WO2008016004A1 - Method for film formation, apparatus for film formation, computer program, and storage medium - Google Patents

Abstract

This invention provides a method for film formation, comprising properly selecting process conditions for the formation of a film such as a barrier layer or an auxiliary seed film, shaving off the bottom part of a recess part under the process conditions, and forming a thin film on the side and upper faces while removing a layer causative of an electrical resistance rise in the bottom part of the shaved recess part. A metallic target (78) is ionized within a processing container (34) to produce metal ion-containing metallic particles, and metallic particles are drawn into an object (W) mounted on a mounting table (44) by bias electric power to form a thin film on the surface of the object with a recess part (5) formed in the surface thereof. While the bottom part of the lowermost layer in the recess part in the object is shaven to form a shaved recess part (12), a first metal-containing barrier layer (10) is formed on the object in its whole surface including the surface within the recess part (barrier layer formation step). Next, the bottom part of the shaved recess part is further shaved, and a second metal-containing auxiliary seed film (14A) for plating is formed on the object in its surface including the surface within the recess part (auxiliary seed film formation step).

Description

 Specification

 Film forming method, film forming apparatus, computer program, and storage medium

 Technical field

 [0001] The present invention relates to a film forming method, a film forming apparatus, a computer program, and a memory for effectively forming a thin film such as a metal film on the surface of a recess formed on the surface of an object to be processed such as a semiconductor wafer. It relates to the medium.

 Background art

 [0002] In general, in order to manufacture a semiconductor device, a semiconductor device is repeatedly subjected to various processes such as a film forming process and a pattern etching process to manufacture a desired device. Line widths and hole diameters are becoming increasingly finer due to the demand for higher miniaturization. As wiring materials and embedding materials, there is a tendency to use copper, which has a very low electric resistance and is inexpensive, because it is necessary to reduce the electric resistance by miniaturizing various dimensions (Japanese Patent Laid-Open No. 2000-77365). Publication). When copper is used as the wiring material or embedding material, the tantalum metal (Ta) or tantalum nitride (TaN) isostatic S barrier layer is generally considered in consideration of adhesion to the lower layer. Used as

 In order to form this NOR layer, a tantalum nitride film (hereinafter also referred to as “TaN film”) or a tantalum film (hereinafter referred to as “Ta film”) is used as a base layer on the wafer surface in a plasma sputtering apparatus. Next, a barrier layer is formed by forming a tantalum film (changing film forming conditions when the underlayer is a Ta film) in the same plasma sputtering apparatus. Thereafter, a thin seed film made of a copper film is formed on the surface of this NOR layer, and then the entire surface of the wafer is subjected to a copper plating process so as to fill the recess.

[0004] By the way, when the lower wiring layer and the upper wiring layer stacked with the insulating film interposed therebetween are electrically connected, the insulating layer is formed on the lower wiring layer and then the insulating layer is formed. A communication hole such as a via hole or a through hole is formed in the layer so that the lower wiring layer is exposed at the bottom of the communication hole, and then the communication hole is embedded with the material of the upper wiring layer and at the same time, the upper wiring layer It is designed to deposit. As described above, the line width and hole diameter are further reduced due to the demand for miniaturization. The connection structure between the lower wiring layers has also been devised to lower its electrical resistance. As an example, the bottom of the communication hole is shaved to a predetermined depth in the thickness direction of the lower wiring layer so that the contact resistance between the embedding material for embedding the communication hole and the lower wiring layer is made smaller. Structure is adopted. Such a structure is called a so-called punch-through structure, and this production method is called a so-called punch-through process.

[0005] However, in such a punch-through process, the bottom of the recess is scraped off. | J The force that forms the recess s and the recess with the same depth that does not depend on the width of the recess. It is difficult to form a part. In addition, it is difficult to form a seed layer with high accuracy in the recess.

 Disclosure of the invention

 [0006] The present invention has been devised to pay attention to the above problems and to effectively solve them. The object of the present invention is to appropriately treat the process conditions during film formation such as the seed layer and the seed layer so that only the bottom of the bottom layer of the recess is selectively scraped and the surface to be processed includes the surface in the recess. A thin film can be formed on the entire surface of the body, and the bottom can be scraped off to the same depth without depending on the width of the recess to form a recess with the same depth. A film forming method, a film forming apparatus, a computer program, and a storage medium capable of forming a thin film on a side surface and an upper surface of a recess while removing, for example, a Ta 'Cu mixed layer that causes an increase in electrical resistance at the bottom of the portion There is.

 [0007] When forming a metal film by plasma sputtering, the present inventors have appropriately adjusted process conditions such as bias voltage, direct current power to the metal target, and plasma power to neutral atoms of metal particles. The present invention has been achieved by obtaining the knowledge that a metal film can be formed over the entire surface of the wafer including the surface of the semiconductor wafer by controlling the ratio of the metal particle ions to the metal wafer.

In addition, the inventors of the present invention can increase the number of neutral atoms of metal particles compared to ions during plasma sputtering processing, particularly by setting the process pressure larger than that in the conventional processing, thereby flattening the wafer surface. Cu neutral atoms predominate on the surface and side walls, and a Cu film can be actively deposited, while metal ions and gas ions that are drawn deeply by bias power become dominant at the bottom of the deep recess. The bottom can be further scraped off. By obtaining this knowledge, the present invention has been achieved.

 [0008] The present invention includes a step of placing an object to be processed having a recess formed on a surface of a mounting table provided in a processing vessel that can be evacuated, and an inert gas in the processing vessel. The metal target is ionized by the plasma formed by plasma generation to generate metal particles containing metal ions, and the metal particles are drawn into the target object mounted on the mounting table in the processing container by bias power. And forming a thin film containing the metal on the surface of the object to be processed, and the step of forming a thin film on the surface of the object to be processed is formed by shaving the bottom of the recess of the object to be processed. A barrier layer forming step of forming a barrier layer containing the first metal on the entire surface of the object to be processed including the surface in the recess while forming a portion, and further cutting the bottom of the cut-in recess Before including the surface in the recess A film forming method characterized by having an auxiliary seed film formation step of forming an auxiliary seed layer for a plated including the second metal on the surface of the object.

 [0009] According to the present invention, by appropriately selecting the process conditions at the time of film formation of the barrier layer, the auxiliary seed film, etc., only the bottom of the bottom layer of the recess is selectively scraped, and the surface in the recess is removed. A thin film can be formed over the entire surface of the object to be processed. It is possible to cut the bottom part by the same depth without depending on the force and the width of the concave part to form a cut-in hollow part of the same depth, and further increase the electrical resistance at the bottom of the cut-out hollow part. For example, a thin film can be formed on the side surface and the upper surface of the recess while removing the Ta ′ Cu mixed layer.

 [0010] The present invention is a film forming method characterized in that after the auxiliary seed film forming step, a main seed film forming step of forming a main seed film for plating is performed.

 [0011] The present invention is a film forming method, wherein a plating step of applying plating with the second metal is performed after the seed film forming step.

 [0012] In the present invention, the barrier layer forming step includes a base film forming step of forming a base film made of the first metal nitride film on the entire surface of the object to be processed including the surface in the recess. A film forming method, comprising: forming a main nano film made of the first metal alone on at least a side wall in the recess while forming the cut recess. is there.

[0013] In the present invention, it is preferable that the first metal is made of Ta and the second metal is made of Cu. This is a characteristic film forming method.

In the present invention, the barrier layer forming step includes forming a base film made of the first metal nitride film on the entire surface of the object to be processed including the surface in the recess, and A main barrier film forming step of forming a main nora film made of the first metal alone on at least a side wall in the recess while forming the cut-in depression, and an auxiliary barrier film containing a third metal And an auxiliary barrier film forming step for forming the film.

Yes

 [0015] The present invention is a film forming method characterized in that after the auxiliary barrier film forming step, a plating process for applying a plating with the second metal is performed.

 [0016] The present invention is the film forming method, wherein the first metal is made of Ta, the second metal is made of Cu, and the third metal is made of Ru.

 [0017] The present invention is the film forming method, wherein the auxiliary seed film forming step is performed by setting the pressure in the processing container within a range of 30 to 90 mTorr.

 [0018] The present invention is the film forming method, wherein the auxiliary seed film forming step is performed by setting the bias power within a range of 100 to 250 watts.

 [0019] The present invention is the film forming method, wherein the auxiliary seed film forming step is performed by setting an electric power for forming the plasma in a range of 0.5 to 2 kilowatts.

 [0020] The present invention provides a film forming method, wherein the concave portion of the object to be processed has a communication hole to be a via hole or a through hole, and is formed in a two-step step shape! is there.

 [0021] The present invention is the film forming method, wherein the concave portion includes a communication hole that becomes a via hole or a through hole.

[0022] The present invention provides a processing container that can be evacuated, a mounting table for mounting a target object having a recess formed on a surface thereof, and a predetermined container containing at least an inert gas in the processing container. A gas introduction means for introducing a gas; a plasma generation source for generating plasma power and generating a plasma of an inert gas in the processing vessel; and a DC power source applied to the processing vessel. A metal target to be ionized by the plasma, a bias power source that supplies a predetermined bias power to the mounting table, a gas introduction unit, a plasma generation source, and a device control unit that controls the bias power source, In a film deposition system equipped with The apparatus controller further comprises a thin film containing a second metal on the surface of the object to be processed including the surface in the recess by further scraping the bottom of the cut-in recess in the recess. The film forming apparatus is characterized in that the gas introducing means, the plasma generation source, and the noise power source are controlled so as to form an auxiliary seed film for use.

 [0023] According to the present invention, in a computer program for causing a computer to execute a film forming method, the film forming method includes: a mounting table provided in a processing container that is evacuated; A step of placing the object to be processed and a plasma formed by converting the inert gas into a plasma in the processing container to ionize a metal target to generate metal particles containing metal ions, Forming a thin film containing the metal on the surface of the object to be processed by drawing the particles into the object to be processed placed on the mounting table in the processing container by bias power, and the surface of the object to be processed In the step of forming a thin film, an auxiliary seed film for plating containing a second metal is formed on the surface of the object to be processed including the surface in the recess by further cutting the etched recess in the bottom in the recess. Form A computer program characterized by comprising an auxiliary sheet over de film forming step.

 [0024] The present invention provides a storage medium storing a computer program for causing a computer to execute a film forming method. The film forming method is performed on a surface of a mounting table provided in a processing container that can be evacuated. A metal target containing ions is generated by ionizing a metal target using a plasma formed by plasma forming an inactive gas in the processing container, and placing the object to be processed with recesses on the substrate. And drawing the metal particles into a target object placed on a mounting table in the processing container by bias power to form a thin film containing the metal on the surface of the target object. The step of forming a thin film on the surface of the processing object further comprises a step of further cutting away the cut-in recess at the bottom of the recess to supplement the plating for the metal containing the second metal on the surface of the object to be processed including the surface in the recess. A storage medium characterized by having an auxiliary seed film formation step of forming a seed film.

 [0025] According to the film forming method, film forming apparatus, and storage medium according to the present invention, the following excellent operational effects can be exhibited.

By appropriately selecting the process conditions at the time of film formation such as the nori layer and the auxiliary seed film, only the bottom of the bottom layer of the recess is selectively scraped, and the object including the surface in the recess is removed. A thin film can be formed over the entire surface. It is possible to cut the bottom part by the same depth without depending on the width of the concave part, and to form a hollow part having the same depth, and further increase the electrical resistance at the bottom part of the hollow part. For example, a thin film can be formed on the side surface and top surface of the recess while removing the Ta′Cu mixed layer.

 Brief Description of Drawings

 FIG. 1 is a cross-sectional view showing an example of a film forming apparatus according to the present invention.

 [FIG. 2] FIG. 2 is a graph showing the angle dependency of the patch etching.

 FIG. 3 is a graph showing the relationship between the bias power and the amount of film formation on the upper surface of the wafer.

 [FIG. 4] FIGS. 4 (A) to (H) are flowcharts for explaining a first embodiment of the method of the present invention.

 [FIG. 5] FIG. 5 is a partially enlarged view showing the bottom of the communication hole (the bottom of the cut-in recess) when the main barrier film is formed.

 FIG. 6 is a graph showing the relationship between the aspect ratio of the recess and the copper etching rate at the bottom.

 [FIG. 7] FIGS. 7A and 7B are diagrams schematically showing the trend of Cu metal particles when the process pressure is low and when the process pressure is high.

 [FIG. 8] FIGS. 8A to 8D are graphs showing the deposition rate of the Cu film when the plasma power and the bias power are variously changed.

 FIGS. 9A and 9B are diagrams showing a part of the steps of the second embodiment of the method of the present invention.

 [FIG. 10] FIGS. 10 (A) to 10 (C) are process diagrams showing a part of a modification of the method for forming a NOR layer including a TaN film.

 [FIG. 11] FIGS. 11 (A) to 11 (C) are views showing a state before the communication holes formed on the semiconductor wafer are embedded.

 [FIG. 12] FIGS. 12 (A)-(E) are diagrams showing a process of filling a communication hole.

 [FIG. 13] FIGS. 13A and 13B are views showing embodiments of recesses (trench) having various widths. BEST MODE FOR CARRYING OUT THE INVENTION

In order to better understand the present invention, an example of a general punch-through process will be described with reference to FIG. 11 and FIG. Fig. 11 embeds the communication holes formed on the semiconductor wafer. 11 (A) is a plan view, FIG. 11 (B) is a cross-sectional view taken along line A—A in FIG. 11 (A), and FIG. 11 (C) is a perspective view. Each is shown. FIG. 12 is a diagram showing the process of embedding the communication holes.

 The semiconductor wafer W is made of, for example, a silicon substrate, and a lower wiring layer 2 made of, for example, copper and an insulating layer 4 made of a silicon oxide film or the like are sequentially laminated on the surface of the silicon substrate. A recess 5 is formed on the surface of the insulating layer 4. In this recess 5, here, a wiring groove having a predetermined width for forming an upper wiring layer, that is, a trench 6 is formed, and the insulating layer 4 is partially penetrated at the bottom of the trench 6. A via hole or a through hole 8 is formed to communicate with the lower wiring layer 2! The diameter L1 of the communication hole 8 is very small, for example, about 60 to 200 nm, and the width L2 of the concave portion 5, that is, the trench 6 is, for example, about 60 to 1000 nm.

 In order to embed the communication hole 8 and the trench 6 as described above, first, as shown in FIG. 12A, the entire surface of the wafer W including the surface in the trench 6 and the communication hole 8 is formed on the lower surface. A barrier layer 10 made of a metal film is formed by, for example, plasma sputtering for the purpose of improving adhesion to the base layer, preventing diffusion of copper into the insulating layer 4 and preventing migration. The barrier layer 10 mainly employs, for example, a two-layer structure of a tantalum nitride film (TaN film) and a tantalum film (Ta film), or a two-layer structure of tantalum films formed with different film formation conditions. Is done.

 Next, as shown in FIG. 12 (B), for example, plasma etching using Ar gas as an inert gas is performed to scrape off the noble layer 10 formed on the bottom of the communication hole 8, and then Etching is performed on the lower wiring layer 2 as a base, and a concavity 12 having a predetermined depth is formed therein.

 Next, as shown in FIG. 12 (C), for example, by sputtering, the seed layer 14 for electroplating is extremely applied to the entire surface including the above-described etched recess 12, the communication hole 8, and the inner surface of the trench 6. Form thinly. Here, as the seed layer 14, for example, a copper (Cu) film is used because copper plating is performed in a later step.

Next, as shown in FIG. 12 (D), electric plating is performed with the seed layer 14 as a starting point, and the above-described cut-out depression portion 12, the communication hole 8, and the trench 6 are connected to the upper wiring layer 16. Embed each with materials. As the material of the upper wiring layer 16, for example, copper is used as described above. As shown in FIG. 12 (E), the upper wiring layer 16 electrically connected to the lower wiring layer 2 is formed by scraping off unnecessary metal material on the upper surface by polishing or the like.

 As described above, the shape force of the recess 5 having a communication hole 8 such as a through hole or a via hole at the bottom of the trench 6 and the cross section of which is a stepped shape in two stages, so-called dual damascene (Dual Damascene) ) Called structure.

 By the way, in the conventional film forming method as described above, in the plasma etching process as shown in FIG. 12 (B), for example, the particles of the barrier layer scattered by the etching at the corner as shown at the point P1. It has the characteristic of scattering with directivity within an angle range confined to a specific direction. In this case, the problem was not particularly noticeable when the line width and groove width were quite wide. Force As described above, when the groove width or the like is reduced to about lOOnm, the particles scattered in the specific direction may adhere to the opposing wall surface and form the deposited protrusions 18 there. When the deposited protrusions 18 are generated in this way, a portion that is a shadow of the deposited protrusions 18 is generated in the plasma snow / flying process shown in FIG. Thus, there is a problem that a so-called shadowing phenomenon occurs and the seed layer 14 does not adhere to the shadow portion 20 of the deposited protrusion 18. When a portion where the seed layer 14 does not adhere is generated in this way, as shown in FIG. 12 (D), a void, that is, a void 22 is generated in this portion, which is preferable!

 [0033] FIG. 13 is a diagram showing the form of the recesses 5 (trench 6) having different widths L2. The surface of the force semiconductor wafer W actually has a width L2 as shown in FIG. There are many different types of recesses 5. In this case, even if the aspect ratio of the communication hole 8 (this diameter L1 is the same) is the same, if the aspect ratio of the trench 6 is different, the upper side from the bottom of the communication hole 8 Since the angles Θ1 and Θ2 are different as shown in the figure (θ1 <Θ2), the thicknesses Hl and H2 of the barrier layer 10 deposited on the bottom of the communication hole 8 which is the bottom layer of the recess are different. End up. For this reason, due to the difference in the thicknesses Hl and H2 of the barrier layer 10, the barrier layer is scraped off, resulting in variations in the depth of the cut recess 12 formed at the bottom. There was a problem.

[0034] In FIG. 12A, when forming the NOR layer 10, a part of the Ta metal is added to the NOA current. The Ta'Cu mixture, which is drawn into the force and is deeply driven into the Cu underlayer wiring layer 2 at the bottom of the communication hole 8 and increases the electrical resistance even if the dent 12 is formed here, It remained and became a cause of increasing the connection electric resistance in this portion.

Next, an embodiment of a film forming method, a film forming apparatus, a computer program, and a storage medium according to the present invention will be described in detail with reference to the accompanying drawings.

 FIG. 1 is a cross-sectional view showing an example of a film forming apparatus according to the present invention. Here, an ICP (Inductively Coupled Plasma) type plasma sputtering apparatus will be described as an example of the film forming apparatus. As shown in the figure, the film forming apparatus 32 includes a processing container 34 formed into a cylindrical shape with, for example, aluminum. The processing vessel 34 is grounded, and an exhaust port 38 is provided at the bottom 36, and can be evacuated by a vacuum pump 42 through a throttle valve 40.

 [0036] In the processing container 34, a disk-shaped mounting table 44 made of, for example, aluminum is provided, and an electrostatic chuck 46 is installed on the upper surface of the mounting table 44. The semiconductor wafer W as the object to be processed can be adsorbed and held on the substrate. Note that a DC voltage for suction (not shown) is applied to the electrostatic chuck 46 as necessary. The mounting table 44 is supported by a support column 48 extending downward from the center of the lower surface, and the lower portion of the support column 48 penetrates the container bottom 36. The column 48 can be moved up and down by an elevator mechanism (not shown), and the table 44 itself can be moved up and down.

 [0037] A bellows-shaped metal bellows 50 is provided so as to be stretchable so as to surround the support column 48, and the upper end of the metal bellows 50 is airtightly joined to the lower surface of the mounting table 44, Further, the lower end is airtightly joined to the upper surface of the bottom portion 36, and the up / down movement of the mounting table 44 can be allowed while maintaining the airtightness in the processing vessel 34. The mounting table 44 is formed with a refrigerant circulation path 52 through which a refrigerant for cooling the wafer W flows. This refrigerant is not shown in the support column 48! /, And is supplied / discharged through the flow path! /, The

[0038] Further, for example, three support pins 54 (only two are shown in the illustrated example) are provided upright on the container bottom 36 so as to correspond to the support pins 54. A pin insertion hole 56 is formed in the mounting table 44 described above. Therefore, when the mounting table 44 is lowered, the wafer W is received by the upper end portion of the support pin 54 penetrating the pin through hole 56 and is received. The wafer W from the outside is not shown! /, And can be transferred to and from the transfer arm. Therefore, a gate valve 58 that can be opened and closed is provided on the lower side wall of the processing vessel 34 to allow the transfer arm to enter.

 Further, the electrostatic chuck 46 provided on the mounting table 44 is connected to, for example, 13.

 A bias power source 62 composed of a high frequency power source that generates a 56 MHz high frequency is connected, and a predetermined bias power can be applied to the mounting table 44 described above. The bias power supply 62 can control the output bias power as required.

 [0040] On the other hand, on the ceiling of the processing vessel 34, a transmission plate 64 that is permeable to high frequencies made of a dielectric material such as aluminum nitride is hermetically sealed through a seal member 66 such as an O-ring. Is provided. Further, on the outside of the transmission plate 64, a plasma generation source 70 is provided in the processing space 68 in the processing vessel 34 for generating plasma by, for example, converting Ar gas as plasma gas into plasma. As this plasma gas, another inert gas such as He or Ne may be used instead of Ar. Specifically, the plasma generation source 70 has an induction coil portion 72 provided in correspondence with the transmission plate 64. The induction coil portion 72 has a high frequency of 13.56 MHz for generating plasma, for example. A power source 74 is connected so that a high frequency can be introduced into the processing space 68 through the transmission plate 64. Here, the plasma power output from the high-frequency power source 74 can be controlled as necessary.

In addition, a baffle plate 76 made of, for example, aluminum is provided immediately below the transmission plate 64 to diffuse the introduced high frequency. At the lower part of the baffle plate 76, a metal target 78 is provided so as to surround the upper side of the processing space 68. For example, the cross section is inclined inward to form an annular shape (a frustoconical shell shape). A variable DC power supply 80 is connected to the metal target 78. The DC power output from the variable DC power supply 80 can also be controlled as necessary. Here, as the metal target 78, for example, tantalum metal is used when forming a Ta film or TaN film, and copper is used when forming a Cu film. These metals are sputtered as metal atoms or metal atomic groups by Ar ions in the plasma, and are mostly ionized when passing through the plasma. [0042] Further, a cylindrical protective cover 82 made of, for example, aluminum is provided below the metal target 78 so as to surround the processing space 68. Is bent inward and is located near the side of the mounting table 44 described above. Further, at the bottom of the processing vessel 34, for example, a gas introduction port 84 is provided as a gas introduction means for introducing a predetermined gas required into the processing vessel 34. The gas inlet 84 is supplied as a plasma gas through a gas control unit 86 including, for example, an Ar gas and other necessary gases such as N2 gas, a 1S gas flow controller, a valve, and the like.

 Here, each component of the film forming apparatus 32 is connected to and controlled by an apparatus control unit 88 formed of, for example, a computer. Specifically, the device control unit 88 controls the operations of the noise power source 62, the high-frequency power source 74 for plasma generation, the variable DC power source 80, the gas control unit 86, the slot valve 40, the vacuum pump 42, etc. When a thin film such as a metal film is formed, it operates as follows.

 First, under the control of the apparatus control unit 88, Ar gas is allowed to flow while operating the gas control unit 86 into the processing vessel 34 that has been evacuated by operating the vacuum pump 42, and the throttle valve 40 is controlled to control the processing vessel. The inside of 34 is maintained at a predetermined degree of vacuum. Thereafter, direct current power is applied to the metal target 78 via the variable direct current power source 80, and further high frequency power (plasma power) is applied to the induction coil unit 72 via the high frequency power source 74.

 On the other hand, the device control unit 88 also issues a command to the bias power source 62 and applies a predetermined bias power to the mounting table 44. In the processing vessel 34 controlled in this way, argon plasma is generated by the power applied to the metal target 78 and the induction coil unit 72 to generate argon ions, and these ions collide with the metal target 78. The metal target 78 is sputtered to release metal particles.

Further, most of the metal atoms and metal atomic groups that are metal particles from the sputtered metal target 78 are ionized when passing through the plasma. Here, the metal particles are scattered in a downward state in a state where ionized metal ions and electrically neutral metal atoms are mixed. In particular, metal ions are attracted by the bias power applied to the mounting table 44, and have high directivity with respect to the wafer W, and are deposited on the wafer W on the mounting table 44 as metal ions. As will be described later, the apparatus control unit 88 can attract Ar ions in the plasma toward the mounting table 44 by giving a command to output a large output to the bias power source 62, for example. It is achieved that both sputter etchings occur simultaneously. Here, the control of each component of the apparatus is controlled by the apparatus control unit 88 based on a program created so that the metal film is formed under a predetermined condition. At this time, for example, a program including instructions for controlling each component is stored in a storage medium 90 such as a floppy disk (FD), a compact disk (CD), a flash memory, and the like, and a predetermined program based on this program is stored. Each component is controlled to perform the process under the following conditions.

 Next, a film forming method of the present invention performed using the film forming apparatus 32 configured as described above will be described.

 Fig. 2 is a graph showing the angle dependence of sputter etching, Fig. 3 is a graph showing the relationship between the bias power and the amount of film formed on the upper surface of the wafer, and Fig. 4 is a flowchart for explaining the first embodiment of the method of the present invention. FIG.

[0047] First, the first feature of the method of the present invention is that, in a specific step in a series of film formation processes, when a thin film such as a metal film is formed by sputtering film formation by plasma, bias power, direct current It is to control the power, plasma power, etc. to an appropriate magnitude. As a result, film formation by drawing into metal ions and sputter etching with plasma gas (Ar ions) occur simultaneously, and the bottom of the bottom of the recess is set to a state where it is scraped off and formed on the semiconductor wafer. It is possible to deposit a metal film on the surface while forming a hollow portion by scraping the bottom portion of the lowermost layer of the recessed portion. Specifically, the bias power at this time is determined by the film formation rate by drawing metal ions and the sputter etching etching rate by plasma gas (Ar ⁺ ) on the surface facing the metal target 78, that is, the upper surface of the wafer in FIG. Is set to a size that approximately balances

[0048] The second feature of the present invention is that when forming a metal film by plasma sputter deposition, the pressure in the processing vessel (process pressure) is set to be considerably higher than in the conventional method. The amount of neutral metal atoms generated in the metal particles is larger than the amount of metal generated, and as a result, the neutral metal atoms predominate on the wafer surface and side wall portions, and the metal film is actively deposited. It is. On the other hand, at the bottom of the deep depression, metal ions and gas ions drawn to the back by the bias power become dominant, and the Ta ′ Cu mixed layer at the bottom, for example, is further scraped off.

 [0049] The above points will be described in more detail.

First, considering the characteristics of the etching rate of sputter etching using plasma gas without considering the amount of film formation, the relationship between the angle of the sputter surface and the etching rate is as shown in the graph in FIG. Here, the angle of the sputtered surface refers to the angle formed by the normal of the sputtered surface and the incident direction (downward direction in FIG. 1) of the sputtering gas (Ar ion: Ar ⁺ ). 12) are both "0 degree" and the side walls of the recess are "90 degree".

 [0050] As is apparent from this graph, the upper surface of the wafer (sputter surface angle = 0 degree) is subjected to sputtering to some extent, and the side wall of the recess (sputter surface angle = 90 degrees) is almost sputter etched. In addition, it can be seen that the corners of the opening of the recesses (sputter surface angle = around 40 to 80 degrees) are sputter etched considerably intensely.

 [0051] Now, in the film forming apparatus including the ICP type sputtering apparatus as shown in FIG. 1, the relationship between the bias power applied to the wafer W side and the film forming amount deposited on the upper surface of the wafer (not the side wall of the recess). Is as shown in Fig. 3. That is, in a situation where a constant plasma power and a constant DC power to the metal target 78 are applied, if the bias power is not so high, a high film formation amount is caused by metal ion attraction and neutral metal atoms. As the obtained power and bias power increase, the wafer surface gradually becomes more prone to be sputtered by argon ions, which are plasma gases accelerated by the bias power (see Fig. 2). The film is etched.

[0052] As a matter of course, this etching becomes more severe as the bias power increases. Therefore, when the film formation rate by the drawn metal ions and neutral metal atoms and the etching rate of the sputter etching by the plasma gas ions are the same, the film formation and the etching are offset, and the film formation amount force S " The condition at this time corresponds to point XI (bias power: 350 W) in Fig. 3. Note that the bias power and the amount of film formation in FIG. 3 are merely examples, and the above characteristic curve can be obtained by controlling the plasma power and DC power. It fluctuates as shown by the one-dot chain line in Fig. 3.

 [0053] Conventionally, a condition generally operated in this type of sputtering apparatus is the region A1, and a high film formation amount (film formation rate) can be obtained without increasing the noise power. It was an area that could be done. In other words, the amount of film formation is the region where the metal ions are almost the same as when the bias is zero (etching by inert gas plasma does not occur) and the maximum amount of metal ions to be drawn. This is a region where the film formation amount can be earned. On the other hand, here, it is performed mainly in a region where film formation by attracted metal ions and neutral metal atoms and sputter etching by plasma gas occur simultaneously. More specifically, as described above, the etching is performed in the region A2 on the upper surface of the wafer where the film formation rate by the drawn metal ions and neutral metal atoms and the etching rate of the sputter etching by the plasma gas are substantially balanced. Here, the “approximately balanced” is not limited to the case where the film formation amount on the upper surface of the wafer is “zero”, but is formed with a slight film thickness of about 3/10 compared with the film formation amount in the area A1. This includes cases where film thickness is generated.

 [0054] Now, after understanding the above phenomenon, the method of the present invention will be described.

 First, in FIG. 1, with the mounting table 44 lowered, the wafer W is loaded into the processing chamber 34 that can be evacuated through the gate valve 58 of the processing chamber 34, and the wafer W is placed on the support pins 54. To support. When the mounting table 44 is raised in this state, the wafer W is transferred to the upper surface, and the wafer W is adsorbed to the upper surface of the mounting table 44 by the electrostatic chuck 46.

 [0055] Then, after the wafer W is mounted on the mounting table 44 and fixed by suction, the film forming process is started. At this time, on the upper surface of the wafer W, a recess 5 (see FIG. 4A) having the same structure as that described with reference to FIG. That is, the insulating layer 4 is formed on the lower wiring layer 2 made of Cu, and the recess 5 is formed in the insulating layer 4. The recess 5 is formed of a groove-like trench 6 (see FIG. 11 (A)), and a communication hole 8 such as a via hole or a through hole is formed at the bottom so as to reach the wiring layer 2. It is made into a stepped shape! /

[0056] First, tantalum is used as the first metal as the metal target 78, and after the inside of the processing vessel 34 is evacuated to a predetermined pressure, an induction coinor of the plasma generation source 70 is used. Plasma power is applied to the unit 72, and a predetermined bias power is applied to the electrostatic chuck 46 of the mounting table 44 from the bias power source 62. Furthermore, a predetermined direct current power is applied to the metal target 78 from the variable direct current power source 80 to perform film formation. First, as shown in FIG. 4B, a base film forming step for forming the base film 10A is performed as a part of the NOR layer forming process. Here, in order to form a TaN film, that is, a first metal nitride film as the base film 10A, in addition to Ar gas, which is a plasma gas from the gas inlet 84, for example, N2 gas is used as a nitriding gas in the processing vessel 34. To supply. As a result, as shown in FIG. 4B, a TaN film is formed as a base film 10A substantially uniformly not only on the top surface of the wafer W but also on the side walls and bottom surface in the recess 5. The noise power at this time is the area A1 in FIG. 3, which is the same as the conventional general film formation conditions, and is specifically about 100 W (watts).

[0057] After the formation of the base film 10A is completed as described above, a main barrier film forming step is then performed to form a Ta film as the main barrier film 10B made of the first metal alone. Thus, the NOR layer 10 is formed. That is, in this main nano film formation step, the bias power is increased and set in the region A2 in FIG. In this first embodiment, the main nano film forming step is such that the film deposition amount by the metal particles and the etching amount by the plasma of the inert gas are substantially the same on the surface of the wafer W other than the recess 5. The conditions are set so that the amount of film formation by the metal particles on the surface of the wafer W other than the recess 5 is slightly larger than the etching amount by the plasma of the inert gas. The second step may be used, or the second step may be used alone.

 For example, in the case of the first and second steps, the bias power is set to point XI in FIG. 3 in order to set the film formation amount on the wafer upper surface to “zero” in the first step. The bias power at this time is specifically 350 W. At this time, the supply of N2 gas is stopped and only Ar gas is supplied from the gas inlet 84. As a result, as shown in FIG. As shown, the bottom of the lowermost layer (corresponding to the communication hole 8) of the recess 5 is scraped off, so that the upper surface side of the wiring layer 2 made of Cu is scraped, and a shaved recess 12 is formed here.

The reason why the film is hardly formed as described above is explained as follows. That is, as described above, the magnitude of the bias power is set to the area A2 in FIG. 3, more specifically, to the point XI. As a result, the film formation rate by the metal ions and neutral metal atoms drawn on the upper surface of the wafer and the etching rate of the sputter etching by the plasma gas (Ar ⁺ ) are substantially balanced, resulting in the formation of the metal film. This is because the etching rate is larger than the film formation rate at the bottom of the communication hole 8 of the recess 5 while the amount is substantially zero. As a result, the bottom of the communication hole 8 is cut away. Will go. The above items can be expressed at the atomic level for the wafer unit area as follows.

[0060] <Wafer upper surface>

∑Ta + ∑Ta ⁺ = ∑Ar ⁺

 <Bottom of communication hole 8>

∑Ta ⁺ <∑Ar ⁺

Here, Ta represents a neutral metal atom, Ta ⁺ represents a metal ion, and both contribute to the formation of a metal film. On the other hand, Ar ⁺ is an Ar ion and contributes to etching. Therefore, Ta and Ta ⁺ reach sufficiently on the upper surface of the wafer, and Ar ⁺ also reaches sufficiently, resulting in a film formation amount of “zero”.

On the other hand, since the hole diameter is very small at the bottom of the communication hole 8, Ta ⁺ and Ar ⁺ with high directivity reach Ta, which is a neutral metal atom with poor directivity, reaches. It is difficult to do. As a result, the bottom of the communication hole 8 is scraped off as much as Ta that contributes to the film formation does not reach. The amount of scraping at this time is controlled by controlling the processing time of the first step. For the sake of simplicity, it is assumed here that one Ta and Ta ⁺ film is projected (etched) from the surface formed by Ar ⁺ 1 collision. Yes.

When this first step is completed, the process proceeds to the second step. In this second step, the bias power is set to a point other than point XI in area A2, such as A3, and the metal thickness is much less than the film deposition rate in area A1. A film is formed. As a result, a Ta film is formed as the main nore film 10 on the entire wafer surface excluding the bottom of the communication hole 8, that is, on the surface in the recess 5 and the side surface of the communication hole 8. Also in this case, the bottom of the communication hole 8 has a higher etching rate than the film formation rate for the reason described above, and therefore the Ta film is further scraped away without adhering. For this reason, the X The shape is even larger. That is, ^{"ΣTa + ΣTa +> ΣAr +} " in the top surface of the wafer, the 〃ShigumaTa ^task ShigumaAr ⁺ "at the bottom of the communication hole 8. Also, Etsu Chin Great bottom of the case, the top surface of the wafer Therefore, the amount of metal particles contributing to the film formation is set to be larger than the sputter ions so that the film is slightly deposited.

 As described above, since the film formation amount on the wafer surface and the sputter etching amount are balanced in the first step, the base film in FIG. 4 (B) is obtained even after the process of FIG. 4 (C) is completed. The thickness of 10A does not change. Therefore, the base film 10A can have a thickness of, for example, 3.5 nm on the wafer surface and 1. Onm at the bottom of the communication hole 8 regardless of the depth of the hole in the recess IJ recess 12. LOnm or less, more preferably 5 nm or less.

 [0063] On the other hand, in the conventional film formation method, the thickness of the barrier layer 10 in FIG. 12A varies depending on the depth of the hole in the cut-in recess, and when the depth is about 50 nm, About 60nm is required. This is because the wafer surface is simultaneously etched by the Ar etching process shown in FIG. Furthermore, when a 60 nm undercoat film is formed on the wafer surface! /, The bottom of the communication hole! /, The force of about 10 nm to 20 nm, the thickness! /, The formation of a barrier layer is avoided. This indicates that, in the initial stage of the etching process (Fig. 12 (B)), the etched recess is not formed and only the NOR layer is etched.

 [0064] In the present application, the conditions are set so that the film formation amount on the wafer surface becomes substantially zero through the first and second steps, and as described in FIG. Accumulated protrusions 18 do not occur. Further, the depth of the etched recess 12 formed here is substantially uniform in the wafer plane regardless of the width L2 of the recess (see FIG. 13) since the base film at the bottom of the communication hole is extremely thin. I can do it.

Here, ideally, as described above, the Ta film does not adhere to the bottom of the communication hole 8 (the bottom of the cut-out recess 12), but actually, in the first and second steps described above. It is inevitable that a small amount of Ta film (main nano film) adheres to the bottom. That is, FIG. 5 is a partially enlarged view showing the bottom of the communication hole (the bottom of the cut-out recess 12) when the main barrier film is formed (see FIG. 4 (D)) and adheres to the side wall of the communication hole 5. Main barrier film (Ta film) 10B thickness H 1 is a force that makes the film thicker. Even at the bottom part, a slight force H and a main force film 10B are attached. This thickness H2 is, for example, about lnm.

[0066] Further undesirably, Ta ⁺ ions are attracted by the bias power in the vicinity of the bottom, so Ta ⁺ ions are implanted into the Cu wiring layer 2 and this is the cause of the increase in electrical resistance. The Ta 'Cu mixed layer 100 is formed. As a result, when a Cu seed film is formed in this state and Cu plating is further applied, it is affected by the Ta'Cu mixed layer 100 and the main noor film 10B made of a Ta film having a thickness of H2. As a result, the connection electrical resistance at this portion increases.

 [0067] Here, the force shown in the case where both the first and second steps are performed. Even in the first step, the Ta film is very slightly formed on the wafer surface, the recess 5, the side wall of the communication hole 8, or the like. Since this deposits and forms a TaN / Ta barrier film, only one of the first and second steps may be performed. Even in this case, the problem of electric resistance due to the Ta ′ Cu mixed layer 100 and the Ta film of thickness H2 arises.

 Therefore, in the present invention, in order to eliminate the problem of the Ta film or Ta′Cu mixed layer 100 having the above-mentioned thickness H2, the Ta film or Ta′Cu mixed film having the above-mentioned thickness H2 is formed in the subsequent auxiliary seed film forming step. Tier 1

00 is to be removed.

 That is, as described above, when the barrier layer forming process for forming the barrier layer 10 having the stacked structure of the TaN film and the Ta film is completed, the process proceeds to the auxiliary seed film forming process, which is a feature of the present invention. .

First, this wafer W is loaded into a film forming apparatus having the same structure as that shown in FIG. 1 in which the metal target 78 is formed of copper instead of tantalum, and the above-described cutting is performed as shown in FIG. 4 (E). Further, the bottom portion of the recess 12 is further cut to form an auxiliary seed film 14A for plating made of a thin film containing the second metal on the wafer surface including the surfaces in the recess 5 and the communication hole 8. Here, Cu is used as the second metal, and the auxiliary seed film 14A is made of a Cu film. Here, when the auxiliary seed film 14A made of a Cu film is formed, the bottom of the indentation recess 12 is punched and further IJ is removed, and the upper surface side of the wafer as well as the communication hole 8 and A Cu film is deposited on each side surface of the recess 5, and the process conditions are set so that the force and the corner 102 of the step in the recess 5 are not adversely affected. [0069] As such process conditions, for example, when a Cu film is formed by plasma sputtering according to a conventional method, the process pressure is set to, for example, about 5 mTorr. Set it fairly high, for example within the range of 30 to 90 mTorr. The bias power is set within a range of 100 to 250 watts (0.32 W / cm ^{2 to} 0.8 W / cm ² ), for example.

 [0070] Furthermore, the power for forming plasma in the plasma generation source 70, that is, the power of the high-frequency power source 74 is set within a range of 0.5 to 2 kilowatts.

As described above, by setting the process pressure in the above-described range, the concentration of plasma is increased, and the amount of neutral metal atoms of copper, which is a factor mainly for film formation, on the upper surface side of the wafer is increased. More than the total ion of Cu ⁺ ions and Ar ⁺ ions that cause etching, the neutral metal atoms become dominant, and in the deep part of the communicating hole 8, the neutral metal atoms of copper The amount of Cu ⁺ ions and Ar ⁺ ions that are attracted by the bias power is increased more than the neutral metal atoms so that these ions become dominant.

As a result, as described above, the auxiliary seed film 14A made of a Cu film can be deposited thinly on the other surface while further shaving the bottom of the shaving depression 12 downward. Here, as described above, the bottom portion of the engraved depression 12 is further scraped off, so that the Ta′Cu mixed layer 100 located here can be scraped off and removed. For example, the region A2 in FIG. 3 is used for such an auxiliary seed film forming step except that the process pressure is different. Also, since the adhesion force between Cu and Cu ⁺ ions is lower than that of Ta, Cu ⁺ ions act on the deposited Cu film as an etching factor in the A2 region of bias power (see Fig. 3). .

 [0072] When the auxiliary seed film formation step is completed in this way, the process then proceeds to the present seed film formation step, in which the plasma power is set in region A1 in FIG. Under the same conditions, as shown in FIG. 4 (F), the seed layer 14B made of copper is formed not only on the top surface of the wafer but also on the side wall and bottom of the recess 5 to make it thin. Thus, the seed layer 14 having a laminated structure of the auxiliary seed film 14A and the present seed film 14B is formed.

It should be noted that the film forming apparatus on which the copper metal target as described above is mounted has the above tantalum gold. A semiconductor wafer that can be connected to a film forming apparatus equipped with a metal target via a transfer chamber that can be evacuated can be transferred between both film forming apparatuses in a vacuum atmosphere without being exposed to the atmosphere. Can do.

 After the seed layer 14 is formed in this way, the wafer W is taken out of the film forming apparatus and subjected to a normal plating process to perform a plating process, as shown in FIG. 4 (G). 5 is completely filled with the material of the wiring layer 16 made of copper.

 Next, as shown in FIG. 4 (H), unnecessary portions on the upper surface of the wafer are scraped off by polishing to complete the formation of the upper wiring layer 16.

 As described above, in the above embodiment, only the bottom part of the lowermost layer of the recess 5 is selectively selected by properly selecting the process conditions at the time of film formation of the NOR layer 10 and the auxiliary seed film 14A. A thin film can be formed over the entire surface of the wafer including the surface in the recess 5 while removing. Moreover, it is possible to cut the bottom part by the same depth without depending on the width of the concave part 5 to form the cut-in hollow part 12 having the same depth, and further increase the electrical resistance of the bottom part of the cut-in hollow part 12. For example, a thin film can be formed on the side surface and upper surface of the recess 5 while removing the Ta ′ Cu mixed layer 100.

 Here, the setting conditions of the above-mentioned nora layer forming step (first and second steps), that is, the setting conditions that can realize the area A2 in FIG. 3 are as follows.

 Plasma power: 500 ~ 6000W

 DC power: 100-2000W

 Noise power: 100—2000W

 Actually, as described above, the operating point is set in the region A2 by appropriately selecting the above three conditions. In this case, if the operating point is set in a portion other than the region A2, the soaked IJ recess 12 is not sufficiently formed, so that a so-called punch-through structure cannot be formed.

 As other process conditions, the flow rate of Ar gas is in the range of about 50 to 1000 sccm, and the process pressure is in the range of about 0.001 Torr (0. lPa) to 0.1 torr (13.3 Pa).

In the barrier layer forming step, the case where the TaN film is formed as the base film 1 OA has been described as an example, but instead, the Ta film may be formed as the base film 10A. . In this case, since the Ta film 10B is formed on the Ta film serving as the base film 10A, the barrier layer 10 is formed in a two-layer structure of Ta films having different film formation conditions.

 [0077] Here, as a result of evaluating the etched recess 12 formed by the method of the present invention and the conventional method, when the conventional method is used, a deposited protrusion is formed at the upper end opening of the recess 5. Unfavorable force In the case of the method of the present invention, it was confirmed that the deposited protrusions 18 were not generated, and the cut-in recess 12 could be formed in a good state.

 [0078] Next, the evaluation of the dependence of the aspect ratio of the ridge IJ recessed dent 12 formed at the bottom of the recess 5 on the aspect V will be described.

 FIG. 6 is a graph showing the relationship between the aspect ratio of the recess and the copper etching rate at the bottom. Here, the concave portion was not formed in a two-step shape but was formed as a single-step concave portion. In FIG. 6, characteristic A shows the case of the conventional method, and characteristic B shows the case of the method of the present invention.

 [0079] Specifically, in the conventional method, a barrier layer of approximately 60 nm was plasma sputtered on the wafer surface for the recesses having various aspect ratios, and then Ar etching was performed for a predetermined time. The depth of the cut recess formed at this time was measured and used as the copper etching rate. In the method of the present invention, a base film of about 4 nm was plasma sputtered on the wafer surface with respect to the recesses having various aspect ratios, and then the first step was performed for the same predetermined time as the conventional method. Further, the depth of the cut recess formed at this time was measured to obtain the copper etching rate.

 [0080] As is apparent from FIG. 6, when the aspect ratio is small in both characteristics A and B, the aspect ratio is large! /, And the amount of film formed on the bottom of the recess increases compared to the case. Ching rate decreases. In the case of the conventional method shown in the characteristic A, the etching rate of copper changes as the aspect ratio increases. Therefore, the depth of the recess 12 is changed due to the difference in the aspect ratio. This means that it is not preferable. On the other hand, in the case of the method of the present invention shown in the characteristic B, the copper etching rate is greatly changed when the aspect ratio is 2 or less, and the copper etching rate is substantially constant when the aspect ratio is 2 or more. I understand!

[0081] Here, in the general recess 5, the aspect ratio is often 2 or more. According to the above, it was confirmed that the depth of the ridge ij recessed portion 12 related to the aspect ratio can be made substantially uniform, and good results can be obtained. Thus, since the depth of the ridge IJ recess 12 is not affected by the shape of the recess 5, it is possible to always form a recess with the same depth without depending on the width of the recess. it can.

Next, the process conditions of the auxiliary seed film formation step shown in FIG. 4 (E) are evaluated.

 First, in order to remove the Ta film 10 B having a thickness of H2 and the Ta′Cu mixed layer 100 having a large electric resistance generated at the bottom of the etched recess 12 in the process shown in FIG. It is conceivable to remove the Ta′Cu mixed layer 100 and the like by performing plasma sputtering with Ar gas at a relatively low process pressure, for example, about 5 mTorr. However, in this case, the force S that can remove the Ta film 10B having a thickness of H2 and the Ta'Cu mixed layer 100 in the above-described cut-out recess 12 is S, and at the same time, the entire wafer surface, in particular, the recess It is not preferable because the corners of step 5 (102: see Fig. 4 (C)) will be damaged by Ar gas sputtering.

 Therefore, in the present invention, using the portion of region A2 in FIG. 3, using a metal target, the bottom portion of shore IJ recess 12 is further scraped downward to form Ta ′ Cu mixed layer 100. A force to deposit a little metal film on the other wafer surface during removal In this case, the seed film 14B made of Cu film (see Fig. 4 (F)) is attached in the next process. In this case, Cu, which is the same material as the seed film 14B, is used as the metal target, and as a result, the auxiliary seed film 14A made of the Cu film is deposited.

 [0084] Here, when the auxiliary seed film 14A is deposited using a Cu metal target and the swelled recess 12 is scraped off further deeply, if the process pressure is set low as described above, the average number of atoms As the free process becomes larger, the number of collisions with the wafer surface increases and the damage increases. Therefore, the process pressure is increased to some extent, specifically, in the present invention, the process pressure is set within a range of 30 to 90 mTorr, and the metal film is formed while suppressing damage of the wafer surface due to ions. At the same time, the bottom of the dent 12 is shaved deeper.

FIG. 7 shows a part of the situation at this time, and is a diagram schematically showing the trend of Cu metal particles when the process pressure is low and high. Here, a high frequency as shown in Fig. 1 is applied to the recess. Fig. 7 (A) shows a case where the process pressure is low, for example, 5mTorr (conventional method), and Fig. 7 (B) shows a high process pressure. In this case, for example, indicate 50 mTorr (invention method)!

[0086] According to this, in the case of the conventional method shown in Fig. 7 (A), since the process pressure is low, the mean free path of ions and each atom becomes long. As a result, Cu ⁺ ions are applied to the wafer surface. A large number of collisions cause a lot of damage to the Ta film, etc. previously deposited, while the deposited Cu is blown again, reducing the amount of Cu deposited. In contrast, in the case of the present invention the method shown in FIG. 7 (B), the mean free path of the cloud 110 of Cu occurs in the processing space ion and each atom is shortened, and was a Cu ⁺ ions The Cu metal atoms that jump out of the deposited film are rebounded by the Cu cloud 110, and the Cu metal atoms behave again to be deposited on the wafer surface. As a result, in the case shown in Fig. 7 (B), the amount of Cu deposited on the wafer surface increases. Therefore, in the state shown in Fig. 7 (B), by controlling the bias power, Cu ⁺ ions and Ar ⁺ ions are strongly attracted downward except for the neutral metal atoms, so that the bottom of the recess is removed. It will be scraped off by sputtering.

 Next, evaluation of plasma power in the auxiliary seed film formation step will be described.

 Fig. 8 shows the results of this evaluation and is a graph showing the Cu film deposition rate when the plasma power and bias power are variously changed. Here, the process pressure was kept constant at 50 mTorr and the DC power supplied to the metal target was maintained at 3.2 kW. The bias power was changed in the range of 0 to 200 watts [W]. Regarding plasma power, Fig. 8 (A) shows 4kW, Fig. 8 (B) shows 3kW, Fig. 8 (C) shows 2kW, and Fig. 8 (D) shows lkW. As is clear from the figure, when the plasma power is 3kW (Fig. 8 (B)) and 4kW (Fig. 8 (A)), the deposition rate is "0" when the bias power is 100W or more. Can not do it.

 On the other hand, when the plasma power is 2 kW (FIG. 8C), a Cu film is slightly deposited even when the bias power exceeds 00 W, and can be used to some extent. In addition, in the case of plasma power SlkW (Fig. 8 (D)), it was confirmed that the Cu film was sufficiently deposited in the range of 0 to 200 W of bias power, which was good.

Although not shown in the graph, the plasma power is 0.5 kW. When an experiment similar to the above was performed, it was found that the battery was sufficiently usable. Furthermore, when the plasma power was set smaller than 0.5 kW, plasma could not be generated stably. Therefore, it was confirmed that the plasma power is preferably set within the range of 0.5 to 2 kW.

 [0089] Regarding the bias power in the auxiliary seed film formation step, as a result of experiments,

 If the bias power preferred in the 250 W range is less than 100 W, the ion attraction becomes too weak to further scrape the bottom of the concavity 12, and the bias power If it is larger than 250 W, the damage to the wafer surface or the like becomes excessively large, and the amount of Cu film formation becomes too small.

 [0090] Next, a second embodiment of the method of the present invention will be described.

 FIG. 9 is a diagram showing a part of the steps of the second embodiment of the method of the present invention. In the method of the present invention, in the first embodiment shown in FIG. 4, the step of forming the main noor film 10B made of the Ta film shown in FIG. 4D and the auxiliary seed film 14A shown in FIG. 9A, an auxiliary barrier film forming step for forming an auxiliary barrier film 10C containing the third metal is performed. Here, as the third metal, for example, Ru (ruthenium) or the like can be used. The auxiliary barrier film 10C made of this Ru film is formed on the entire surface including the inner surfaces of the recess 5 and the communication hole 8 by using, for example, CVD (Chemical Vapor Deposition). As a result, the NOR layer 10 has a three-layer structure of the base film 10A, the main barrier film 10B, and the auxiliary NOR film 10C.

As described above, when the auxiliary barrier film 10C made of the Ru film is formed, this Ru film also functions as an auxiliary seed film. Therefore, after the formation of the auxiliary barrier film 10C, FIG. After the auxiliary seed film 14A shown in FIG. 4 is formed, the process can proceed to the plating process shown in FIG. 4G without performing the process of forming the seed film 10B shown in FIG. 4F. FIG. 9B shows the final cross-sectional shape in the case of the second embodiment. In this case, the seed layer 14 is formed by the auxiliary norr film 10C and the auxiliary seed film 14A. .

In addition, since the auxiliary noor film 10C made of the Ru film also functions as a seed film for Cu, Cu plating is directly applied on the auxiliary barrier film 10C of the Ru film without providing the auxiliary seed film 14A for the Cu film. You may make it give. [0092] Further, the method for forming the Ta film or TaN film for forming the NOR layer 10 is not particularly limited. For example, plasma power or the like is repeatedly supplied and stopped at intervals of several seconds, for example, The thin film may be formed by the so-called ALD (Atomic Layer Deposition) method in which a thin film is formed one by one at an atomic level.

 <Modification of TaN Film Formation Method>

 Next, a modified example of the method of forming the TaN film that becomes the base film 10A of the barrier 10 will be described. As is well known, the TaN film used for the barrier layer 10 is made of Cu, which is a wiring material or an embedding material, as an interlayer insulating film. This prevents diffusion to a certain insulating layer 4. However, since this TaN film is a metal nitride film, the resistivity is considerably higher than that of Cu as well as of Ta film. Therefore, this TaN film must have a sufficient thickness at the part where the Cu wiring is in contact with the insulating layer 4, and if it exists with a certain thickness at the bottom of the via hole, that is, the bottom of the communication hole 8, Not only will the via resistance at the bottom of the via hole connected to the wiring layer increase, the electrical characteristics of the Cu wiring will deteriorate, but the reliability will also decrease. This phenomenon occurs not only when the wiring material is Cu but also when other metal materials such as tungsten are used.

 Therefore, in this modification, the TaN film at the bottom of the communication hole 8 such as a via hole is selectively removed by a method different from the punch-through process described above. Specifically, when forming a TaN film, the thickness of the TaN film deposited on the bottom of the communication hole (via hole) 8 is a process that is extremely small compared to the thickness of the TaN film deposited on other parts. After setting the conditions, the TaN film is selectively removed by removing the TaN film deposited at the bottom of the communication hole 8 by removing the TaN film by performing Ar etching or the like.

 [0095] In other words, the mean free path of atoms and molecules is relatively long! / Under low pressure! / And neutral Ta atoms and neutral N atoms released from metal targets are Because the incident light is incident at a certain angle with respect to the vertical direction of the wafer, the probability of reaching the bottom of the communication hole 8 which is the bottom of the via hole is very low. The side wall of the trench 6 and the bottom of the trench 6, that is, the step The film can be sufficiently formed on the part.

[0096] On the other hand, the traveling direction of Ta ions, which are charged with electricity, is changed by the electric force. Although it is the same as the vertical direction of C, Ta and N atoms tilted to a certain degree to the vertical direction are required to form a film on the side wall of the communication hole 8. Therefore, in this modification, by optimizing the ratio of neutral Ta atoms or neutral N atoms to Ta ions, the TaN film is formed on the sidewall of the trench 6, the bottom (step) of the trench 6, and While forming a film on the side wall of the communication hole 8, it is necessary to create a state where it is difficult to form a film on the bottom of the communication hole 8!

 [0097] For the process conditions that create the state as described above, the noise power is zero.

 (Vertical axis in FIG. 3), the process pressure is 8 mTorr or less, preferably 5 mTorr or less. The plasma power, which is ICP power, is in the range of 0.75-1.5 kW, preferably in the range of 0.8 to 1.2 kW. When the TaN film is formed as described above, the entire TaN film is removed little by little by etching in the subsequent process, for example, Ar etching. In this case, the TaN film is formed in the thinnest communication hole 8. Since the TaN film at the bottom is completely removed first, only the TaN film at the bottom of the communication hole 8 can be selectively removed by ending the etching at this point.

 Next, a series of flows including the film forming process will be described with reference to FIG. FIG. 10 is a process diagram showing a part of a modification of the method for forming a barrier layer including a TaN film.

 First, as shown in FIG. 4 (A), as shown in FIG. 10 (A), as shown in FIG. 1, a wafer W having a communication hole 8 such as a trench 6 or a via hole formed on the surface as shown in FIG. Using the film forming apparatus 32, the TaN film is formed to form the base film 1OA. In this case, not only the uppermost surface of the wafer W but also the side wall 6A of the trench 6, the side wall 8A of the communication hole 8, and the step portion of the trench 6, that is, the bottom portion 6B of the trench, is sufficiently strong. The process conditions are set so that film formation is unlikely to occur on the bottom 8B of the communication hole 8. As a result, for example, if the film thickness HI of the wafer top surface is “100”, the film thickness H2 of the bottom 6B of the trench 6 is about “50”, and the film thickness H3 of the bottom 8B of the communication hole 8 is “20”. Thus, a difference in film thickness can be created.

Regarding the process conditions as described above, as described above, the bias power is zero and the process pressure force is mTorr or less, preferably 5 mTorr or less. The plasma power is in the range of 0.75 to 1.5 kW, preferably (or in the range of 0.8 to 1.25 kW. In this way, the bias power is set to zero and etching hardly occurs. A TaN film is deposited, where the bias power is set to zero S and the wafer W is sealed with plasma. For example, a voltage of about 20 to 30 volts is applied, so that ions are attracted to the wafer side to some extent.

 [0100] If the bias power is applied, Ta ions are attracted too much, and the communication hole

 This is not preferable because the film thickness H3 deposited on the bottom 8B of 8 becomes too large. Also, as the plasma power and process pressure increase, the proportion of Ta ions to neutral elements increases. If the plasma power is higher than 1.5kW or the process pressure is higher than 8mTorr, the proportion of Ta ions will become too large, and the thickness H3 of the TaN film deposited on the bottom 8B of the communication hole 8 will be The difference between the film thickness H3 and the film thicknesses HI and H2 in other parts becomes too small! / \ Preferably! /.

[0101] Conversely, if the plasma power is made smaller than 0.75 kW, the ratio of Ta ions to neutral elements becomes too small, and the amount of film formation on the bottom 6B of the trench 6 to be originally formed becomes too small. It is not preferable. Even if the process pressure is lowered from ⁸ mTorr to near the base pressure (10-9 Torr), there will be no special problems as described above!

 [0102] Once the base film 10A made of the TaN film is formed as described above, the base film 10A made of the TaN film is thinned by performing Ar sputtering as shown in FIG. 10B. Scrap off. In this case, the TaN film on the entire surface is gradually scraped off by Ar sputtering, but the TaN film with the thickness H3 deposited on the bottom 8B of the communication hole 8 with the smallest thickness is selected first. However, the etching process is completed when the lower wiring layer 2 is slightly removed by over-etching. In this way, since only the TaN film at the bottom 8B of the communication hole 8 can be completely removed, it is possible to improve the electrical characteristics by reducing the resistance of this part, that is, the via resistance.

 [0103] As described above, when the Ar sputtering process is completed, for example, as shown in FIG. 10C, by performing a CVD process, for example, a Ru film is formed on the entire surface of the trench 6 and the communication hole 8. The auxiliary nano film 10C is formed. This is the same process as shown in Fig. 9 (A).

Yes

Thereafter, as shown in FIG. 9B, a seed film 14A may be formed and Cu plating may be applied, or the auxiliary noble film 10C made of this Ru film may be used as a seed film. Since it functions, it is possible to apply a Cu plating process directly on this. It is not limited to.

 [0104] Further, here, after forming the base film 10A made of the TaN film shown in Fig. 10 (A), the force for performing the Ar sputtering treatment shown in Fig. 10 (B) is not limited to this, and the base film After forming 10A, the main barrier film 10B made of Ta film shown in FIG. 4 (D) is formed, and then the processes described in FIGS. 4 (E) to 4 (H) are continuously performed. You may make it carry out.

 In any case, by adopting the TaN film formation method described above, the film thickness of the bottom 8B of the communication hole 8 can be made very small compared to the film thickness of other parts. Since only this portion of the TaN film can be selectively removed, for example, via resistance can be suppressed and electrical characteristics can be improved.

 [0105] In the above embodiments, the communication hole 8 is formed in a part of the recess 5, and the force described by taking the recess 5 formed in a so-called two-stage step shape as an example is not limited to this. The present invention can also be applied to a so-called one-step recess in which the recess 5 itself is a through hole 8 for a through hole or a via hole.

 Further, the numbers in the above-described embodiments are merely examples, and it is needless to say that the numbers are not limited thereto. In the above embodiment, the force described by taking the TaN / Ta / Cu, Ta / Ta / Cu laminated structure as an example of the laminated structure of the barrier film / seed film as a whole is not limited to this kind of laminated structure, for example, TiN / The present invention also relates to a Ti / Cu laminated structure, a TaN / Ru / Cu laminated structure, a Ti / Cu laminated structure, and a TiN / Ti / Ru, Ti / Ru, TaN / Ru, and TaN / Ta / Ru laminated structure. Of course, the method can be applied.

 [0106] Furthermore, the frequency of each high-frequency power source is not limited to 13.56 MHz, and other frequencies such as 27.0 MHz can also be used. Further, the inert gas for plasma is not limited to Ar gas, and other inert gas such as He or Ne may be used.

 Further, here, the force S described by taking the semiconductor wafer as an example of the object to be processed is not limited thereto, and the present invention can be applied to an LCD substrate, a glass substrate, a ceramic substrate, and the like.

Yes

Claims

The scope of the claims

 [1] A step of placing an object to be processed having a recess formed on a surface of a placing table provided in a processing vessel that is evacuated;

 The metal target is ionized by plasma formed by converting the inert gas into plasma in the processing container to generate metal particles containing metal ions, and the metal particles are placed on a mounting table in the processing container. And a step of drawing the object to be processed by bias power to form a thin film containing the metal on the surface of the object to be processed.

 The step of forming a thin film on the surface of the object to be processed includes

 A barrier layer forming step of forming a barrier layer containing a first metal on the entire surface of the object to be processed, including the surface in the recess, while scraping the bottom of the recess of the object to be processed to form a dent. ,

 An auxiliary seed film forming step of further cutting the bottom of the cut-out depression and forming an auxiliary seed film for plating containing a second metal on the surface of the object to be processed including the surface in the recess;

 A film forming method comprising:

2. The film forming method according to claim 1, wherein after the auxiliary seed film forming step, a main seed film forming step of forming a main seed film for plating is performed.

[3] The film forming method according to [2], wherein after the seed film forming step, a plating step of applying plating with the second metal is performed.

[4] The barrier layer forming step includes

 A base film forming step of forming a base film made of a nitride film of the first metal on the entire surface of the object to be processed including the surface in the recess;

 2. A main nor film forming step of forming a main nor film made of the first metal alone on at least a side wall in the recess while forming the cut recess. The film forming method.

[5] The film forming method according to claim 1, wherein the first metal is made of Ta and the second metal is made of Cu.

[6] The barrier layer forming step includes A base film forming step of forming a base film made of a nitride film of the first metal on the entire surface of the object to be processed including the surface in the recess;

 A main noble film forming step of forming a main noble film made of the first metal alone on at least a side wall in the concave part while forming the cut-in hollow part;

 An auxiliary barrier film forming step of forming an auxiliary barrier film containing a third metal;

 The film forming method according to claim 1, comprising:

7. The film forming method according to claim 6, wherein after the step of forming the auxiliary barrier film, a plating step for performing plating with the second metal is performed.

8. The film forming method according to claim 5, wherein the first metal is made of Ta, the second metal is made of Cu, and the third metal is made of Ru.

[9] The film forming method according to claim 1, wherein the auxiliary seed film forming step is performed by setting a pressure in the processing container within a range of 30 to 90 mTorr.

10. The film forming method according to claim 1, wherein the auxiliary seed film forming step is performed by setting the bias power within a range of 100 to 250 watts.

[11] The film forming method according to claim 1, wherein the auxiliary seed film forming step is performed by setting an electric power for forming the plasma within a range of 0.5 to 2 kilowatts.

12. The film forming method according to claim 1, wherein the concave portion of the object to be processed has a communication hole to be a via hole or a through hole, and is formed in a two-stage step shape.

13. The film forming method according to claim 1, wherein the concave portion is a communication hole that becomes a via hole or a through hole.

[14] a processing vessel made evacuable,

 A mounting table for mounting an object to be processed having a recess formed on the surface;

 A gas introduction means for introducing a predetermined gas containing at least an inert gas into the processing container;

 A plasma generation source for generating plasma power and generating plasma of an inert gas in the processing vessel;

A metal target to be ionized by the plasma, provided in the processing vessel, to which direct current power is applied; A film forming apparatus comprising: a bias power source that supplies a predetermined bias power to the mounting table; a gas introduction unit; a plasma generation source; and a device control unit that controls the noise power source.

 The apparatus control unit further cuts the bottom of the cut-in recess in the recess to form an auxiliary seed film for plating comprising a thin film containing a second metal on the surface of the object to be processed including the surface in the recess. A film forming apparatus characterized by controlling a gas introduction means, a plasma generation source, and a noise power source so as to form a film.

[15] In a computer program for causing a computer to execute a film forming method, the film forming method includes:

 Placing the object to be processed having a recess formed on the surface thereof on a mounting table provided in the processing container that is evacuated; and

 The metal target is ionized by plasma formed by converting the inert gas into plasma in the processing container to generate metal particles containing metal ions, and the metal particles are placed on a mounting table in the processing container. And a step of drawing the object to be processed by bias power to form a thin film containing the metal on the surface of the object to be processed.

 The step of forming a thin film on the surface of the object to be processed includes

 A step of forming an auxiliary seed film for forming a plating auxiliary seed film containing a second metal on the surface of the object to be processed, including the surface in the concave part, by further shaving the dent in the bottom of the concave part; A computer program comprising:

[16] In a storage medium for storing a computer program for causing a computer to execute a film forming method,

 The film formation method is

 Placing the object to be processed having a recess formed on the surface thereof on a mounting table provided in the processing container that is evacuated; and

The metal target is ionized by plasma formed by converting the inert gas into plasma in the processing container to generate metal particles containing metal ions, and the metal particles are placed on a mounting table in the processing container. And a step of drawing the object to be processed by bias power to form a thin film containing the metal on the surface of the object to be processed. The step of forming a thin film on the surface of the object to be processed includes

 A step of forming an auxiliary seed film for forming a plating auxiliary seed film containing a second metal on the surface of the object to be processed, including the surface of the object to be processed, by further cutting the cut-in depression at the bottom of the concave part. A storage medium characterized by that.