride. Thus, the SiN films formed according to the embodiments described above may be preferably used as a gate insulating film, a capacitive insulating film, sidewall spacers, an etching stopper layer, or the like. Also, the SiN film may be preferably used as a hard mask during a process of forming a silicon trench isolation (STI) layer.
- In the embodiments described above, a method of forming a SiN film containing silicon (a semiconductor element) as a nitride film has been described above, but the present invention is not limited thereto. For example, the present invention may also be applied to a case in which a metal nitride film including a metallic element, such as titanium (Ti), zirconium (Zr), hafnium (Hf), tantalum (Ta), aluminum (Al), or molybdenum (Mo), is formed.
- For example, the present invention may also be applied to a case in which a titanium nitride (TiN) film is formed, a zirconium nitride (ZrN) film is formed, a hafnium nitride (HfN) film is formed, a tantalum nitride (TaN) film is formed, an aluminum nitride (AlN) film is formed, or a molybdenum nitride (MoN) film is formed.
- In this case, such films may be formed using a material including metal elements as a source gas according to the same film-forming sequence as in the embodiments described above. When a liquid source that is in a liquid state at normal temperature and pressure, the liquid source is vaporized by a vaporizing system, such as a vaporizer or a bubbler, and is then supplied as the source gas. Also, the same nitrogen-containing gas and modifying gas as in the embodiments described above may be used. The same process conditions as in the embodiments described above may also be used.
- For example, when a TiN film is formed, titanium tetrachloride (TiCl4), tetrakis(ethylmethylamino)titanium (Ti[N(C2H5)(CH3)]4, abbreviated to TEMAT), tetrakis(dimethylamino)titanium (Ti[N(CH3)2]4, abbreviated to TDMAT), or tetrakis(diethylamino)titanium (Ti[N(C2H5)2]4, abbreviated to TDEAT) may be used as a source element.
- For example, when a ZrN film is formed, zirconium tetrachloride (ZrCl4), tetrakis(ethylmethylamino)zirconium (Zr[N(C2H5(CH3)]4, abbreviated to TEMAZ), tetrakis(dimethylamino)zirconium (Zr[N(CH3)2]4, abbreviated to TDMAZ), or tetrakis(diethylamino)zirconium (Zr[N(C2H5)2]4, abbreviated to TDEAZ) may be used as a source element.
- For example, when a HfN film is formed, hafnium tetrachloride (HfCl4), tetrakis(ethylmethylamino)hafnium (Hf[N(C2H5(CH3)]4, abbreviated to TEMAH), tetrakis(dimethylamino)hafnium (Hf[N(CH3)2]4, abbreviated to TDMAH), or tetrakis(diethylamino)hafnium (Hf[N(C2H5)2]4, abbreviated to TDEAH) may be used as a source element.
- For example, when a TaN film is formed, tantalum pentachloride (TaCl5), tantalum pentafluoride (TaF5), pentaethoxy tantalum (Ta(OC2H5)5, abbreviated to: PET), or tert-butylimino tris(diethylamino)tantalum (Ta(NC(CH3)3)(N(C2H5)2)3, abbreviated to: TBTDET) may be used as a source element.
- For example, when an AlN film is formed, aluminum trichloride (AlCl3), aluminum trifluoride (AlF3), or trimethyl aluminum (Al(CH3)3, abbreviated to: TMA) may be used as a source element.
- For example, when a MoN film is formed, molybdenum pentachloride (MoCl5), or molybdenum pentafluoride (MoF5) may be used as a source element.
- As described above, the present invention may be applied not only a case in which a SiN film is formed but also a case in which a metal nitride film is formed. In this case, the same effects as in the embodiments described above may also be achieved. That is, the present invention may also be applied to formation of a nitride film including a specific element, such as a semiconductor element or a metal element.
- A case in which a thin film is formed using a batch-type substrate processing apparatus capable of processing a plurality of substrates at a time has been described in the embodiments described above, but the present invention is not limited thereto, and a thin film may be formed using a single-wafer type substrate processing apparatus capable of processing one or several substrates at a time.
- Also, an appropriate combination of the embodiments, modified examples, or application examples described above may be used.
- The present invention may also be realized by changing, for example, a program recipe of the existing substrate processing apparatus. To change the program recipe, a program recipe according to the present invention may be installed in the existing substrate processing apparatus via an electric communication line or a recording medium storing the program recipe according to the present invention, or the program recipe of the existing substrate processing apparatus may be replaced with the program recipe according to the present invention by manipulating an input/output device of the existing substrate processing apparatus.
- In Example 1 of the present invention,
Sample 1 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the third embodiment (wherein only a first modifying process is performed and a second modifying process is skipped). DCS gas was used as a source gas, NH3 gas was used as a nitrogen-containing gas, and Ar gas was used as a modifying gas during the first modifying process. - Also, in Example 1,
Sample 2 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to a film-forming sequence as described with respect to the fourth embodiment (wherein the first modifying process is skipped and only the second modifying process is performed). DCS gas was used as a source gas, NH3 gas was used as a nitrogen-containing gas, and Ar gas was used as a modifying gas during the second modifying process. - Also, as a Comparative Example,
Sample 3 was obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence. The cycle included supplying DCS gas to the wafer, purging the process chamber, supplying plasma-excited NH3 gas to the wafer in the process chamber, and purging the process chamber. - For convenience of explanation,
FIG. 15A illustrates only one cycle of a sequence of supplying a gas during the forming of the SiN film to obtain each ofSamples 1 to 3. All ofSamples 1 to 3 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated inFIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow. The temperature of the wafer was set to 550° C. when the SiN film was formed. The other process conditions were set to be substantially the same as those in the embodiments described above. - Then, wet-etching rates (WERs) of the SiN films (
Samples 1 to 3) were measured. When the SiN films were wet-etched, a liquid containing a hydrogen fluoride content of about 1% was used. -
FIG. 15B is a graph illustrating results of measuring the WERs of the SiN films (Samples 1 to 3). InFIG. 15B , a horizontal axis denotesSamples 1 to 3, and a vertical axis denotes the WERs thereof (Å/min). Here, ‘WER’ means an average of wet-etching rates in a plane of the wafer. - Referring to
FIG. 15B , it could be seen that the SiN film had low WERs and was highly resistant to hydrogen fluoride inSamples 1 and 2 (Example 1) to which a modifying process of supplying plasma-excited Ar gas to a silicon-containing layer or a SiN layer was performed, compared to in Sample 3 (Comparative Example) to which the modifying process was not performed. This seems to be because an excited species obtained by plasma-exciting Ar gas through the modifying process allowed impurities, such as hydrogen or chlorine, to be efficiently desorbed from the silicon-containing layer or the SiN layer, thereby improving the quality of the SiN film. - Furthermore, it could be seen that
Sample 1 obtained by performing only the first modifying process and skipping the second modifying process had a lower WER and a higher resistance to hydrogen fluoride thanSample 2 obtained by skipping the first modifying process and performing only the second modifying process. This seems to be because impurities, such as hydrogen or chlorine, in the silicon-containing layer are more efficiently desorbed from the silicon-containing layer through the first modifying process performed immediately after the silicon-containing layer is formed than through the second modifying process performed after the silicon-containing layer is modified into a SiN layer, due to desorbing reaction of DCS gas. - <Effects According to Pressure in Modifying Process>
- Then, in Example 1,
Samples 4 to 7 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the third embodiment (wherein only a first modifying process is performed and a second modifying process is skipped). DCS gas was used as a source gas, NH3 gas was used as a nitrogen-containing gas, and Ar gas was used as a modifying gas during the first modifying process. WhenSamples 4 to 7 were obtained, pressures in the process chamber during the first modifying process were sequentially set to 85 Pa, 44.5 Pa, 21.5 Pa, and 12 Pa. - For convenience of explanation,
FIG. 16A illustrates only one cycle of a sequence of supplying a gas during the forming of the SiN film to obtain each ofSamples 4 to 7. AllSamples 4 to 7 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated inFIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow. The temperature of the wafer was set to 550° C. when the SiN film was formed. The other process conditions were set to be substantially the same as those in the embodiments described above. - Then, WERs of the SiN films (
Samples 4 to 7), the range of the WERS in a plane of the wafer, and the distribution of the WERs in the plane of the wafer were measured. When the SiN films were wet-etched, a liquid containing a hydrogen fluoride content of about 1% was used. -
FIG. 16B is a graph illustrating a result of measuring the WERs of the SiN films (Samples 4 to 7). InFIG. 16B , a horizontal axis denotesSamples 4 to 7, and a vertical axis denotes the WERs thereof (Å/min). Here, ‘WER’ means an average of the wet-etching rates in the plane of the wafer. -
FIG. 17A is a graph illustrating a result of measuring a range of the WERs of the SiN films (Samples 4 to 7) in a plane of a wafer according to Example 1 of the present invention. InFIG. 17A , a horizontal axis denotesSamples 4 to 7, and a vertical axis denotes the WERs thereof (Å/min). Here, ‘WER’ means an average of the wet-etching rates in the plane of the wafer. The range of WERs in the plane of the wafer means the difference between a maximum WER and minimum WER in the plane of the wafer. -
FIG. 17B is a graph illustrating a result of measuring a distribution of the WERs of the SiN films (Samples 4 to 7) in a plane of a wafer according to Example 1 of the present invention. InFIG. 17B , a horizontal axis denotes measurement positions inSamples 4 to 7, and a vertical axis denotes WERs thereof (Å/min). The WERs were measured along the diameter of the wafer. In the horizontal axis, ‘0 mm’ means a result of measuring the distribution of WERs at a central portion of the wafer, and ‘±150 mm’ means a result of measuring the distribution of WERs at an edge portion of the wafer. - Referring to
FIG. 16B , it could be seen that, during the first modifying process, a lower pressure in the process chamber led to a lower WER of a SiN film, thereby improving the resistance of the SiN film to hydrogen fluoride. This seems to because when the pressure in the process chamber during the first modifying process is lowered, the lifespan of an excited species obtained by plasma-exciting Ar gas may increase and the excited species may be more efficiently supplied to the wafer, thereby improving the quality of the SiN film. - Also, referring to
FIGS. 17A and 17B , it could be seen that, during the first modifying process, the lower the pressure in the pressure chamber, the less the range of WERs in the plane of the wafer, thereby equalizing the distribution of WERs in the plane of the wafer. This seems to be because during the first modifying process, when the pressure in the process chamber is lowered, the lifespan of an excited species obtained by plasma-exciting Ar gas may increase and the excited species may thus be more efficiently supplied to the central portion of the wafer, thereby uniformly improving the quality of the SiN film in the plane of the wafer. - In Example 2 of the present invention,
Sample 1 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the third embodiment (wherein only a first modifying process is performed and a second modifying process is skipped). DCS gas was used as a source gas, NH3 gas was used as a nitrogen-containing gas, and Ar gas was used as a modifying gas during the first modifying process. - Also, in Example 2 of the present invention,
Samples 2 to 4 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the first embodiment (wherein both a first modifying process and a second modifying process are performed using the same modifying gas). Similarly, DCS gas was used as a source gas and NH3 gas was used as a nitrogen-containing gas. Ar gas was used as a modifying gas during the first and second modifying processes to obtainSample 2. H2 gas was used as a modifying gas during the first and second modifying processes to obtainSample 3. N2 gas was used as a modifying gas during the first and second modifying processes to obtainSample 4. - Also, in Example 2 of the present invention,
Sample 5 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the second embodiment (wherein different kinds of modifying gases are used during a first modifying process and a second modifying process). Similarly, DCS gas was used as a source gas and NH3 gas was used as a nitrogen-containing gas. H2 gas was used as a modifying gas during the first modifying process. N2 gas was used as a modifying gas during the second modifying process. - Also, as a Comparative Example,
Sample 6 was obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence. The cycle includes supplying DCS gas, purging the process chamber, supplying plasma-excited NH3 gas to the wafer in the process chamber, and purging the process chamber. - For convenience of explanation,
FIG. 18A illustrates only one cycle included in a sequence of supplying a gas during the forming of the SiN film to obtain each ofSamples 1 to 6. All ofSamples 1 to 6 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated inFIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow. The temperature of the wafer was set to 550° C. when the SiN film was formed. The other process conditions were set to be substantially the same as those in the embodiments described above. - Then, WERs of the SiN films (
Samples 1 to 6), a range of the WERs in a plane of the wafer, a distribution of the WERs in the plane of the wafer, and a distribution of thicknesses of the SiN films (Samples 1 to 6) in the plane of the wafer were measured. When the SiN films were wet-etched, a liquid containing a hydrogen fluoride content of about 1% was used. -
FIG. 18B is a graph illustrating a result of measuring the WERs of the SiN films (Samples 1 to 5). InFIG. 18B , a horizontal axis denotesSamples 1 to 5, and a vertical axis denotes the WERs thereof (Å/min). Here, ‘WER’ means an average of the WERs in the plane of the wafer. The results of measuring a WER of the SiN film (Sample 6) was the same as that of the SiN film (Sample 3) in Example 1 and is thus not illustrated here. -
FIG. 19A is a graph comparing results of measuring a range of WERs of the SiN films (Samples 1 to 6) in a plane of a wafer according to Example 2 of the present invention and the Comparative Example. InFIG. 19A , a horizontal axis denotesSamples 1 to 6, and a vertical axis denotes the ranges of WERs thereof (Å/min) in the plane of the wafer. -
FIG. 19B is a graph illustrating a result of measuring distributions of WERs of the SiN films (Samples 1 to 5) in a plane of a wafer according to Example 2 of the present invention and the Comparative Example. InFIG. 19B , a horizontal axis denotes measurement positions onSamples 1 to 5, and a horizontal axis denotes the WERs thereof (Å/min). The WERs were measured along the diameter of the wafer. In the horizontal axis, ‘0 mm’ means a result of measuring the distribution of WERs at a central portion of the wafer, and ‘±150 mm’ means a result of measuring the distribution of WERs at an edge portion of the wafer. -
FIG. 20 is a graph illustrating results of measuring thickness uniformity of the SiN films (Samples 1 to 6) in a plane of the wafer. InFIG. 20 , a horizontal axis denotesSamples 1 to 6, and a vertical axis denotes the thickness uniformity (±%) of the SiN films (Samples 1 to 6) in the plane of the wafer.FIG. 20 shows that the smaller the number on the vertical axis, the higher the thickness uniformity of the SiN film. - Referring to
FIG. 18B , it could be seen that, inSamples 1 to 5 to which a modifying process is performed, all the WERs of the SiN films were low and the SiN films thus had improved resistance to hydrogen fluoride, compared to Sample 6 (Comparative Example) in which a modifying process was not performed. In other words, it could be seen that the SiN film had improved quality and high resistance to hydrogen fluoride when Ar gas was used as a modifying gas (Samples 1 and 2), when H2 gas was used as a modifying gas (Sample 3), and when N2 gas was used as a modifying gas (Sample 4). In the case ofSample 5 obtained using different types of modifying gases during the first and second modifying processes, it could be seen that the SiN film also had improved quality and high resistance to hydrogen fluoride. That is, it could be seen that, if any combination of Ar gas, H2 gas, and N2 gas is used as a modifying gas, impurities, such as hydrogen or chlorine, may be efficiently desorbed from the silicon-containing layer or the SiN layer, thereby improving the quality of the SiN film. - Referring to
FIGS. 19A and 19B , it could be seen that, in the case ofSample 3 obtained using H2 gas as a modifying gas during the first and second modifying processes, a range of WERs of the SiN film in the plane of the wafer was lowest and the uniformity of the WERs in the plane of the wafer was highest. In the case ofSample 5 obtained using H2 gas as a modifying gas during the first modifying process and using N2 gas as a modifying gas during the second modifying process, it could be seen that a range of WERs of the SiN film in the plane of the wafer was second lowest and the uniformity of the WERs in the plane of the wafer was second highest. This seems to be because an excited species obtained by plasma-exciting H2 gas has a longer lifespan than excited species obtained by plasma-exciting Ar gas or N2 gas. Thus, an excited species may be more efficiently supplied to a central part of thewafer 200 when H2 gas is used as a modifying gas. Thus, desorbing of impurities from the SiN film at the central part of thewafer 200 may be greatly promoted. - Also, referring to
FIG. 20 , it could be seen that thickness uniformity of the SiN film in the plane of the wafer was high in the case ofSample 2 obtained using Ar gas as a modifying gas during the first and second modifying processes orSample 4 obtained using N2 gas as a modifying gas during the first and second modifying processes. On the other hand, it could be seen that thickness uniformity of the SiN film in the plane of the wafer was low in the case ofSample 3 obtained using H2 gas as a modifying gas during the first and second modifying processes. This seems to be because excited species obtained by plasma-exciting Ar gas or N2 gas are heavier than those obtained by plasma-exciting H2 gas, and the elements of the SiN film may thus be decomposed or desorbed near an edge portion of thewafer 200 at which a film is likely to be thick, when Ar gas or N2 gas is used as a modifying gas. Also, it seems to be relatively difficult for the elements of the SiN film to decompose or be desorbed near an edge portion of thewafer 200 when a relatively light excited species like an excited species obtained by plasma-exciting H2 gas is used. However, in the case ofSample 5 obtained using H2 gas as a modifying gas during the first modifying process and using N2 gas as a modifying gas during the second modifying process, it could be seen that the thickness uniformity of the SiN film in the plane of the wafer was desirable. From the results, it could be seen that, even if H2 gas was used as a modifying gas during one modifying process, the thickness uniformity of the SiN film in the plane of the wafer was desirable when N2 gas or Ar gas was used as a modifying gas during another modifying process. - From the above results, it may be concluded that, for example, in the case of
Sample 5, WERs (i.e., film quality) and thickness of a SiN film in the plane of the wafer were uniformly improved when the SiN film was formed using H2 gas as a modifying gas during the first modifying process and using N2 gas as a modifying gas during the second modifying process, i.e., using H2 gas as a modifying gas during one modifying process and using N2 gas or Ar gas as a modifying gas during another modifying process. - In Example 3 of the present invention,
Samples 1 to 4 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the second embodiment (wherein different kinds of modifying gases are used during a first modifying process and a second modifying process). Similarly, DCS gas was used as a source gas and NH3 gas was used as a nitrogen-containing gas. H2 gas was used as a modifying gas during the first modifying process. N2 gas was used as a modifying gas during the second modifying process.Samples 1 to 4 were obtained by changing the durations of purging processes per cycle. Specifically,Sample 1 was obtained by setting the durations of a first purging process and a second purging process included in each cycle to four seconds.Sample 2 was obtained by setting the durations of the first purging process and the second purging process included in each cycle to two seconds.Sample 3 was obtained by setting the durations of the first purging process and the second purging process included in each cycle to four seconds and two seconds, respectively.Sample 4 was obtained by setting the durations of the first purging process and the second purging process included in each cycle to two seconds and four seconds, respectively. - Also, in Example 3,
Sample 5 was obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the fifth embodiment (wherein a second purging process is skipped, and a process of supplying a nitrogen-containing gas and a second modifying process are continuously performed). Similarly, DCS gas was used as a source gas and NH3 gas was used as a nitrogen-containing gas. H2 gas was used as a modifying gas during a first modifying process. N2 gas was used as a modifying gas during the second modifying process. Also, the duration of a first purging process included in each cycle was set to four seconds. - For convenience of explanation,
FIG. 21A illustrates only one cycle of a sequence of supplying a gas during the forming of the SiN film to obtain each ofSamples 1 to 5. InFIG. 21A , each halftone part denotes the first or second purging process, in which a number means the duration of the first or second purging process. AllSamples 1 to 5 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated inFIG. 3 , and the DCS gas was supplied into the process chamber according to the flash flow. The temperature of the wafer was set to 550° C. when the SiN film was formed. The other process conditions were set to be substantially the same as those in the embodiments described above. - Then, a range of WERs and thickness distribution of the SiN films (
Samples 1 to 5) in a plane of the wafer were measured. When the SiN films were wet-etched, a liquid containing a hydrogen fluoride content of about 1% was used. -
FIG. 21B is a graph illustrating a result of measuring ranges of WERs of the SiN films (Samples 1 to 5) in the plane of the wafer according to Example 3 of the present invention. InFIG. 21B , a horizontal axis denotesSamples 1 to 5, and a vertical axis denotes the ranges of the WERs thereof (Å/min) in the plane of the wafer. -
FIG. 21C is a graph illustrating a result of measuring thickness uniformity of the SiN films (Samples 1 to 5) in the plane of the wafer according to Example 3 of the present invention. InFIG. 21C , a horizontal axis denotesSamples 1 to 5, and a vertical axis denotes thickness uniformity (±%) of the SiN films (Samples 1 to 5) in the plane of the wafer.FIG. 21C reveals that the less a value on the vertical axis, the higher the thickness uniformity of the SiN film. - Referring to
FIG. 21B , it could be seen that the differences between the ranges of WERs of the SiN films (Samples 1 to 5) are not large (that is, the differences between the film qualities of the SiN films in the plane of the wafer are not large). - However, referring to
FIG. 21C , it could be seen that the differences between the thickness uniformities of the SiN films (Samples 1 to 5) are large. That is, it could be seen that, in the case ofSamples Samples - The reason for which the thickness uniformities of the SiN films in the plane of the wafer were lowered when the duration of the first purging process was insufficient seems to be that when the duration of the first purging process was insufficient, the first modifying process began while the DCS gas remained in the process chamber. That is, during the first modifying process, an excited species obtained by plasma-exciting H2 gas may cause or promote the residual DCS gas remaining in the process chamber to be decomposed or adsorbed on an edge portion of the wafer.
- The reason for which the thickness uniformities of the SiN films in the plane of the wafer were not greatly lowered even when the duration of the second purging process was insufficient seems to be that even if the second modifying process begins while NH3 gas remains in the process chamber, the NH3 gas is hardly adsorbed onto the wafer. That is, even if during the second modifying process, an excited species obtained by plasma-exciting N2 gas causes the NH3 gas to be decomposed, the NH3 gas is more likely to be desorbed from the wafer, rather than be adsorbed onto the wafer.
- In Example 4 of the present invention,
Samples 1 to 5 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the fifth embodiment (wherein a second purging process is skipped, and a process of supplying a nitrogen-containing gas and a second modifying process are continuously performed). Similarly, DCS gas was used as a source gas and NH3 gas was used as a nitrogen-containing gas. H2 gas was used as a modifying gas during a first modifying process. N2 gas was used as a modifying gas during the second modifying process. To obtainSamples 1 to 5, the temperature of the wafer (film-forming temperature) was sequentially set to 350° C., 400° C., 450° C., 500° C., and 550° C. The duration of a first purging process included in each cycle was set to four seconds. - Also, as a Comparative Example,
Samples 6 to 10 were obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence. The cycle included supplying DCS gas to the wafer, purging the process chamber, supplying plasma-excited NH3 gas to the wafer in the process chamber, and purging the process chamber. To obtainSamples 6 to 10, the temperature of the wafer (film-forming temperature) was sequentially set to 350° C., 400° C., 450° C., 500° C., and 550° C. - Also, in Example 4, Samples 11 to 13 were obtained by forming a SiN film on a wafer having a diameter of 300 mm according to the same film-forming sequence as described with respect to the fifth embodiment (wherein a second purging process is skipped, and a process of supplying a nitrogen-containing gas and a second modifying process are continuously performed). Similarly, MCS gas was used as a source gas and NH3 gas was used as a nitrogen-containing gas. H2 gas was used as a modifying gas during a first modifying process. N2 gas was used as a modifying gas during the second modifying process. To obtain Samples 11 to 13, the temperature of the wafer (film-forming temperature) was sequentially set to 400° C., 450° C., and 500° C. The duration of a first purging process included in each cycle was set to four seconds.
- Also, as a Reference Example, Samples 14 to 16 were obtained by forming a SiN film on a wafer having a diameter of 300 mm in a process chamber by performing one cycle a predetermined number of times, according to a general film-forming sequence. The cycle includes supplying MCS gas to the wafer, purging the process chamber, supplying plasma-excited NH3 gas to the wafer in the process chamber, and purging the process chamber. To obtain Samples 14 to 16, the temperature of the wafer (film-forming temperature) was sequentially set to 400° C., 450° C., and 500° C.
- All of
Samples 1 to 16 were obtained using a substrate processing apparatus with two plasma generation units, as illustrated inFIG. 3 , and a source gas (DCS gas or MCS gas) was supplied into the process chamber according to the flash flow. The other process conditions were set to be substantially the same as those in the embodiments described above. - Then, WERs of the SiN films (
Samples 1 to 16) were measured. When the SiN films were wet-etched, a liquid containing a hydrogen fluoride content of about 1% was used. -
FIG. 22A is a graph illustrating the relationship between the WER of each SiN film and a film-forming temperature according to Example 4 of the present invention. InFIG. 22A , a horizontal axis denotes the film-forming temperature when each SiN film was formed, and a vertical axis denotes the WER (Å/min) of each SiN film. Here, ‘WER’ means an average of WERs in a plane of the wafer. InFIG. 22A , ‘▪’ sequentially denotesSamples 1 to 5 (Example 4) from the left, ‘♦’ sequentially denotesSamples 6 to 10 (Comparative Example) from the left, ‘’ sequentially denotes Samples 11 to 13 (Example 4) from the left, and ‘▴’ sequentially denotes Samples 14 to 16 (Reference Example) from the left.FIG. 22B is a partially enlarged view of the graph ofFIG. 22A , in which only a range of WERs that are less than or equal to 350 (Å/min) is shown. - Referring to
FIGS. 22A and 22B , it could be seen that, at a low temperature of no more than 550° C., the SiN films (Samples 1 to 5) (Example 4) had low WERs and improved resistance to hydrogen fluoride, compared to the SiN films (Samples 6 to 10) (Comparative Example). This seems to be because excited species obtained by plasma-exciting H2 gas or N2 gas through the first or second modifying process cause impurities, such as hydrogen or chlorine, to be efficiently desorbed from a silicon-containing layer or a SiN layer, thereby improving the quality of the SiN films. Also, it was confirmed that the WERs, qualities, and thicknesses of the SiN films (Samples 1 to 5) (Example 4) in the plane of the wafer were uniformly improved. - Referring to
FIGS. 22A and 22B , it could be seen that, at a low temperature of no more than 550° C., the SiN films (Samples 14 to 16) (Reference Example) had low WERs and improved resistance to hydrogen fluoride, compared to the SiN films (Samples 6 to 10) (Comparative Example). This seems to be because MCS gas having a lower chlorine content than DCS gas was used as a source gas, and thus the concentration of chlorine in the SiN films could be lowered, thereby improving the resistance of the SiN films to hydrogen fluoride. - Also, referring to
FIGS. 22A and 22B , it could be seen that, at a low temperature of no more than 550° C., the SiN films (Samples 11 to 13) (Example 4) had lower WERs and more improved resistance to hydrogen fluoride than the SiN films (Samples 1 to 5) (Example 4). This seems to be because MCS gas having a lower chlorine content than DCS gas was used as a source gas, and because, in addition to the use of the MCS gas, active species (excited species) obtained by plasma-exciting H2 gas or N2 gas through the first and second modifying processes cause impurities, such as hydrogen or chlorine, to be efficiently desorbed from a silicon-containing layer or a SiN layer, thereby improving the quality of the SiN films. Also, it was confirmed that the WERs, i.e., qualities, and thicknesses of the SiN Films (Samples 11 to 13) (Example 4) in the plane of the wafer, were uniformly improved. - From the above results, it was concluded that the resistance of the SiN films to hydrogen fluoride (i.e., qualities of the SiN films) may be more improved using MCS gas as a source gas, and performing the modifying processes described above after the process of supplying the MCS gas and before the process of supplying the NH3 gas and/or after the process of supplying NH3 gas and before the process of supplying the MCS gas. Also, it could be seen that even if the durations of the modifying processes are shortened using the MCS gas as a source gas, a SiN film having a desirable quality may be formed, thereby greatly increasing the yield.
- According to the present invention, a method of manufacturing a semiconductor device capable of forming a nitride film resistant to hydrogen fluoride at low temperatures, a method of processing a substrate, a substrate processing apparatus, and a non-transitory computer-readable recording medium can be provided.
- Exemplary embodiments of the present invention are hereinafter added.
- According to an embodiment of the present invention, there is provided a method of manufacturing a semiconductor device, the method including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- (a) supplying a source gas to the substrate;
- (b) supplying a plasma-excited hydrogen-containing gas to the substrate;
- (c) supplying a plasma-excited or thermally excited nitriding gas to the substrate; and
- (d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
- In the method of
Supplementary Note 1, the step (b) may be performed during one of a time period after the step (a) and a time period after the step (c), and - the step (d) may be performed during one of the time period after the step (a) and the time period after the step (c) other than the time period where the step (b) is performed.
- In the method of
Supplementary Note 1, the step (b) may be performed during one of a time period after the step (a) where a supply of the plasma-excited or thermally excited nitriding gas is suspended and a time period after the step (c) where a supply of the source gas is suspended, and - the step (d) may be performed during one of the time period after the step (a) where the supply of the plasma-excited or thermally excited nitriding gas is suspended and the time period after the step (c) where the supply of the source gas is suspended other than the time period where the step (b) is performed.
- In the method of
Supplementary Note 1, the step (b) may be performed during one of a time period after the step (a) and before the step (c) and a time period after the step (c) and before the step (a), and - the step (d) may be performed during one of the time period after the step (a) and before the step (c) and the time period after the step (c) and before the step (a) other than the time period where the step (b) is performed.
- In the method of
Supplementary Note 1, the step (b) may be performed during a time period after the step (a), and - the step (d) may be performed during a time period after the step (c).
- In the method of
Supplementary Note 1, wherein the step (a), the step (b), the step (c) and the step (d) in the cycle are performed in order, - the step (a) may include forming a layer on the substrate,
- the step (b) may include performing a first modifying process to the layer,
- the step (c) may include changing the layer to which the first modifying process is performed into a nitride layer, and
- the step (d) may include performing a second modifying process to the nitride layer.
- In the method of
Supplementary Note 1, wherein the step (a), the step (d), the step (c) and the step (b) in the cycle are performed in order, - the step (a) may include forming a layer on the substrate,
- the step (d) may include performing a first modifying process to the layer,
- the step (c) may include changing the layer to which the first modifying process is performed into a nitride layer, and
- the step (b) may include performing a second modifying process to the nitride layer.
- In the method of
Supplementary Note 1, wherein the step (a), the step (c), the step (b) and the step (d) in the cycle are performed in order, - the step (a) may include forming a layer on the substrate,
- the step (c) may include changing the layer into a nitride layer,
- the step (b) may include performing a first modifying process to the nitride layer, and
- the step (d) may include performing a second modifying process to the nitride layer.
- In the method of any one of
Supplementary Notes 1 to 8, the steps (a) through (d) may be performed in a state where the substrate is accommodated in a process chamber, the method further including a first purging process for purging the process chamber after the step (a), and a second purging process for purging the process chamber after the step (c). - In the method of Supplementary Note 9, a duration of the first purging process may be set to be longer than a duration of the second purging process.
- In the method of Supplementary Note 9, the second purging process may be skipped.
- In the method of any one of
Supplementary Notes 1 to 11, the step (b), the step (c) and the step (d) may be performed consecutively. - In the method of any one of
Supplementary Notes 1 to 12, the steps (a) through (d) may be performed while the substrate is accommodated in a process chamber, and - the step (b), the step (c) and the step (d) may be consecutively performed without purging the process chamber.
- In the method of any one of
Supplementary Notes 1 to 13, the step (c) may include supplying the plasma-excited nitriding gas to the substrate. - According to another embodiment of the present invention, there is provided a method of manufacturing a semiconductor device, the method including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- (a) supplying a source gas to the substrate;
- (b) supplying a plasma-excited hydrogen-containing gas to the substrate;
- (c) supplying a plasma-excited nitriding gas to the substrate; and
- (d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
- In the method of any one of
Supplementary Notes 1 to 15, the step (b) may include supplying the plasma-excited hydrogen-containing gas excited by a plurality of excitation units to the substrate through each of the plurality of the excitation units. - In the method of any one of
Supplementary Notes 1 to 16, the step (d) may include supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas excited by a plurality of excitation units to the substrate through each of the plurality of the excitation units. - In the method of any one of
Supplementary Notes 1 to 17, the step (c) may include supplying the plasma-excited or thermally excited nitriding gas excited by a plurality of excitation units to the substrate through each of the plurality of the excitation units. - According to another embodiment of the present invention, there is provided a method of manufacturing a semiconductor device, the method including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- (a) supplying a source gas to the substrate;
- (b) respectively supplying a hydrogen-containing gas, which is plasma-excited by a plurality of excitation units, to the substrate by the plurality of the excitation units;
- (c) respectively supplying a nitriding gas, which is plasma-excited by a plurality of excitation units, to the substrate by the plurality of the excitation units; and
- (d) respectively supplying at least one of nitrogen gas and a rare gas, which are plasma-excited by a plurality of excitation units, to the substrate by the plurality of the excitation units.
- In the method of any one of Supplementary Notes 16 to 19, the plurality of the excitation units may be disposed to be linearly symmetrical with respect to a straight line connecting a center of the substrate and a center of an exhaust port configured to exhaust a gas supplied into the process chamber.
- In the method of any one of Supplementary Notes 16 to 19, the plurality of the excitation units may be disposed to face one another via the center of the substrate,
- In the method of any one of Supplementary Notes 16 to 19, two excitation units may be disposed such that lines connecting the plurality of the excitation units and an exhaust port configured to exhaust a gas supplied into the process chamber form an isosceles triangle.
- In the method of any one of
Supplementary Notes 1 to 22, during the forming of the nitride film, the substrate may be rotated. - In the method of any one of
Supplementary Notes 1 to 23, during the forming of the nitride film, the temperature of the substrate may be set to fall within a range of 300° C. to 650° C. - In the method of any one of
Supplementary Notes 1 to 24, during the forming of the nitride film, the temperature of the substrate may be set to fall within a range of 300° C. to 600° C. - In the method of any one of
Supplementary Notes 1 to 25, the nitriding gas may include ammonia gas, the hydrogen-containing gas may include hydrogen gas, and the rare gas may include at least one of argon gas and helium gas. - In the method of any one of
Supplementary Notes 1 to 26, the source gas may include a silane-based source gas. - In the method of any one of
Supplementary Notes 1 to 21, the source gas may include a chlorosilane-based source gas. - In the method of any one of
Supplementary Notes 1 to 22, the source gas may include at least one of dichlorosilane gas and monochlorosilane gas. - According to another embodiment of the present invention, there is provided a method of processing a substrate including forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- (a) supplying a source gas to the substrate;
- (b) supplying a plasma-excited hydrogen-containing gas to the substrate;
- (c) supplying a plasma-excited or thermally excited nitriding gas to the substrate; and
- (d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate.
- According to another embodiment of the present invention, there is provided a substrate processing apparatus including:
- a process chamber configured to accommodate a substrate;
- a first gas supply system configured to supply a source gas to the substrate in the process chamber;
- a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber;
- a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber;
- a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber;
- an excitation unit configured to plasma-excite or thermally excite a gas; and
- a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a predetermined number of times, the cycle including:
- (a) supplying the source gas to the substrate in the process chamber;
- (b) supplying the plasma-excited hydrogen-containing gas to the substrate in the process chamber;
- (c) supplying the plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and
- (d) supplying at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas to the substrate in the process chamber.
- According to another embodiment of the present invention, there is provided a program that causes a computer to perform a process of forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- (a) supplying a source gas to the substrate in a process chamber;
- (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber;
- (c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and
- (d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate in the process chamber.
- According to another embodiment of the present invention, there is provided a non-transitory computer-readable recording medium storing a program that causes a computer to perform a process of forming a nitride film on a substrate by performing a cycle a predetermined number of times, the cycle including:
- (a) supplying a source gas to the substrate in a process chamber;
- (b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber;
- (c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and
- (d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate in the process chamber.
Claims (19)
1. A substrate processing apparatus comprising:
a process chamber configured to accommodate a substrate;
a first gas supply system configured to supply a source gas to the substrate in the process chamber;
a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber;
a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber;
a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber;
an excitation unit configured to plasma-excite or thermally excite a gas; and
a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including:
(a) supplying the source gas to the substrate in the process chamber;
(b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber;
(c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and
(d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate in the process chamber,
wherein the process (b) is performed during a time period after the process (a) or a time period after the process (c), and the process (d) is performed during the time period after the process (a) or the time period after the process (c) other than the time period where the process (b) is performed.
2. The apparatus of claim 1 , wherein the control unit is configured to control the first through fourth gas supply systems and the excitation unit to perform the process (b) during a time period after the process (a) where a supply of the plasma-excited or thermally excited nitriding gas is suspended or a time period after the process (c) where a supply of the source gas is suspended, and to perform the process (d) during the time period after the process (a) where the supply of the plasma-excited or thermally excited nitriding gas is suspended or the time period after the process (c) where the supply of the source gas is suspended other than the time period where the process (b) is performed.
3. The apparatus of claim 1 , wherein the control unit is configured to control the first through fourth gas supply systems and the excitation unit to perform the cycle the plurality of times in a manner that the process (a), the process (b), the process (c) and the process (d) in each cycle are performed in order.
4. The apparatus of claim 1 , wherein the control unit is configured to control the first through fourth gas supply systems and the excitation unit to: form a layer on the substrate in the process (a); perform a first modifying process to the layer in the process (b); change the layer to which the first modifying process is performed into a nitride layer in the process (c); and perform a second modifying process to the nitride layer in the process (d).
5. The apparatus of claim 1 , further comprising a pressure adjustment unit configured to regulate an inner pressure of the process chamber,
and the control unit is configured to control the first through fourth gas supply systems, the excitation unit and the pressure adjustment unit to consecutively perform the process (b), the process (c) and the process (d) without performing a vacuum exhaust of the process chamber while gas supply is suspended.
6. The apparatus of claim 1 , further comprising a pressure adjustment unit configured to regulate an inner pressure of the process chamber,
and the control unit is configured to control the first through fourth gas supply systems, the excitation unit and the pressure adjustment unit to consecutively perform the process (b), the process (c) and the process (d) without performing a gas replacement in the process chamber.
7. The apparatus of claim 1 , wherein the control unit is configured to control the second gas supply system and the excitation unit to supply the plasma-excited nitriding gas to the substrate in the process (c).
8. The apparatus of claim 1 , wherein the excitation unit comprises a plurality of excitation units, and the control unit is configured to control the third gas supply system and the plurality of the excitation units to supply the plasma-excited hydrogen-containing gas excited by the plurality of the excitation units to the substrate through each of the plurality of the excitation units in the process (b).
9. The apparatus of claim 1 , wherein the excitation unit comprises a plurality of excitation units, and the control unit is configured to control the fourth gas supply system and the plurality of the excitation units to supply at least one of the plasma-excited nitrogen gas and the plasma-excited rare gas excited by the plurality of the excitation units to the substrate through each of the plurality of the excitation units in the process (d).
10. The apparatus of claim 1 , wherein the excitation unit comprises a plurality of excitation units, and the control unit is configured to control the second gas supply system and the plurality of the excitation units to supply the plasma-excited or thermally excited nitriding gas excited by the plurality of the excitation units to the substrate through each of the plurality of the excitation units in the process (c).
11. The apparatus of claim 1 , wherein the control unit is configured to control the first through fourth gas supply systems and the excitation unit to further perform: (e) purging the process chamber after performing the process (a); and (f) purging the process chamber after performing the process (c).
12. The apparatus of claim 11 , wherein the control unit configured to control the first through fourth gas supply systems and the excitation unit in a manner that a purging time of the process (e) is longer than that of the process (f).
13. The apparatus of claim 1 , wherein the control unit is configured to control the first through fourth gas supply systems and the excitation unit to: replace a gas in a process chamber after the process (a), and continuously perform at least one of the processes (b) and (d) after performing the process (c) without replacing the gas in the process chamber.
14. The apparatus of claim 1 , wherein the control unit is configured to control the fourth gas supply system and the excitation unit to supply the plasma-excited rare gas to the substrate in the process (d).
15. The apparatus of claim 1 , wherein the control unit is configured to control the fourth gas supply system and the excitation unit to supply at least one selected from the group consisting of plasma-excited Ar gas, plasma-excited He gas, plasma-excited Ne gas and plasma-excited Xe gas in the process (d).
16. The apparatus of claim 1 , wherein the control unit is configured to control the fourth gas supply system and the excitation unit to supply at least one selected from the group consisting of plasma-excited Ar gas and plasma-excited He gas in the process (d).
17. The apparatus of claim 1 , wherein the control unit is configured to control the first through fourth gas supply systems and the excitation unit to: perform the processes (b), (c) and (d) consecutively; perform the process (c) immediately after the process (b) is completed; and perform the process (d) immediately after the process (c) is completed.
18. A substrate processing apparatus comprising:
a process chamber configured to accommodate a substrate;
a first gas supply system configured to supply a source gas to the substrate in the process chamber;
a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber;
a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber;
a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber;
an excitation unit configured to plasma-excite or thermally excite a gas; and
a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including:
(a) supplying the source gas to the substrate in the process chamber;
(b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber;
(c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and
(d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate in the process chamber,
wherein the process (a), the process (b), the process (c) and the process (d) in the cycle are performed in order.
19. A substrate processing apparatus comprising:
a process chamber configured to accommodate a substrate;
a first gas supply system configured to supply a source gas to the substrate in the process chamber;
a second gas supply system configured to supply a nitriding gas to the substrate in the process chamber;
a third gas supply system configured to supply a hydrogen-containing gas to the substrate in the process chamber;
a fourth gas supply system configured to supply at least one of nitrogen gas and a rare gas to the substrate in the process chamber;
an excitation unit configured to plasma-excite or thermally excite a gas; and
a control unit configured to control the first through fourth gas supply systems and the excitation unit so as to form a nitride film on the substrate by performing a cycle a plurality of times, the cycle including:
(a) supplying the source gas to the substrate in the process chamber;
(b) supplying a plasma-excited hydrogen-containing gas to the substrate in the process chamber;
(c) supplying a plasma-excited or thermally excited nitriding gas to the substrate in the process chamber; and
(d) supplying at least one of a plasma-excited nitrogen gas and a plasma-excited rare gas to the substrate in the process chamber,
wherein the process (a), the process (d), the process (c) and the process (b) in the cycle are performed in order.
Priority Applications (1)
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US14/579,489 US20150101533A1 (en) | 2011-10-07 | 2014-12-22 | Substrate processing apparatus |
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JP2011223134 | 2011-10-07 | ||
JP2012-181859 | 2012-08-20 | ||
JP2012181859A JP6088178B2 (en) | 2011-10-07 | 2012-08-20 | Semiconductor device manufacturing method, substrate processing apparatus, and program |
US13/647,908 US8956984B2 (en) | 2011-10-07 | 2012-10-09 | Method of manufacturing semiconductor device, method of processing substrate, substrate processing apparatus, and non-transitory computer-readable recording medium |
US14/579,489 US20150101533A1 (en) | 2011-10-07 | 2014-12-22 | Substrate processing apparatus |
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US13/647,908 Division US8956984B2 (en) | 2011-10-07 | 2012-10-09 | Method of manufacturing semiconductor device, method of processing substrate, substrate processing apparatus, and non-transitory computer-readable recording medium |
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US13/647,908 Active US8956984B2 (en) | 2011-10-07 | 2012-10-09 | Method of manufacturing semiconductor device, method of processing substrate, substrate processing apparatus, and non-transitory computer-readable recording medium |
US14/579,489 Abandoned US20150101533A1 (en) | 2011-10-07 | 2014-12-22 | Substrate processing apparatus |
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US (2) | US8956984B2 (en) |
JP (1) | JP6088178B2 (en) |
TW (1) | TWI475599B (en) |
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US20130171838A1 (en) | 2013-07-04 |
TWI475599B (en) | 2015-03-01 |
JP2013093551A (en) | 2013-05-16 |
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TW201318038A (en) | 2013-05-01 |
US8956984B2 (en) | 2015-02-17 |
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