KR20180059244A - Apparatus and method for treating substrate - Google Patents

Abstract

The present invention relates to a substrate treatment method which comprises the following steps: etching the surface of a substrate; passivating the surface of the substrate; and cleaning the surface of the substrate, wherein the step of cleaning the substrate can induce an etch residue to be moved from the surface of the substrate by inducing an electric field on the substrate. The substrate treatment method can easily remove a small particle (etch residue) remaining between patterns in wet cleaning.

Description

[0001] APPARATUS AND METHOD FOR TREATING SUBSTRATE [0002]

The present invention relates to a substrate processing apparatus, and more particularly, to a substrate processing apparatus and method capable of etching, cleaning, and pacifying by a wet process using a vaporized, liquefied or gasified gas without a dry etching process .

The etching process of a semiconductor device is a process of forming a desired circuit pattern on a thin film of a plurality of layers constituting a semiconductor by selectively removing an unnecessary portion using a liquid or a gas etchant on the substrate, By repeating this, a semiconductor structure is formed.

The etching process is divided into a wet process and a dry process depending on the state of the material causing the etching reaction. The dry process has a disadvantage that it is costly and difficult to process in comparison with wet process. Recently, however, , Dry etching is more widespread than wet etching in order to increase the yield by increasing the circuit line width.

However, the dry etching process is difficult to satisfy the uniformity and selectivity of the high aspect ratio, and the etching rate is lower than that of the wet etching, and a high cost is required.

Particularly, dry etching is performed by repeating wet cleaning, layer deposition, dry etching, and wet cleaning. In this case, wet cleaning, film deposition, dry etching, There is a problem in that it is carried out in different chambers.

In addition, there is a difficulty in removing small particles (etching residues) remaining between the patterns during the wet cleaning in the dry etching process.

Embodiments of the present invention seek to provide a substrate processing apparatus and method that facilitates removal of small particles (etching residues) remaining between patterns during wet cleaning.

The objects of the present invention are not limited thereto, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a method of manufacturing a semiconductor device, comprising: etching a substrate surface; Pacifying the substrate surface; And cleaning the substrate surface; The substrate cleaning step may provide a substrate processing method that induces the behavior of the etch residue from the substrate surface through the induction of an electric field on the substrate.

In addition, the etching step may etch the substrate surface using a first dissolving water in which at least one gas phase substance having an etching action on the substrate surface is dissolved in deionized water.

In addition, the passivation step may passivate the substrate surface using a second dissolution water in which at least one gaseous substance having a passivating action on the substrate surface is dissolved in deionized water.

Further, the etching step may provide the first dissolved water to the substrate surface in a vapor state or a liquid state, and the pacification step may provide the second dissolved water to the substrate surface in a vapor state or a liquid state.

Further, the etching step and the passivation step may be performed in the same chamber, and the chamber may be a closed chamber.

A first purge step of purifying the interior of the chamber using a purge gas between the etching step and the passivation step; Further comprising a second purge step of purifying the interior of the chamber using a purge gas after the passivation step, wherein the etching step, the first purge step, the passivation step, and the second purge step are repeatedly performed .

The method may further include cleaning the substrate after the passivation step; The cleaning step may include a pretreatment step of replacing the atmosphere inside the chamber with water vapor; And a solution cleaning step of cleaning the substrate using a cleaning solution.

In addition, the water vapor may have dissolved at least one gas phase substance having an etching action on the cleaning solution or the substrate surface.

In addition, the pretreatment step may be performed in a chamber atmosphere of a low vacuum state, and the solution cleaning step may be performed in a chamber atmosphere of an atmospheric pressure state.

Further, the method may further include a drying step of drying the substrate after the cleaning step; The drying step may provide an IPA vapor or an inert gas for drying onto a rotating substrate in a low vacuum or atmospheric chamber atmosphere.

Further, the electric field may be provided by applying a bias power or an alternating current.

According to an aspect of the invention, there is provided a process chamber for providing an atmospheric pressure or a low vacuum atmosphere; A substrate support member installed in an inner space of the process chamber and on which a substrate is placed; And a first nozzle member for supplying the dissolution water onto the substrate placed on the substrate support member; The substrate support member and the first nozzle member may be provided with a substrate processing apparatus in which an upper electrode and a lower electrode are provided for inducing an electric field on the substrate to induce the behavior of the etching residue from the substrate surface.

A first dissolving water supply unit for supplying a first dissolving water to the first nozzle member, the first dissolving water having at least one kind of gaseous substance having an etching action on the substrate surface dissolved in deionized water; And a second dissolution water supply unit for supplying the first nozzle member with a second dissolution water in which at least one gaseous substance having a passivating action with respect to the substrate surface is dissolved in deionized water.

The first dissolving water supply unit may supply the first dissolving water in a vapor state or a liquid state, and the second dissolving water supply unit may supply the second dissolving water in a vapor state or a liquid state.

A second nozzle member for supplying a cleaning fluid onto a substrate placed on the substrate support member; And a cleaning fluid supply unit for selectively supplying water vapor and a cleaning solution to the second nozzle member.

In addition, the water vapor may have dissolved at least one gas phase substance having an etching action on the cleaning solution or the substrate surface.

The second nozzle member may include a cylindrical nozzle body having a plurality of injection holes for spraying water vapor so that water vapor is sprayed over the entire surface of the substrate. And a central spray nozzle located at the center of the nozzle body and spraying the cleaning solution.

A first electrode in the form of a ring provided on the substrate support member; A ring-shaped second electrode located on the substrate; And a power supply unit applying the alternating current to at least one of the first electrode and the second electrode while changing the value of the alternating current.

According to the present invention, it is possible to easily remove small particles (etching residues) remaining between patterns during wet cleaning.

According to the present invention, since various processes are performed in a closed chamber without moving between chambers, a special effect that a clean and uncontaminated environment can be maintained can be expected.

According to the present invention, high uniformity and selectivity can be expected through the progress of the vaporization or liquidification passivation process.

According to the present invention, in the case of a vaporized or liquefied gas, an extremely smaller amount than the amount used for forming the atmosphere with the dry gas can be used, which can lower the cost and shorten the processing time Effect can be expected.

According to the present invention, the degree of toxicity of the vaporized and liquefied gas to be introduced into the closed chamber is lower than that of the dry type, so that safety can be expected to be improved.

1 is a plan view schematically showing a substrate processing system.
2 is a plan view showing a configuration of a substrate processing apparatus according to the present invention.
3 is a side cross-sectional view showing a configuration of a substrate processing apparatus according to the present invention.
FIG. 4 is a view illustrating a first and second dissolved water supply units connected to the first nozzle member.
5 is a view showing a cleaning fluid supply unit connected to the second movable nozzle member.
6 is a flow chart for explaining a substrate processing method according to an embodiment of the present invention.
7 is a process sectional view showing a pattern forming method according to the etching step and the passivation step.
8 is a diagram for explaining the pre-processing step.
9 is a view for explaining a solution cleaning step.
10 is a view for explaining the drying step.
11A and 11B are diagrams for explaining an electric field induction method using a bias power in a substrate cleaning process.
12 is a view showing a lower electrode provided on a spin head.
13A to 13B are views for explaining an electric field induction method using alternating current in a substrate cleaning process.
14 is a view showing another modification of the upper electrode.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout the specification and claims. The description will be omitted.

1 is a plan view schematically showing a substrate processing system of the present invention.

Referring to FIG. 1, the substrate processing system 1000 of the present invention may include an index unit 10, a buffer unit 20, and a processing unit 50. The index unit 10, the buffer unit 20, and the processing unit are arranged in a line. Hereinafter, the direction in which the index unit 10, the buffer unit 20, and the processing unit 50 are arranged is referred to as a first direction, the direction perpendicular to the first direction as viewed from above is referred to as a second direction, And a direction perpendicular to the plane including the first direction and the second direction is defined as a third direction.

The index portion 10 is disposed in front of the substrate processing system 1000 in the first direction. The index section 10 includes four load ports 12 and one index robot 13. The four load ports 12 are disposed in front of the index portion 10 in the first direction. A plurality of load ports 12 are provided and they are disposed along the second direction. The number of load ports 12 may increase or decrease depending on the process efficiency and footprint conditions of the substrate processing system 1000. In the load ports 12, a substrate W to be supplied to the process and a carrier (e.g., cassette, FOUP, etc.) in which the processed substrate W is placed are placed. The carrier 16 is formed with a plurality of slots for accommodating the substrates horizontally arranged with respect to the paper surface.

The index robot 13 is disposed in the first direction adjacent to the load port 12. [ The index robot 13 is installed between the load port 12 and the buffer unit 20. The index robot 13 transfers the substrate W waiting on the upper layer of the buffer unit 20 to the carrier 16 or transfers the substrate W waiting on the carrier 16 to the lower layer of the buffer unit 20 do.

The buffer unit 20 is provided between the index unit 10 and the processing unit. The buffer unit 20 temporarily stores the substrate W to be supplied to the process before being transferred by the index robot 13 or the substrate W whose processing has been completed before being transferred by the main transfer robot 30, .

The main transfer robot 30 is installed in the transfer passage 40 and transfers substrates between the substrate processing apparatuses 1 and the buffer unit 20. [ The main transfer robot 30 transfers the substrate to be provided to the process waiting in the buffer unit 20 to each substrate processing apparatus 1 or transfers the substrate that has been processed in each substrate processing apparatus 1 to the buffer unit 20 ).

The transfer passage 40 is disposed along a first direction in the processing section and provides a passage through which the main transfer robot 30 moves. On both sides of the transfer passage 40, the substrate processing apparatuses 1 are disposed to face each other and along the first direction. The main transfer robot 30 moves along the first direction to the transfer passage 40 and the upper and lower layers of the substrate processing apparatus 1 and the upper and lower layers of the buffer unit 20 are provided with movable rails .

The substrate processing apparatus 1 is disposed on both sides of the moving path 40 on which the main transfer robot 30 is installed so as to face each other. The substrate processing system 1000 includes a plurality of upper and lower substrate processing apparatuses 1 but the number of the substrate processing apparatuses 1 is increased or decreased depending on the process efficiency and the footprint conditions of the substrate processing system 1000 You may. Each of the substrate processing apparatuses 1 is constituted by an independent housing, and a process of processing the substrate in an independent form in each of the substrate processing apparatuses can be performed.

In the following embodiments, a substrate processing apparatus for performing etching, passivation and cleaning processes on the surface of a substrate using dissolved water in which etching gas and passivation gas are respectively dissolved in deionized water will be described as an example.

2 is a plan view showing a configuration of a substrate processing apparatus according to the present invention. 3 is a side cross-sectional view showing a configuration of a substrate processing apparatus according to the present invention.

In the present embodiment, the substrate processed by the substrate processing apparatus 1 is illustrated as a semiconductor substrate by way of example, but the present invention is not limited thereto and can be applied to various types of substrates such as a glass substrate.

2 and 3, a substrate processing apparatus 1 according to the present invention is an apparatus for etching, pacifying, and cleaning a substrate surface using various process fluids. The apparatus 800 includes a chamber 800, a processing vessel 100, And includes a substrate support member 200, a first moving nozzle member 300, a fixed nozzle 500, an exhaust member 400, and a second moving nozzle member 900.

The chamber 800 provides a closed internal space, and a fan filter unit 810 is installed on the upper part. The fan filter unit 810 generates a vertical air flow inside the chamber 800.

The fan filter unit 810 is a unit in which the filter and the air supply fan are modularized into one unit, and supplies the high-humidity outside air to the inside of the chamber by filtering. The high-humidity outside air passes through the fan filter unit 810 and is supplied into the chamber to form a vertical airflow. This vertical airflow provides a uniform air flow over the substrate and the contaminants (fumes) generated during the processing of the substrate surface by the processing fluid are directed to the exhaust member (not shown) through the suction ducts of the processing vessel 100 400 so that the cleanliness of the inside of the processing vessel can be maintained.

As shown in FIG. 2, the chamber 800 is partitioned into a process area 816 and a maintenance area 818 by a horizontal partition 814. The maintenance area 818 is a space in which the driving units of the elevation unit are located in addition to the discharge lines 141, 143 and 145 connected to the processing vessel 100 and the sub exhaust line 410, 818 are preferably isolated from the process region where the substrate processing is performed.

The processing vessel 100 has a cylindrical shape with an open top, and provides a processing space for processing the substrate w. The open upper surface of the processing vessel 100 is provided as a take-out and carry-in passage of the substrate w. The substrate support member 200 is located in the process space. The substrate support member 200 supports the substrate W and rotates the substrate during the process.

The processing vessel 100 is divided into an upper space 132a where the spin head 210 is located and an upper space 132a by the spin head 210. An exhaust duct 190 is provided at the lower end of the processing vessel 100 And provides a connected lower space 132b. The upper space 132a of the processing vessel 100 is provided with annular first, second, and third suction ducts 110 (including water) for introducing and sucking processing liquid (including dissolved water) , 120, and 130 are arranged in multiple stages. In the present embodiment, the processing vessel is shown as having three suction ducts, but not limited thereto, and the processing vessel may include two suction ducts or three or more suction ducts.

The annular first, second and third suction ducts 110, 120 and 130 have exhaust ports H communicating with one common annular space (corresponding to the lower space of the container). In the lower space 132b, an exhaust duct 190 connected to the exhaust member 400 is provided. Specifically, the first to third suction ducts 110, 120, and 130 each have a bottom surface having an annular ring shape and a side wall having a cylindrical shape extending from the bottom surface. The second suction duct 120 surrounds the first suction duct 110 and is located apart from the first suction duct 110. The third suction duct 130 surrounds the second suction duct 120 and is located apart from the second suction duct 120.

The first to third suction ducts 110, 120 and 130 provide the first to third collection spaces RS1, RS2 and RS3 through which the airflow containing the processing liquid and the gas scattered from the substrate w flows . The first collection space RS1 is defined by the first intake duct 110 and the second collection space RS2 is defined by the spacing space between the first intake duct 110 and the second intake duct 120 And the third collection space RS3 is defined by the spacing space between the second suction duct 120 and the third suction duct 130. [

Each of the upper surfaces of the first to third suction ducts 110, 120, and 130 has an inclined surface whose center portion is open and whose distance from the corresponding side surface gradually increases from the connected side wall to the opening side. Accordingly, the processing liquid scattered from the substrate w flows into the recovery spaces RS1, RS2, and RS3 along the upper surfaces of the first to third suction ducts 110, 120, and 130.

On the other hand, the processing vessel 100 is combined with the elevation unit 600 that changes the vertical position of the processing vessel 100. The elevating unit 600 moves the processing vessel 100 linearly in the vertical direction. The relative height of the processing vessel 100 to the spin head 210 is changed as the processing vessel 100 is moved up and down. The lifting unit 600 may include a bracket 612, a moving shaft 614, and a driver 616. The bracket 612 is fixed to the outer wall of the processing container 100 and a moving shaft 614 which is moved upward and downward by a driver 616 is fixedly coupled to the bracket 612. The processing vessel 100 is lowered so that the spin head 210 protrudes to the upper portion of the processing vessel 100 when the substrate W is loaded into the spin head 210 or unloaded from the spin head 210. The height of the processing vessel 100 may be adjusted so that the processing solution may flow into the predetermined suction ducts 110, 120, and 130 depending on the type of the processing solution supplied to the substrate W. have. Thus, the relative vertical position between the processing container 100 and the substrate w is changed. Accordingly, the processing vessel 100 can differentiate the kinds of the processing liquid and the polluting gas recovered for each of the recovery spaces RS1, RS2, and RS3.

In this embodiment, the substrate processing apparatus 1 vertically moves the processing vessel 100 to change the relative vertical position between the processing vessel 100 and the substrate supporting member 200. However, the substrate processing apparatus 1 may change the relative vertical position between the processing container 100 and the substrate supporting member 200 by vertically moving the substrate supporting member 200.

The substrate support member 200 is installed inside the processing vessel 100. The substrate support member 200 supports the substrate W during the process and can be rotated by a driving unit 240, which will be described later, during the process. The substrate support member 200 has a spin head 210 having a circular upper surface and support pins 212 and chucking pins 214 for supporting the substrate W are formed on the upper surface of the spin head 210 I have. The support pins 212 are disposed at predetermined intervals on the upper edge of the spin head 210 to be arranged in a predetermined array and protrude upward from the spin head 210. The support pins 212 support the lower surface of the substrate W so that the substrate W is supported in a state of being spaced upward from the spin head 210. Chucking pins 214 are disposed on the outer sides of the support pins 212, and the chucking pins 214 are provided to protrude upward. The chucking pins 214 align the substrate W such that the substrate W supported by the plurality of support pins 212 is in position on the spin head 210. The chucking pins 214 contact the side of the substrate W to prevent the substrate W from being displaced from the correct position.

A support shaft 220 for supporting the spin head 210 is connected to the lower portion of the spin head 210 and the support shaft 220 is rotated by a drive unit 230 connected to the lower end of the support shaft 220. The driving unit 230 may be a motor or the like. As the support shaft 220 rotates, the spin head 210 and the substrate W rotate.

The exhaust member 400 is connected to a suction duct (not shown) for making the interior of the chamber low in vacuum (for example, 10 -3 torr) and for recovering the processing solution in the first to third suction ducts 110, (Suction pressure). The exhaust member 400 includes a sub-exhaust line 410 connected to the exhaust duct 190, and a damper 420. The sub-exhaust line 410 may be provided with a vacuum pump (not shown).

Fixing nozzles 500 are installed at the top of the processing vessel 100. The fixed nozzle 500 ejects the processing fluid to the substrate W placed on the spin head 210. The fixed nozzle 500 can adjust the spray angle according to the processing position of the substrate.

The first moving nozzle member 300 is moved over the center of the substrate through the swing movement to spray the molten water for etching or passivation treatment on the substrate. The first moving nozzle member 300 includes a supporting shaft 310, a driving unit 320, a nozzle arm 330, and a first nozzle 340.

A first molten water supply unit 380 and a second molten water supply unit 390 are connected to the first movable nozzle member 300.

The first dissolving water supply unit 380 supplies the first nozzle 340 with a first dissolved water in which at least one kind of gas phase substance (hereinafter referred to as etching gas) having an etching action on the substrate surface is dissolved in deionized water. The second dissolved water supply unit 390 supplies the second dissolved water obtained by dissolving at least one kind of gas phase substance (hereinafter referred to as "pacification gas") having a passivating action to the substrate surface in deionized water to the first nozzle 340 do.

FIG. 4 is a view illustrating a first and second dissolved water supply units connected to the first nozzle member.

Referring to FIG. 4, the first dissolving water supply unit 380 includes a first dissolving processing unit 350 for dissolving etching gas supplied from the etching gas supply source 382 and the etching gas supply source 382 in deionized water to produce a first dissolving water, (384). For example, SF6 gas may be used as the first dissolved water supply unit 382, but not limited thereto, and various etching gases may be used.

A solvent such as ethanol, hexane, or benzene may be used for the first dissolution processor 384 to increase the solubility of the etching gas.

The second dissolution water supply unit 390 includes a passivation gas supply source 392, a second dissolution processing unit 394 for dissolving the passivation gas supplied from the passivation gas supply source 392 in deionized water to produce a second dissolution water, . ≪ / RTI > For example, the second dissolved water supply unit 392 may be made of fluorocarbon gas (C4F8), but is not limited thereto, and various passivation gases may be used.

A solvent such as a solvent or a polymer may be used in the second dissolution processor 394 to increase solubility of the passivation gas.

In order to increase the efficiency with which the etching gas and the passivation gas are dissolved in the deionized water, it is preferable to use deionized water which has been deaerated beforehand. Deaeration of the deionized water ideally removes various gases previously dissolved in the deionized water and may increase the capacity of the gas dissolution to dissolve the desired gas. In other words, if various gases remain in the deionized water before dissolving the desired gas, the capacity for dissolving the desired gas in the deionized water may be insufficient and the desired concentration may not be obtained. In this respect, there is a possibility that the concentration of the gas dissolved in the deionized water can not be set at a desired concentration based on the change in the flow rate of the deionized water. Particularly, when a gas having a low solubility is dissolved in deionized water, it is necessary to previously deionize the deionized water in order to maintain a constant concentration even if the flow rate of the deionized water fluctuates.

Referring again to Figures 2 and 3, the second moving nozzle member 900 is moved over the center of the substrate through the swing movement to dispense processing fluid for cleaning and drying on the substrate. The second moving nozzle member 900 includes a supporting shaft 910, a driving portion 920, a nozzle arm 940, and a second nozzle 980.

The second movable nozzle member 900 is connected to a cleaning fluid supply unit 860 for selectively supplying water vapor (or cleaning liquid vapor) and cleaning liquid.

5 is a view showing a cleaning fluid supply unit connected to the second movable nozzle member.

5, the cleaning fluid supply 960 may include a cleaning solution source 962, a vapor generator 964 to vaporize the cleaning solution, and a pure water vapor supply 966. [ Here, the cleaning solution may contain dissolved water in which at least one gas phase substance having an etching action with respect to the substrate surface is dissolved.

The second nozzle 980 includes a cylindrical nozzle body 984 and a nozzle body 984 having a plurality of injection holes 982 for spraying water vapor so that the cleaning solution water vapor (chemical vapor) And a central injection nozzle 986 for spraying the cleaning solution. The central injection nozzle 986 is connected to the cleaning solution supply source 962 and the injection holes 982 are connected to the steam generating part 964 and the water vapor supplying part 966.

Meanwhile, the second nozzle 980 may be connected to a drying fluid supply unit 970.

FIG. 6 is a flow chart showing a substrate processing method in the substrate processing apparatus shown in FIG. 2, and FIG. 7 is a process sectional view showing a pattern forming method according to the etching step and the passivation step.

6 and 7, a substrate processing method according to an embodiment of the present invention includes an etching step S10, a purge step S20, a passivation step S30, a purge step S40, a cleaning step S50 , And a drying step (S60). Here, the etching step S10, the purge step S20, the passivation step S30, and the purge step S40 are repeated until a desired pattern is formed on the substrate.

6, the substrate W includes an etch mask layer pattern 95 having an opening 94 that exposes a portion of the surface of the etch target layer 92 above the etch target layer 92. The etching mask layer pattern 95 has an exposed upper surface that is sufficiently larger than the exposed surface area of the etching target layer 92 exposed by the opening 94. The exposed portion of the etching target layer 92 exposed by the opening 94 is a portion where a trench 96 of a certain depth is to be formed. In one example, the etch target layer 92 may include at least one of sapphire, silicon, polysilicon, oxide, nitride, and metal. In one example, the etch mask layer pattern 95 may be formed of a photoresist layer.

In the etching step S10, the first dissolved water is supplied to the surface of the rotating substrate to etch the exposed portion of the etching target layer 92.

In the passivation step S30, the second dissolution water is supplied to the surface of the rotating substrate to deposit or form the passivation layer 97 on the surface of the etched portion.

On the other hand, when the etching and passivation steps S10 and S30 are completed, the purge steps S20 and S40 may be performed, respectively. The purge steps S20 and S40 may include a step of replacing the inside of the chamber by supplying an inert gas or spraying ultrapure water onto the surface of the substrate to remove dissolved water remaining on the surface of the substrate.

As described above, the present invention utilizes vaporization, liquefied etching gas or pacification gas without a dry etching process. Thus, the clean, uncontaminated environment can be maintained by the etching, cleaning and pacification processes in one chamber without moving between chambers. In addition, the concentration of dissolved water can be applied not only to patterns with high AR, but also to overetching issues.

8 and 9 are views for explaining a cleaning process.

If a desired pattern is formed on the substrate through the etching step (S10), the purge step (S20), the passivation step (S30), and the purge step (S40), as shown in FIGS. 6, 8 and 9, .

The cleaning step S50 may include a pre-treatment step and a solution cleaning step. The cleaning step S50 proceeds while the substrate rotates.

As shown in FIG. 8, in the pretreatment step, the atmosphere inside the chamber is replaced by steam. The pretreatment step may be performed in a chamber atmosphere in a low vacuum (for example, 10 < -3 > torr). That is, in the pretreatment step, the cleaning solution (or etching solution) in the form of vapor penetrates into the gas in the pattern first, so that the cleaning process can be easily performed due to the preservation of the dissolved amount of the cleaning solution and the polarity of the same properties.

In the pre-treatment step, the second nozzle 980 receives pure steam from the chemical vapor or water vapor supply unit 966 from the vapor generating unit 964, and supplies the vapor to the substrate W.

In the pretreatment step, the chemical vapor may be used as a cleaning solution or water vapor or pure water vapor in which at least one gas phase substance having an etching action on the substrate surface is dissolved.

As in FIG. 9, the solution cleaning step causes the cleaning solution to be discharged onto the substrate surface to clean the substrate surface. The solution cleaning step is performed in an atmospheric pressure environment. The cleaning solution is fed to the top of the rotating substrate through the central injection nozzle 986. [

As described above, surface infiltration and modification are initiated by line discharge such as chemical vapor or pure water vapor, so that penetration into small particles (etching residues) existing deep inside the pattern surface having high AR is easy.

10 is a view for explaining the drying step.

Referring to FIG. 10, the drying step may be performed by providing IPA vapor for drying, inert gas without pervisable vapor, or the like on a rotating substrate in a chamber atmosphere of a low vacuum or atmospheric pressure, .

By supplying IPA vapor or feasible vapor in the drying step, it is possible to reduce the occurrence of lining by controlling the surface energy between the patterns and hydrophobic reforming.

In addition, when an inert gas or an ultra pure water vapor is supplied in the drying step, the generation of static electricity can be reduced.

11A to 14 are views showing another example of the present invention.

According to the present embodiment, an electric field is formed on the substrate during the cleaning step to induce the behavior of the etching residue from the substrate surface, thereby improving the cleaning efficiency. The electric field induction can be applied to the electric field induction using the bias power and the electric field induction using the alternating current.

11A and 11B are diagrams for explaining an electric field induction method using a bias power in a substrate cleaning process.

11A, when a positive (+) / negative (-) bias is given, the particles (particles) having positive ions are given by F = qE field is given.

11B, when the lower electrode 710 is provided in the spin head 210 and the upper electrode (plate-shaped conductor) 720 is mounted on the nozzle arm to apply bias power to the electrode, The behavior of the E-field makes it easier for the small particles (etching residues) having positive polarity to move to the upper surface of the substrate W. [

12 is a view showing a lower electrode 710 provided in the spin head 210. A plurality of lower electrodes 710 may be provided in a ring shape and each of the ring electrodes may be connected to a spin head 210 The crossbar 712 formed radially from the center of rotation of the electrode assembly 710. [

FIGS. 13A and 13B are diagrams for explaining an electric field induction method using alternating current in a substrate cleaning process, and FIG. 14 is a view showing another modification of the upper electrode.

FIG. 13A shows a principle that an electric field is generated when an induced current flows through the second electrode when two current-circulating electrodes (conductive wires) are arranged side by side while changing the current value to the first electrode.

As shown in FIG. 13B, unlike the bias power, when a current is shaken only on one electrode, a magnetic field is formed. Therefore, when an electric force (current is shaken) is applied to only one electrode, Will influence. Here, the lower electrode 730 may be provided in a ring shape within the spin head 210, and the upper electrode 740 may be provided in a ring shape within the wide nozzle body 799 as shown in FIG. 13B. To this end, a power supply unit 760 may be provided for applying an alternating current value to the upper electrode while varying the value of the alternating current.

If it is difficult to mount the ring-shaped upper electrode in the nozzle, the ring-shaped upper electrode 750 may be separately formed on the spin head 210 as shown in FIG. 14, It is preferable that the lifting mechanism 750 has a lifting structure capable of moving up and down.

As described above, electrodes (conductive rings or conductive plates) are mounted on the inner surface of the spin head 210, the spray surface of the nozzle, or the lower surface of the spin head 210 to induce an electric field so that small particles (mainly positive polarity) remaining in the deep trench pattern ) F = qE given in this field can improve the efficiency of cleaning by providing mobility to the outside of the trench.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

800: chamber 100: processing vessel
200: substrate supporting member 300: first moving nozzle member
400: exhaust member 900: second moving nozzle member

Claims (18)

Etching the substrate surface;
Pacifying the substrate surface; And
Cleaning the substrate surface;
The substrate cleaning step
A substrate processing method for inducing the behavior of etching residues from a substrate surface through induction of an electric field on the substrate. The method according to claim 1,
The electric field induction
A bias power or an alternating current is applied. The method according to claim 1,
The electric field induction
If the value of the alternating current provided to one of the first electrode and the second electrode in the form of a ring arranged on the upper and lower sides of the substrate is changed, an induced current flows in the other electrode, ≪ / RTI > 3. The method according to claim 1 or 2,
The substrate cleaning step
A pretreatment step of replacing the atmosphere inside the chamber with water vapor; And
And a solution cleaning step of cleaning the substrate using a cleaning solution. 5. The method of claim 4,
The water vapor
Wherein at least one gas phase substance having an etching action on the cleaning solution or the substrate surface is dissolved. 5. The method of claim 4,
The pre-
Is performed in a chamber atmosphere of a low vacuum state,
The solution cleaning step
In a chamber atmosphere at atmospheric pressure. 5. The method of claim 4,
Further comprising a drying step of drying the substrate after the cleaning step;
The drying step
A substrate processing method for providing an IPA vapor or an inert gas for drying onto a rotating substrate in a chamber atmosphere at a low vacuum or atmospheric pressure. The method according to claim 1,
The etching step
The surface of the substrate is etched by using a first dissolving water in which at least one kind of gas phase substance having an etching action on the substrate surface is dissolved in deionized water,
The passivation step
Wherein the surface of the substrate is subjected to pacification using a second dissolving water in which at least one gas phase substance having a passivating action on the substrate surface is dissolved in deionized water. 9. The method of claim 8,
The etching step
Supplying the first dissolved water to the substrate surface in a vapor state or a liquid state,
The passivation step
And the second dissolved water is supplied to the surface of the substrate in a vapor state or a liquid state. The method according to claim 1,
The etching step, the passivation step, and the cleaning step
Wherein the substrate is processed in the same chamber, and the chamber is a closed chamber. A process chamber providing an atmospheric pressure or a low vacuum atmosphere;
A substrate support member installed in an inner space of the process chamber and on which a substrate is placed; And
And a first nozzle member for supplying the dissolution water onto the substrate placed on the substrate support member;
The substrate support member and the first nozzle member
Wherein an upper electrode and a lower electrode are provided for inducing an electric field on the substrate to induce the behavior of the etching residue from the substrate surface. 12. The method of claim 11,
And a bias current is applied to the upper electrode and the lower electrode. 12. The method of claim 11,
Wherein the lower electrode and the upper electrode are formed in a ring shape,
Further comprising a power supply unit for applying an alternating current value to at least one of the lower electrode and the upper electrode while changing the value of the alternating current. 12. The method of claim 11,
A first dissolving water supply unit for supplying a first dissolving water to the first nozzle member, the first dissolving water having at least one kind of gaseous material having an etching action on the substrate surface dissolved in deionized water; And
Further comprising a second dissolving water supply unit for supplying a second dissolving water to the first nozzle member, the second dissolving water dissolving at least one gas phase substance having a passivating action on the substrate surface in deionized water. 15. The method of claim 14,
The first dissolved water supply unit
Supplying the first dissolved water in a vapor state or a liquid state,
The second dissolved water supply unit
And supplies the second dissolved water in a vapor state or a liquid state. 12. The method of claim 11,
A second nozzle member for supplying a cleaning fluid onto the substrate placed on the substrate support member; And
Further comprising a cleaning fluid supply portion for selectively supplying water vapor and a cleaning solution to the second nozzle member. 17. The method of claim 16,
The water vapor
Wherein at least one gas phase substance having an etching action on the cleaning solution or the substrate surface is dissolved. 17. The method of claim 16,
The second nozzle member
A cylindrical nozzle body having a plurality of spray holes for spraying water vapor so that water vapor is sprayed over the entire surface of the substrate; And
And a central injection nozzle located at the center of the nozzle body for spraying the cleaning solution.

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