JP2010016136A - Thin film forming method and apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thin film forming method for effectively depositing a thin film having a function, for example, of a barrier layer to the bottom part of a recessed part, while controlling deposition of such thin film to a sidewall of the recessed part even if a diameter of the recessed part of the material to be processed is small. <P>SOLUTION: The film forming method, to form a thin film to the front surface of the material W to be processed on which a recessed part 6 is formed on the front surface, includes a titanium film forming step of forming a titanium film 100 to the front surface of the material to be processed including the internal surface of the recessed part using the titanium compound gas and the reducing gas, a nitriding step of forming a first titanium nitride film 104 with nitriding of the entire part of the titanium film using the nitriding gas, and a titanium nitride film depositing step of forming a second titanium nitride film 106 by depositing this film on the front surface of the material to be processed including the internal surface of the recessed part. Therefore, even when the diameter of the recessed part of the material to be processed is small, the thin film can be deposited effectively to the bottom part of the recessed part while deposition of the thin film to the sidewall of the recessed part is controlled. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a thin film forming method and a film forming apparatus for forming a thin film such as a barrier layer on the surface of a semiconductor wafer such as a silicon substrate.

  In general, in order to form a semiconductor device such as an IC, various processes such as a film formation process, an oxidation diffusion process, an etching process, and a modification process are repeatedly performed on a semiconductor wafer made of a silicon substrate or the like.

  A recent semiconductor device that has been highly integrated and highly densified has a so-called multilayer wiring structure composed of a plurality of wiring layers. In such a semiconductor device, in order to obtain good electrical characteristics, the contact hole for electrically connecting the silicon substrate and the wiring layer, or the upper wiring layer and the lower wiring layer are electrically connected. In order to achieve this, a technique for embedding metal in via holes has become more important. Particularly in recent years, tungsten has a tendency to be buried mainly by CVD (Chemical Vapor Deposition) in recesses such as contact holes and via holes due to higher embedding performance.

  FIG. 14 shows a general contact structure in a semiconductor wafer such as a silicon substrate embedded with tungsten. As shown in FIG. 14A, in order to obtain such a contact structure, for example, first, in the insulating film 2 on the semiconductor wafer W made of a silicon substrate or the like, a region corresponding to the conductive layer 4 containing silicon. Is etched to form a recess 6 such as a hole. The conductive layer 4 serves as an impurity diffusion layer that constitutes a lower wiring layer, a source and a drain of a transistor, and the like.

  Then, tungsten is buried in the recess 6. In this case, in order to improve the adhesion of the tungsten film, the electrical characteristics of the recess 6, etc., the surface of the recess 6 is included prior to the formation of the tungsten film. A titanium film 8 and a titanium nitride film 10 are sequentially formed on the entire wafer surface, and then a tungsten film 12 is formed thereon.

Conventionally, each of these film forming steps has been performed by a plurality of processing apparatuses. For example, first, in the first processing apparatus, the inside of the recess 6 is included by a plasma CVD method or the like using, for example, titanium tetrachloride (hereinafter also referred to as “TiCl ₄ ”) gas and hydrogen (hereinafter also referred to as “H ₂ ”) gas. Thus, the titanium film 8 is formed on the entire surface of the wafer W. At this time, on the surface of the conductive layer 4, silicon and titanium in the conductive layer 4 react to form a titanium silicide (TiSi _x ) layer 14.

Subsequently, the wafer W is transferred to the second processing apparatus, and the titanium nitride film 10 is formed by thermal CVD using, for example, titanium tetrachloride gas and ammonia (hereinafter also referred to as “NH ₃ ”) gas. . Then, this wafer W is transferred to a third processing apparatus, and for example, monosilane (SiH ₄ ) gas and hydrogen gas or one of them and tungsten hexafluoride (hereinafter also referred to as “WF ₆ ”) gas. The tungsten film 12 is formed using thermal CVD. As a result, tungsten is embedded in the recess 6.

  Since the tungsten hexafluoride gas used when forming such a tungsten film 12 contains fluorine (F) having high reactivity with a metal such as titanium, the titanium nitride film 10 is not formed. When the tungsten film 12 is formed directly on the film 8, the titanium film 8 is etched by fluorine. That is, the titanium nitride film 10 formed between the tungsten film 12 and the titanium film 8 functions as a barrier layer that prevents the diffusion of fluorine in the process of forming the tungsten film 12. Is kept in a good state without being invaded by fluorine.

  For these reasons, a titanium nitride film 10 has been conventionally formed on the titanium film 8. In this case, after the titanium film 8 is formed and before the titanium nitride film 10 is formed, the surface of the titanium film 8 is nitrided by, for example, plasma. As a result, a thin titanium nitride layer 16 is formed on the surface (upper layer portion) of the titanium film 8, so that the titanium film 8 is used by the titanium tetrachloride gas used in the subsequent film-forming process of the titanium nitride film 10 by, for example, thermal CVD. It is possible to prevent the surface of the substrate from being etched.

JP 2003-142425 A JP 2002-542399 A

However, conventionally, since only the surface of the titanium film 8 is nitrided, the titanium layer 18 remains on the titanium film 8. Therefore, if the titanium nitride layer 16 and the titanium nitride film 10 of the titanium film 8 do not have sufficient thickness, a part of fluorine passes through the titanium nitride layer 10 and the titanium nitride film 16 and the titanium layer 18 of the titanium film 8. And fragile titanium fluoride (TiF _x ) may be generated. When titanium fluoride is generated in this way, the adhesion between the titanium nitride film 10 and the tungsten film 12 is deteriorated and may be peeled off from the surface of the wafer W.

  Further, recently, the demand for miniaturization becomes more severe, and when the demand for the diameter of the concave portion 6, for example, the hole diameter is 60 nm or less, titanium nitride is formed by thermal CVD in the second processing apparatus. When the film 10 is formed, this thermal CVD method has a relatively low directivity during film formation. Therefore, as shown in FIG. 14B, not only the bottom in the recess 6 but also the side wall of the recess 6 is formed. As a result, the titanium nitride film 10 is isotropically deposited also in a portion corresponding to 6A, and as a result, the inside of the recess 6 becomes too narrow, and the film forming gas is increased in the subsequent tungsten film forming process. There was also a problem in that the plug resistance could not be sufficiently penetrated into the recess 6 and the amount of embedding of the recess 6 was reduced to increase the plug resistance.

  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 allow the thin film functioning as a barrier layer to be deposited efficiently on the bottom of the recess while suppressing the deposition of a thin film functioning as a barrier layer on the sidewall of the recess, for example. An object of the present invention is to provide a thin film forming method and film forming apparatus.

  According to a first aspect of the present invention, there is provided a film forming method for forming a thin film on a surface of a target object having a recess formed on the surface thereof, and a titanium compound gas and a reducing gas are formed on the surface of the target object including the inner surface of the recess. A titanium film forming step of forming a titanium film using a nitriding gas, a nitriding step of forming a first titanium nitride film by nitriding all of the titanium film using a nitriding gas, and the object to be processed including an inner surface of the recess And a titanium nitride film deposition step of depositing a second titanium nitride film on the surface of the film.

  Thus, in the film-forming method which forms a thin film on the surface of the to-be-processed object in which the recessed part is formed in the surface, a titanium film is used for the surface of the to-be-processed object including the inner surface of a recessed part using titanium compound gas and reducing gas Forming a first titanium nitride film by nitriding all of the titanium film using a nitriding gas, and forming a second titanium nitride on the surface of the object to be processed including the inner surface of the recess. A thin film functioning as a barrier layer, for example, to the side wall of the recess, even if the recess diameter of the object to be processed is small. It is possible to efficiently deposit on the bottom of the recess while suppressing the deposition.

The invention of claim 2 is characterized in that, in the invention of claim 1, the titanium nitride film deposition step is performed after the titanium film forming step and the nitriding step are alternately repeated a plurality of times.
A third aspect of the invention is characterized in that, in the first or second aspect of the invention, the titanium film forming step and the nitriding step are each performed in the presence of plasma.

According to a fourth aspect of the present invention, in the invention according to any one of the first to third aspects, a conductive layer containing silicon is exposed at a bottom of the concave portion, and the conductive layer is formed in the titanium film forming step. The object to be processed is set to a first temperature so that a silicon silicide layer is formed by a reaction between the silicon and titanium of the titanium film.
The invention of claim 5 is the invention of claim 4, wherein the first temperature is in the range of 400 to 650 ° C.

A sixth aspect of the invention is characterized in that, in the invention according to any one of the first to fifth aspects, the thickness of the titanium film formed in the titanium film forming step is 15 nm or less.
According to a seventh aspect of the present invention, in the invention according to any one of the first to sixth aspects, in the titanium nitride film deposition step, plasma is generated using a titanium compound gas, a reducing gas, a nitrogen gas, and a plasma stabilizing gas. The second titanium nitride film is deposited in the presence of.

  Thus, in the titanium nitride film deposition step, the second titanium nitride film is deposited in the presence of plasma using the titanium compound gas, the reducing gas, the nitrogen gas, and the plasma stabilizing gas. The film formation on the bottom of the concave portion can be promoted while the film formation on the side wall of the recess is controlled.

The invention of claim 8 is the invention of claim 7, wherein the flow rate Y ₁ of the nitrogen gas, the relationship between the high-frequency power X ₁ to be introduced in order to generate the plasma, depends on the flow rate of the titanium compound gas wherein the flow rate Y ₁ and said high-frequency power X ₁ is set so as to satisfy a predetermined relational expression and determined to.
The invention according to claim 9 is the invention according to claim 8, wherein the predetermined relational expression is the following formula 1 when the flow rate of the titanium compound gas is 20 sccm or less.
Y ₁ ≦ 7.62 · 10 ⁻⁴ · X ₁ ² −2.37 · X ₁ + 2.02 · 10 ³ (Expression 1)
The invention of claim 10 is the invention of claim 9, wherein the lower limit of the flow rate Y ₁ of said nitrogen gas characterized in that it is a 1 sccm.

The invention according to claim 11 is the invention according to claim 7, wherein the flow rate Y _{2 of the} nitrogen gas per unit area of the object to be processed and the unit area of the object to be processed to be supplied to form the plasma. the relationship between the high-frequency power X ₂ are, the said flow rate Y ₂ so as to satisfy a titanium compound predetermined relational expression in which the determined depending on the flow rate per unit area of the object gas and the high-frequency power X ₂ is It is characterized by being set.

The invention of claim 12 is the invention of claim 11, wherein the predetermined relational expression is that the flow rate of the titanium compound gas per unit area of the object to be processed is 2.831 · 10 ⁻² sccm / cm ² or less. At the time of, it is characterized by the following formula 2.
Y ₂ ≦ 5.39 · 10 ⁻¹ · X ₂ ² −2.37 · X ₂ +2.86 (Equation 2)
According to a thirteenth aspect of the present invention, in the invention of the twelfth aspect, the lower limit of the flow rate Y ₂ of the nitrogen gas per unit area of the object to be processed is 1.415 · 10 ⁻³ sccm / cm ^2. Features.

The invention according to claim 14 is the invention according to claim 7, wherein the relationship between the partial pressure Y _{3 of the} nitrogen gas and the high frequency power X ₃ per unit area of the object to be processed to generate plasma is as follows: The partial pressure Y ₃ and the high-frequency power X ₃ are set so as to satisfy a predetermined relational expression determined depending on the partial pressure of the titanium compound gas.

According to a fifteenth aspect of the present invention, in the invention according to the fourteenth aspect, when the partial pressure of the titanium compound gas is 2.37 Pa or less, the predetermined relational expression is the following formula (3).
Y ₃ ≦ 28.9 · 10 ¹ · X ₃ ² −140 · X ₃ + 1.87 · 10 ² (Expression 3)
The invention of claim 16 is the invention of claim 15 wherein the partial lower limit of the pressure Y ₃ of the nitrogen gas, characterized in that it is a 0.12 Pa.

The invention of claim 17 is the invention according to any one of claims 1 to 16, wherein the titanium film forming step, the nitriding step, and the titanium nitride film depositing step are performed in the same film forming apparatus. It is characterized by that.
As described above, since the titanium film forming process, the nitriding process, and the titanium nitride film depositing process are performed in the same film forming apparatus, the number of necessary film forming apparatuses can be reduced accordingly. It can contribute to the reduction of equipment cost.

The invention of claim 18 is characterized in that, in the invention of any one of claims 1 to 17, the titanium compound gas is titanium tetrachloride gas.
The invention of claim 19 is the invention according to any one of claims 1 to 18, wherein the reducing gas is H ₂ gas.
The invention according to claim 20 is the tungsten film according to any one of claims 1 to 19, wherein after the titanium film deposition step, a tungsten film is formed on a surface of the object to be processed to fill the recess. A forming step is performed.

  The invention according to claim 21 is a film forming apparatus for forming a thin film on a surface of an object to be processed in which a recess is formed on the surface, and a processing container for housing the object to be processed, and the object to be processed in the processing container And a shower head portion that is used as an upper electrode while introducing gas into the processing vessel, and is connected to the shower head portion to supply necessary gas. A gas supply means, a heating means for heating the object to be processed, an exhaust system for evacuating the inside of the processing container, a high-frequency power supply means for supplying high-frequency power to form plasma in the processing container, A film forming apparatus comprising: a control unit that controls the entire apparatus in order to carry out the thin film forming method according to claim 1.

  According to a twenty-second aspect of the present invention, there is provided a processing container that accommodates an object to be processed, a mounting table on which the object to be processed is mounted in the processing container and provided with a lower electrode, and a gas is introduced into the processing container. In addition, a shower head unit also used as an upper electrode, a gas supply unit connected to the shower head unit for supplying necessary gas, a heating unit for heating the object to be processed, and the inside of the processing container are evacuated. A recess is formed on the surface using a film forming apparatus including an exhaust system, a high-frequency power supply means for supplying high-frequency power to form plasma in the processing container, and a control unit for controlling the entire apparatus. A computer-readable program for controlling the entire apparatus so as to implement the thin film forming method according to any one of claims 1 to 20 when forming a thin film on a surface of an object to be processed A storage medium and to store.

According to the method and apparatus for forming a thin film according to the present invention, the following excellent effects can be achieved.
In a film forming method for forming a thin film on the surface of an object to be processed having recesses formed on the surface, titanium for forming a titanium film on the surface of the object to be processed including the inner surface of the recess using a titanium compound gas and a reducing gas A film forming step, a nitriding step of nitriding all of the titanium film using a nitriding gas to form a first titanium nitride film, and depositing a second titanium nitride film on the surface of the object to be processed including the inner surface of the recess. The titanium nitride film deposition step is formed, so that even if the diameter of the concave portion of the object to be processed is small, for example, a thin film functioning as a barrier layer is suppressed from being deposited on the side wall of the concave portion. It can be deposited efficiently on the bottom. For this reason, when a plug (or contact) is formed by filling the recess with a wiring metal in a later step, a thick plug can be formed, and a device having a low plug (contact) resistance can be manufactured.

In particular, according to the seventh aspect of the invention, in the titanium nitride film deposition step, the second titanium nitride film is deposited in the presence of plasma using a titanium compound gas, a reducing gas, a nitrogen gas, and a plasma stabilizing gas. Since it did in this way, the film-forming to the bottom part of a recessed part can be accelerated | stimulated especially controlling the film-forming to the side wall of a recessed part.
In particular, according to the invention of claim 17, the titanium film forming step, the nitriding step, and the titanium nitride film depositing step are performed in the same film forming apparatus, and accordingly, the necessary film forming apparatus. The number of units can be reduced, which can contribute to a reduction in equipment costs.

A preferred embodiment of a thin film forming method and film forming apparatus according to the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 1 is a sectional view showing an example of a film forming apparatus according to the present invention, FIG. 2 is a flowchart showing an example of a film forming method of the present invention, and FIG. 3 is a thin film formed on the surface of an object to be processed by the method of the present invention. FIG. 4 is a timing chart showing the supply state of each gas during the formation of the first titanium nitride film, and FIG. 5 is a graph showing the RF power (when the second titanium nitride film is deposited). FIG. 6 is an explanatory diagram for explaining the relationship between the N ₂ gas flow rate and the TiCl ₄ gas flow rate when the high-frequency power) is constant, and FIG. 6 shows the N ₂ gas flow rate, RF power, and TiCl when the second titanium nitride film is formed. It is explanatory drawing for demonstrating the influence which ₄ gas flow rates have on the fluctuation | variation of the peak of a film thickness.

FIG. 7 is an explanatory diagram for explaining the optimum range of the N ₂ gas flow rate with respect to the high-frequency power when depositing the second titanium nitride film, and FIG. 8 is an object to be processed when depositing the second titanium nitride film. FIG. 9 is an explanatory diagram for explaining the optimum range of the N ₂ gas flow rate per unit area of the object to be processed with respect to the high-frequency power per unit area, and FIG. 9 shows the object to be processed when the second titanium nitride film is deposited. FIG. 10 is an explanatory diagram for explaining the optimum range of the partial pressure of N ₂ gas with respect to the high frequency power per unit area. FIG. 10 shows the N ₂ gas flow rate and film thickness when the RF power is 800 W and the TiCl ₄ gas flow rate is 12 sccm. FIG. 11 is an electron micrograph showing the deposition state of the thin film in the vicinity of the bottom surface of the recess, and FIG. 12 is a case where the N ₂ gas flow rate when depositing the second titanium nitride film is large and small. Form of reaction that occurs in some cases Schematically shown FIG, 13 is a timing chart showing the timing of supply of the gas when forming the tungsten film. Here, a case where the titanium film forming process, the nitriding process, and the titanium nitride film forming process are performed in the same film forming apparatus will be described.

  As shown in FIG. 1, the film forming apparatus 22 has a processing container 24 made of aluminum or aluminum alloy, the inside of which is substantially cylindrical. In this processing container 24, a susceptor 26 as a mounting table for horizontally supporting a semiconductor wafer W as an object to be processed is supported in a state of being supported by a cylindrical support member 28 provided at the center lower part thereof. Has been. The susceptor 26 is made of a ceramic such as aluminum nitride (AlN), and a guide ring 30 for guiding the wafer W is provided on the outer edge thereof.

  A heater 32 is embedded in the susceptor 26 as a heating means for heating the wafer W. The heater 32 is supplied with power from a heater power supply 34 to heat the wafer W to a predetermined temperature. In the susceptor 26, a lower electrode 36 is embedded on the heater 32, and the lower electrode 36 is grounded (not shown), for example.

  A shower head 40 is provided on the top wall 24 </ b> A of the processing container 24 via an insulating member 38. The shower head portion 40 is roughly composed of a base member 42 as an upper portion and a shower plate 44 as a lower portion.

  A heater 46 is embedded in the base member 42, and the heater 46 can be heated to a predetermined temperature by being supplied with power from a heater power supply 48.

  A large number of discharge holes 50 for discharging gas into the processing container 24 are formed in the shower plate 44. Each discharge hole 50 communicates with a gas diffusion space 52 formed between the base member 42 and the shower plate 44. A gas introduction port 54 for supplying a processing gas to the gas diffusion space 52 is provided at the center of the base member 42. The gas introduction port 54 is connected to a mixed gas supply line 58 of a gas supply means 56 described later.

  The gas supply means 56 includes, for example, a titanium tetrachloride gas supply source 60 that supplies titanium tetrachloride gas as a titanium compound gas, and an argon gas supply source 62 that supplies, for example, argon (hereinafter also referred to as “Ar”) gas as a plasma stabilizing gas. For example, a hydrogen gas supply source 64 for supplying hydrogen gas as a reducing gas, an ammonia gas supply source 66 for supplying ammonia gas as a nitrogen compound gas, and a nitrogen gas supply source 68 for supplying nitrogen gas are provided.

  The titanium tetrachloride gas supply line 60L is connected to the titanium tetrachloride gas supply source 60, the argon gas supply line 62L is connected to the argon gas supply source 62, and the hydrogen gas supply source 64 is supplied with hydrogen. A gas supply line 64L is connected, an ammonia gas supply line 66L is connected to the ammonia gas supply source 66, and a nitrogen gas supply line 68L is connected to the nitrogen gas supply source 68. The gas supply lines 60L to 68L are respectively provided with mass flow controllers (MFC) 60C to 68C and two valves 60V to 68V across the mass flow controllers 60C to 68C.

  And the front-end | tip of each said lines 60L-68L is connected to the gas mixing part 70. FIG. The gas mixing unit 70 has a function of mixing the processing gas and supplying the mixed gas to the shower head unit 40. The gas inflow side is connected to the gas inflow side via the gas supply lines 60L to 68L as described above. Each gas supply source 60-68 is connected, and the shower head part 40 is connected to the gas outflow side via the mixed gas supply line 58.

  At the time of the process, one kind of gas selected from titanium tetrachloride gas, argon gas, hydrogen gas, ammonia gas and nitrogen gas or a mixed gas of a plurality of gases is introduced into the gas introduction port 54 of the shower head 40 and gas diffusion. It is introduced into the processing container 24 from the plurality of ejection holes 50 via the space 52.

  As described above, the shower head unit 40 according to the present embodiment is configured as a so-called premix type in which each gas is mixed in advance and supplied into the processing container 24. However, each gas is independently supplied into the processing container 24. You may make it comprise with what is called a postmix type supplied to.

  The shower head unit 40 is connected to high frequency power supply means 72 for supplying high frequency power for generating plasma. The high-frequency power supply means 72 has a power supply line 74 connected to the shower head unit 40, and a matching unit 76 and a high-frequency power supply 78 are sequentially interposed in the power supply line 74. By supplying high frequency power of, for example, 450 kHz from the high frequency power supply 78 to the shower head unit 40, a high frequency electric field is generated between the shower head unit 40 also serving as the upper electrode and the lower electrode 36, and is generated in the processing container 24. The supplied gas can be converted into plasma.

  In addition, a circular hole is formed in the central portion of the bottom wall 24B of the processing container 24, and an exhaust chamber 80 that protrudes downward is provided on the bottom wall 24B so as to cover the hole. An exhaust pipe 82 is connected to the side surface of the exhaust chamber 80, and an exhaust system 84 is connected to the exhaust pipe 82. By operating the exhaust system 84, the inside of the processing container 24 can be depressurized to a predetermined degree of vacuum. The exhaust system 84 has a pressure control valve and a vacuum pump (not shown), and performs vacuum exhaust as described above.

  The susceptor 26 is provided with three wafer support pins 84 (only two are shown) for supporting the wafer W to be moved up and down so that the wafer support pins 84 can be raised and lowered with respect to the surface of the susceptor 26. It is fixed to the plate 86. The wafer support pins 84 are moved up and down via a support plate 86 by a drive mechanism 88 such as an air cylinder.

  The side wall 24C of the processing container 24 is provided with a loading / unloading port 90 for loading / unloading the wafer W to / from a common transfer chamber (not shown) and a gate valve 92 for opening / closing the loading / unloading port 90. Yes.

  Control of the overall operation of the film forming apparatus 22 having such a configuration, for example, control of starting and stopping the supply of various gases, flow control of each gas, temperature control of the wafer W, pressure control in the processing container 24, etc. For example, this is performed by the control unit 94 formed of a computer. A computer-readable program necessary for this control is described in the storage medium 96. The storage medium 96 includes a flexible disk, a CD (Compact Disc), a CD-ROM, a hard disk, a flash memory, a DVD, or the like.

Next, the film forming method of the present invention performed using the film forming apparatus 22 configured as described above will be described.
First, an unprocessed semiconductor wafer W is transferred from a common transfer chamber of a processing system (not shown), for example, a cluster tool into the processing container 24 via a gate valve 92 and a loading / unloading port 90 opened using a transfer arm. It is carried in. The wafer W is transferred to the wafer support pin 84 side by raising the wafer support pin 84 provided on the susceptor 26, and the wafer support pin 84 is lowered after the transfer arm is moved backward. The wafer W is placed on the susceptor 26.

  The inside of the processing container 24 is evacuated in advance, and the processing container 24 is sealed by closing the gate valve 92. As described with reference to FIG. 14, the insulating layer 2 and the recess 6 are formed in advance on the surface of the semiconductor wafer W. Impurity diffusion such as a lower wiring layer and a source and drain of a transistor is formed at the bottom of the recess 6. The conductive layer 4 serving as a layer is exposed.

  Then, the heater 32 disposed on the susceptor 26 is driven to raise the temperature of the wafer W on the susceptor 26 to a predetermined temperature and maintain that temperature. At the same time, necessary gases are flowed from the gas sources 60 to 68 of the gas supply means 56 while controlling the flow rate, and these gases are mixed in the gas mixing unit 70 and then mixed through the mixed gas supply line 58. The gas is introduced into the gas diffusion chamber 52 of the shower head unit 40. The mixed gas introduced into the gas diffusion chamber 52 diffuses in the gas diffusion chamber 52 in the plane direction and is supplied to the processing space S below the numerous discharge holes 50.

  Simultaneously with this gas supply, the high-frequency power supply means 72 is driven to apply high-frequency power between the upper electrode formed of the shower head unit 40 and the lower electrode 36 provided on the susceptor 26, thereby allowing the processing space S to be applied. A plasma mainly composed of Ar gas is generated, and various processes described below are executed.

  First, in the film forming method of the present invention performed using the film forming apparatus 22, a titanium film is formed using a titanium compound gas and a reducing gas on the surface of a semiconductor wafer which is an object to be processed including the inner surface of the recess. A titanium film forming step, a nitriding step of nitriding all of the titanium film using a nitriding gas to form a first titanium nitride film, and a second titanium nitride on the surface of the object to be processed including the inner surface of the recess. A titanium nitride film deposition step for depositing and forming a film.

This will be described with reference to FIGS. 2 and 3 as well. First, as shown in FIG. 3A, a recess 6 is formed in the insulating layer 2 such as an interlayer insulating layer made of SiO ₂ or the like on the surface of the semiconductor wafer W. It is formed in advance in the previous step, and the conductive layer 4 containing Si is exposed at the bottom of the recess 6. Then, as shown in step S <b> 1, a titanium film forming process is performed in which a titanium film 100 is formed on the surface of the wafer W using a titanium compound gas and a reducing gas. For example, TiCl ₄ gas is used as the titanium compound gas, and H ₂ gas is used as the reducing gas.

  This titanium film forming step is performed, for example, by an SFD (Sequential Flow Deposition) method as described later. At this time, titanium is silicided at the boundary between the titanium film 100 and the conductive layer 4 to form a titanium silicide layer 102.

Next, as shown in step S <b> 2, a nitriding process is performed in which the titanium film 100 is entirely nitrided using a nitriding gas to form a first titanium nitride film 104. For example, NH ₃ gas is used as the nitriding gas.

  Then, as shown in step S3, the titanium film forming process in step S1 and the nitriding process in step S2 are alternately repeated a predetermined number of times. In this case, the number of repetitions may be “1” or a plurality of times, but the number of repetitions may be zero, both steps S1 and S2 may be performed only once (one pass), and the process may proceed to the next step. .

  Next, as shown in step S <b> 4, a second titanium nitride film 106 is deposited on the surface of the wafer W including the inner surface of the recess 6. Here, as will be described later, the second titanium nitride film 106 is formed in the presence of plasma using a titanium compound gas, a reducing gas, a nitriding gas, and a plasma stabilizing gas. As a result, a barrier layer 108 composed of the first and second titanium nitride films 104 and 106 is formed.

  When the barrier layer 108 is formed in this way, a tungsten film forming step for forming the tungsten film 110 on the surface of the wafer W and filling the recesses 6 is performed as shown in step S5.

Next, the above steps will be described in detail.
<Titanium film forming process and nitriding process>
First, a titanium film forming process and a nitriding process will be described. Here, as shown in FIG. 4, the titanium film forming step and the nitriding step are alternately repeated a plurality of times. In other words, in order to form the first titanium nitride film 104, a plasma SFD (Sequential Flow) for forming the first titanium nitride film 104 by repeatedly forming the thin titanium film 100 and nitriding the thin titanium film 100 several times. Deposition) method can be used.

  In the formation process of the first titanium nitride film 104 by the plasma SFD method, for example, a titanium film is formed by generating plasma while supplying titanium compound gas, argon gas, and hydrogen gas at the same time to form a thin titanium film 100. The process and the nitriding step of generating plasma while supplying ammonia gas, argon gas and hydrogen gas at the same time and nitriding all of the thin titanium film 100 are defined as one cycle, and this is the first titanium nitride film. Repeat several times until 104 reaches a predetermined film thickness.

  Specifically, the process temperature (wafer temperature) is set within the range of 400 to 650 ° C. (first temperature in the claims), more preferably within the range of 400 to 560 ° C., for example, 550 ° C., and the process pressure is set. For example, it is set within the range of 500 to 800 Pa, for example, 667 Pa. Then, during a period P11 (gas stabilization), titanium tetrachloride gas (titanium compound gas), hydrogen gas (reducing gas), and argon gas are supplied. At this time, the flow rate of titanium tetrachloride gas is adjusted to, for example, 12 sccm, the flow rate of hydrogen gas is adjusted to, for example, 4000 sccm, and the flow rate of argon gas is adjusted to, for example, 1600 sccm. The main purpose of this period P11 is to stabilize the processing gas in the processing container 24 prior to the next period P12. The period P11 is set to 0 to 5 seconds, for example.

  Next, in period P12, a high frequency power of, for example, 800 W is applied to the shower head portion (upper electrode) 40 while titanium tetrachloride gas, hydrogen gas, and argon gas are continuously supplied from the period P11 at the same flow rate. And plasma is formed. Thereby, the titanium film 100 is deposited. Titanium in the titanium film 100 reacts with silicon at the boundary with the lower conductive layer 4 to be silicided. The period P12 is set to 4 seconds, for example.

  Subsequently, the supply of titanium tetrachloride gas is stopped from the state of period P12, and the process proceeds to period P13. In this period P13, hydrogen gas and argon gas are supplied at the same flow rate as in period P12, and these are turned into plasma. As a result, the titanium film 100 deposited in the previous period P12 is plasma annealed. The period P13 is set to 5 seconds, for example.

  Next, the plasma is extinguished from the state of the period P13 and the process proceeds to the period P14. This period P14 is a waiting time until the next period P15 is started, and this time is, for example, 1 second. By executing the processes in the above periods P11 to P14, an extremely thin titanium film 100 is formed. Note that the argon gas may not be introduced in the periods P11 to P14.

  Next, in the period P15, the entire titanium film 100 formed by the treatment in the periods P11 to P14 is nitrided to form the very thin first titanium nitride film 104. Here, hydrogen gas, argon gas, and ammonia gas (nitrogen compound gas) are supplied, and a high frequency power of, for example, 800 W is applied to the shower head (upper electrode) 40 to form plasma again. At this time, the flow rate of hydrogen gas is adjusted to 2000 sccm, the flow rate of argon gas is adjusted to 1600 sccm, for example, and the flow rate of ammonia gas is adjusted to 1500 sccm, for example. The period P15 is set to 5 seconds, for example.

  In the next period P16, the plasma is turned off and the supply of ammonia gas is stopped. The hydrogen gas and the argon gas are adjusted to the same flow rate as in the period P15, and the ammonia gas remaining in the processing container 24 is purged with these gases. This prevents the titanium tetrachloride gas supplied into the processing container 24 from being mixed with the residual ammonia gas in the period P11 of the next cycle, and forms a higher quality first titanium nitride film. Can do. The period P16 is set to 2 seconds, for example.

  Each process in the above periods P11 to P16 is set as one cycle, and the same cycle is repeated until the first titanium nitride film 104 reaches a predetermined film thickness of 1 to 15 nm, for example, 10 nm. In this way, as shown in FIG. 3C, the first titanium nitride 104 having a predetermined thickness is formed. Here, the plasma SFD method is used for film formation, but instead of this, a plasma CVD method as disclosed in Japanese Patent Application Laid-Open No. 2004-232080 is used, that is, P12 (titanium in FIG. 4). A film consisting of (film formation) and P13 (plasma annealing) is repeated once or a plurality of times to form a titanium film having a thickness of, for example, 10 nm, and thereafter all of this titanium film is formed by P15 (nitriding treatment) in FIG. A method of nitriding with plasma may be employed.

<Titanium nitride film deposition process>
Next, as shown in FIG. 3D, a second titanium nitride film 106 is formed. The reason why the second titanium nitride film 106 is formed is that the film thickness of the first titanium nitride film 104 alone is not sufficient in barrier properties against fluorine gas components caused by tungsten hexafluoride used in a subsequent process. In addition, in order to form the first titanium nitride film with a sufficient barrier property by the plasma SFD method, the deposition rate of the plasma SFD method is very low, and thus the throughput is greatly reduced. For reasons.

  The important point in the second titanium nitride film deposition step is to suppress the film formation on the side surface of the recess 6 and to the bottom surface of the recess 6 in order to secure a sufficient amount of tungsten embedded in the recess 6 in a later step. Whether to perform the film formation. In other words, in FIG. 3D, regarding the second titanium nitride film 106 in the recess 6, the thickness T1 of the side wall in the recess 6 is made as thin as possible, and the thickness T2 of the bottom is made as thick as possible. Necessary. In particular, when the hole diameter of the recess 6 becomes 60 nm or less due to a further miniaturization tendency, control of film formation on the surface in the recess 6 becomes important.

In the present invention, the above object is achieved by optimizing the flow rate of N ₂ gas in the titanium nitride film deposition step. Specifically, here, a titanium compound gas, a reducing gas, a nitrogen gas, and a plasma stabilizing gas are used. For example, a TiCl ₄ gas is used as the titanium compound gas, and an H ₂ gas is used as the reducing gas. For example, Ar gas is used as the plasma stabilizing gas. Then, the above four types of gases are simultaneously supplied into the processing vessel 24, and high frequency power is applied to the shower head unit 40 to generate plasma, thereby generating active species of each gas and generating recesses 6 in the wafer W. A second titanium nitride film is formed on the entire wafer surface including the inner surface by plasma CVD.

In this case, film formation on the sidewall of the recess 6 is suppressed by controlling the flow rate of each gas, particularly the flow rate of N ₂ gas, and also controlling the high-frequency power input for plasma formation. The film formation on the bottom of the recess 6 is promoted. In this case, of course, a titanium nitride film is deposited also on the upper surface of the insulating layer 2 of the wafer W.

The present inventors have found that the film formation state of titanium nitride on the surface in the recess 6 largely depends on the gas flow rates of titanium tetrachloride and N ₂ and the high-frequency power to be supplied, and optimize these. I am doing so.

First, the relationship between the N ₂ gas flow rate and the TiCl ₄ gas flow rate when the high frequency power (RF power) is made constant when the second titanium nitride film is deposited will be described with reference to FIG. In FIG. 5, the horizontal axis represents the N ₂ gas flow rate, and the vertical axis represents the film thickness. The TiCl ₄ gas is changed from 8 sccm to 20 sccm. The RF power at this time is constant at 800 W (watts). Further, here, a processing vessel corresponding to a wafer diameter of 300 mm is used, and its volume is 706.5 cm ³ , and this point is the same in each graph described hereinafter.

As is apparent from this graph, the film thickness has a peak value with respect to the N ₂ gas flow rate, and the peak value moves in the left-right direction depending on the TiCl ₄ gas flow rate. For example, the peak K1 when the TiCl ₄ gas flow rate is 8 sccm is when the N ₂ gas flow rate is about 100 sccm, and the peak K2 when the TiCl ₄ gas flow rate is 12 sccm is when the N ₂ gas flow rate is about 200 sccm. ₄ gas peak flow rate when the 16 sccm K3 is the time when _{N 2} gas flow rate of about 380Sccm, peak K4 when the TiCl ₄ gas flow rate 20sccm is when _{N 2} gas flow rate of about 400 sccm.

Here, when the film thickness state of the surface in the concave portion 6 of the wafer was confirmed by an electron micrograph, the deposition state of each left region from the peaks K1 to K4 in each TiCl ₄ gas flow rate is the right region. It was very good compared with. That is, it has been found that in the region on the left side of each peak K1 to K4, deposition on the bottom surface can be promoted while deposition on the side surface in the recess 6 is suppressed.

Next, the influence of the N ₂ gas flow rate, the RF power, and the TiCl ₄ gas flow rate on the fluctuation of the film thickness peak when the second titanium nitride film is deposited will be described with reference to FIG. In FIG. 6, the horizontal axis represents the N ₂ gas flow rate, the vertical axis represents the film thickness, and the RF power is varied from 400 W to 1200 W. Regarding the flow rate of TiCl ₄ gas, FIG. 6A shows the case of 20 sccm, FIG. 6B shows the case of 12 sccm, and FIG. 6C shows the case of 6 sccm.

  Here, the peaks of the curves of the RF powers 400 W, 800 W, and 1200 W in FIG. 6A are M1, M2, and M3, respectively, and the peaks of the curves of the RF powers 400 W, 800 W, and 1200 W in FIG. , N2, and N3, and the peaks of the curves of RF power 400W, 800W, and 1200W in FIG. 6C are O1, O2, and O3, respectively.

As is apparent from FIG. 6, when the flow rate of TiCl ₄ gas is constant, the peak of the film thickness shifts to the right side as the RF power decreases. Accordingly, when the flow rate of TiCl ₄ gas is constant, the peak of the film thickness shifts in a direction where the N ₂ gas flow rate increases as the RF power decreases, and the peak of the film thickness increases as the RF power increases. _{2 The} gas flow rate has shifted to a smaller direction. This point is common to the graphs of FIGS. 6 (A) to 6 (C). It can be seen that the peak of each graph shifts to the left side as the flow rate of TiCl ₄ gas decreases (see FIG. 6C).

Here, when the film thickness state of the surface in the recess 6 of the wafer was confirmed with an electron microscope, peaks M1 to M3 and N1 to N1 at each TiCl ₄ gas flow rate in each graph of FIGS. 6 (A) to 6 (C). The deposition state in the region on the left side of N3 and O1 to O3 was very good as compared with the region on the right side. This is the same as in the case of FIG. And since the graph of the curve formed by connecting each peak in the said FIG. 6 was calculated | required, the result is shown in FIG. FIG. 7 is an explanatory diagram for explaining an optimum range of the N ₂ gas flow rate with respect to the high-frequency power when the second titanium nitride film is deposited.

In FIG. 7, the horizontal axis represents high frequency power (RF power): X ₁ , and the vertical axis represents N ₂ gas flow rate: Y ₁ . As shown in FIG. 7, each peak M1~M3 in FIG 6, N1~N3, O1~O3 is plotted for each flow rate of the TiCl ₄ gas, tables in three curves the flow rate of TiCl ₄ gas is different Has been. And the area | region with the favorable deposition state of the left side from each peak in FIG. 6 becomes an area | region under each curve represented in FIG. That is, the flow rate Y ₁ of the nitrogen gas, the relationship between the high-frequency power X ₁ to be introduced to generate plasma, and the flow rate Y ₁ so as to satisfy a predetermined relational expression determined depending on the flow rate of the titanium compound gas the high frequency power X ₁ are set.

Here, the lower limit of the high frequency power is 200 W, and if the high frequency power becomes smaller than this, it becomes difficult to stably form and maintain the plasma. In addition, the lower limit of the flow rate of the TiCl ₄ gas is 1 sccm, and if this flow rate is less than 1 sccm, it is substantially difficult to form a titanium nitride film. In particular, when considering a substantial film forming rate, the flow rate of the TiCl ₄ gas is preferably set to 4 sccm or more. The flow rate of the N ₂ gas is much larger than that of the TiCl ₄ gas, but the lower limit is 1 sccm, which is the same as that of the TiCl ₄ gas in consideration of the composition of the deposited TiN film. Considering the film rate, it is preferable to set it to 4 sccm or more.

The relational expression between the nitrogen gas flow rate Y ₁ determined when the TiCl ₄ gas flow rate is 20 sccm and the high-frequency power X ₁ is as shown in the following equation ( ₁ ). a high frequency power X ₁ is set.

Y ₁ ≦ 7.62 · 10 ⁻⁴ · X ₁ ² −2.37 · X ₁ + 2.02 · 10 ³ (Expression 1)

Actually, the region below the curve represented by the above equation ₁ is the optimum range, and the high frequency power X ₁ and the N ₂ gas flow rate Y ₁ are set so as to fall within this region. And as evident from FIG. 7, the optimum range of the TiCl ₄ gas flow rate in the area indicated by the number 1 is determined when 12 sccm, and will be TiCl ₄ gas flow also includes the optimum range determined at the time of 6 sccm, the number 1 The region shown indicates the optimum range determined when the TiCl ₄ gas flow rate is 20 sccm or less.

Further, the flow rate _{Y 1} of nitrogen gas the TiCl ₄ gas flow rate is determined at the time of 12 sccm, a relational expression between the high-frequency power _{X 1} is as shown in the following numbers 1-2, the to meet this number 1-2 a flow _{Y 1} and the high-frequency power _{X 1} is set.

Y ₁ ≦ 3.13 · 10 ⁻⁴ · X ₁ ² −1.13 · X ₁ +10 ³ (Equation 1-2)

In practice, an area is optimal range under the curve represented by the equation 1-2, the a high frequency power X ₁ and N ₂ gas flow rate Y ₁ is set to fall within this region.

Further, the relational expression between the flow rate Y _{1 of} nitrogen gas determined when the TiCl ₄ gas flow rate is 6 sccm and the high-frequency power X ₁ is expressed by the following formula 1-3, and the above formula 1-3 is satisfied so as to satisfy the formula 1-3. a flow _{Y 1} and the high-frequency power _{X 1} is set.

Y ₁ ≦ 3.13 · 10 ⁻⁴ · X ₁ ² −8.75 · 10 ⁻¹ · X ₁ + 6 · 10 ² (Equation 1-3)

In practice, an area is optimal range under the curve represented by the equation 1-3, the a high frequency power X ₁ and N ₂ gas flow rate Y ₁ is set to fall within this region.

Is described as an example the three curves here, actually includes a number of curves as described above previously determined experimentally for each example the flow rate of TiCl ₄ gas, the TiCl ₄ gas flow rate during the process conditions Is determined, a curve (relational expression) corresponding to the TiCl ₄ gas flow rate is determined in advance as shown in FIG. 7, so that the high-frequency power X is adjusted so as to fit the range of the basin below the curve. ₁ and N ₂ gas flow rate Y ₁ are respectively determined. As a result, any set value of the TiCl ₄ gas can be handled.

For example, when the flow rate of TiCl ₄ gas is set to 20 sccm, the high-frequency power X ₁ and the N ₂ gas flow rate Y ₁ are respectively determined so as to correspond to the shaded area in FIG. Thus, by determining the high frequency power X ₁ and the N ₂ gas flow rate Y ₁ , the deposition state of the second titanium nitride film 106 can be improved. The process temperature at this time is, for example, in the range of about 400 to 650 ° C., more preferably in the range of about 450 to 550 ° C., and the process pressure is in the range of about 500 to 800 Pa, more preferably. Is in the range of about 500 to 700 Pa.

In the case shown in FIG. 7, the optimum range is determined based on the whole process conditions of the film forming apparatus (the flow rate of TiCl ₄ gas flowing as a whole), but the present invention is not limited to this, and the semiconductor that is the object to be processed It may be determined in terms of a value per unit area of the wafer W. FIG. 8 is an explanatory diagram for explaining the optimum range of the N ₂ gas flow rate per unit area of the object to be processed with respect to the high frequency power per unit area of the object to be processed when the second titanium nitride film is deposited. .

In FIG. 8, the horizontal axis represents the high-frequency power per unit area of the wafer, and the vertical axis represents the N ₂ gas flow rate per unit area of the wafer. That is, here, the relationship between the flow rate Y ₂ of nitrogen gas per unit area of the object to be processed and the high-frequency power X ₂ per unit area of the object to be processed to form plasma is expressed by the titanium compound. The flow rate Y ₂ and the high-frequency power X ₂ are set so as to satisfy a predetermined relational expression determined depending on the flow rate of the gas per unit area of the object to be processed.

First, the relational expression determined when the flow rate of TiCl ₄ gas per unit area of the wafer is 2.831 · 10 ⁻² sccm / cm ² (corresponding to 20 sccm) is as shown in the following formula 2.

Y ₂ ≦ 5.39 · 10 ⁻¹ · X ₂ ² −2.37 · X ₂ +2.86 (Equation 2)
As is clear from FIG. 8, the TiCl ₄ gas flow rate per unit area of the wafer is 1.699 · 10 ⁻² sccm / cm ² (corresponding to 12 sccm) and 0.849 · 10 in the region represented by Formula ^{2. −2} sccm / cm ² (corresponding to 6 sccm) is included, and the region represented by Equation ² has a TiCl ₄ gas flow rate of 2.831 · 10 ⁻² sccm / cm per unit area of the wafer. ^The optimum range determined when the value is ² or less is shown. Further, a relational expression determined when the flow rate of TiCl ₄ gas per unit area of the wafer is 1.699 · 10 ⁻² sccm / cm ² (corresponding to 12 sccm) is expressed by the following formula 2-2.

Y ₂ ≦ 2.21 · 10 ⁻¹ · X ₂ ² −1.13 · X ₂ +1.42 (Equation 2-2)
Further, a relational expression determined when the TiCl ₄ gas flow rate per unit area of the wafer is 0.849 · 10 ⁻² sccm / cm ² (corresponding to 6 sccm) is expressed by the following formula 2-3.

Y ₂ ≦ 2.21 · 10 ⁻¹ · X ₂ ² −8.76 · 10 ⁻¹ X ₂ +0.849 (Equation 2-3)
At this time, the lower limits of the N ₂ gas flow rate and the TiCl ₄ gas flow rate per unit area of the wafer are 1.415 · 10 ⁻³ sccm / cm ² (corresponding to 1 sccm), preferably 5.662 · 10 ⁻³ sccm, respectively. / Cm ² (corresponding to 4 sccm).

Further, although FIG. 8 shows a value converted into a value per unit area of the semiconductor wafer W, the present invention is not limited to this, and each gas may be determined by converting into a partial pressure. FIG. 9 is an explanatory diagram for explaining an optimum range of the partial pressure of N ₂ gas with respect to the high frequency power per unit area of the object to be processed when the second titanium nitride film is deposited.

In FIG. 9, the horizontal axis represents the high frequency power per unit area of the wafer, and the vertical axis represents the N ₂ gas partial pressure. The Ar gas flow rate is 1600 sccm, the H ₂ gas flow rate is 4000 sccm, and the process pressure is 667 Pa. That is, here, the relationship between the partial pressure Y _{3 of the} nitrogen gas and the high-frequency power X ₃ per unit area of the object to be processed to generate plasma depends on the partial pressure of the titanium compound gas. and the partial pressure Y ₃ so as to satisfy a predetermined relational expression determined Te and the high frequency power X ₃ is set.

First, the relational expression determined when the partial pressure of TiCl ₄ is 2.37 Pa (corresponding to 20 sccm) is as shown in the following formula 3.

Y ₃ ≦ 28.9 · X ₃ ² −140 · X ₃ +187 (Equation 3)

As is apparent from FIG. 9, the optimum range determined when the partial pressure of TiCl ₄ is 1.43 Pa (corresponding to 12 sccm) and 0.71 Pa (corresponding to 6 sccm) is included in the region represented by Equation 3. The region indicated by 3 shows the optimum range determined when the partial pressure of TiCl ₄ is 2.37 Pa or less.
Further, the relational expression determined when the partial pressure of TiCl ₄ is 1.43 Pa (corresponding to 12 sccm) is expressed by the following formula 3-2.
Y ₃ ≦ 13.1 · X ₃ ² -76.3X ₃ +103 (Equation 3-2)
Further, the relational expression determined when the partial pressure of TiCl ₄ is 0.71 Pa (corresponding to 6 sccm) is expressed by the following formula 3-3.

Y ₃ ≦ 16.4 · X ₃ ² −67.1 · X ₃ +66.6 (Equation 3-3)
At this time, the lower limit of each partial pressure of N ₂ gas and TiCl ₄ gas is 0.12 Pa (corresponding to 1 sccm), preferably 0.48 Pa (corresponding to 4 sccm).

[Evaluation of deposition state of second titanium nitride film]
Here, the deposited state of the thin film in the vicinity of the bottom surface of the recess when the second titanium nitride film was actually formed using the method of the present invention was examined, and the evaluation result will be described. FIG. 10 is a graph showing the relationship between the N ₂ gas flow rate and the film thickness when the RF power is 800 W and the TiCl ₄ gas flow rate is 12 sccm. Here, the N ₂ gas flow rate is variously changed from 1 to 1000 sccm. A second titanium nitride film is deposited. This graph is the same graph as the characteristic when the high-frequency power in FIG. Therefore, the process conditions are as follows: high-frequency power is 800 W, TiCl ₄ gas flow rate is 12 sccm, process temperature is 550 ° C., and the diameter of the recess 6 is 60 nm.

As shown in FIG. 10, when the N ₂ gas flow rate is increased from 1 sccm, the film thickness sequentially increases, and when the N ₂ gas flow rate is about 300 sccm, the film thickness reaches the peak N2. As the N ₂ gas flow rate is further increased, the film thickness gradually decreases. Here, the region on the right side from the peak N2 without including the peak N2 is referred to as mode 1, and the region on the left side from the peak N2 including the peak N2 is referred to as mode 2. The region of mode 2 is a region where the second titanium nitride film is deposited well as described above.

Then, the deposition state of the point A1 (N ₂ = 1000 sccm) portion representing the mode 1 region and the point A2 (N ₂ = 100 sccm) portion representing the mode 2 region was examined. The results are shown in FIG.

  FIG. 11 is an electron micrograph showing the deposition state of the thin film in the vicinity of the bottom surface of the recess. Here, FIG. 11A shows mode 1 (point A1), and FIG. 11B shows mode 2 (point A2). In FIG. 11, an enlarged photograph of the vicinity of the bottom surface of the concave portion is shown together with the lower portion of the photograph showing the cross section of the concave portion. The deposition time is 70 sec in mode 1 and 28 sec in mode 2. As a result, in the case of mode 1, the thickness of the titanium nitride film (second titanium nitride film) deposited on the bottom surface of the recess is substantially zero although the deposition time is longer than that in mode 2. Therefore, the bottom coverage was 0% (the thickness of the titanium nitride deposited on the bottom surface of the recess relative to the thickness of the titanium nitride deposited on the upper surface of the insulating layer), and an undesirable result was obtained.

  On the other hand, in the case of mode 2, although the deposition time is short, a titanium nitride film (second titanium nitride film) is sufficiently deposited on the bottom surface of the recess and the bottom coverage reaches about 30%, which is preferable. The result was obtained. In this mode 2, it is confirmed that the titanium nitride film is very thin and slightly deposited on the side wall in the recess. From this point, it is confirmed that the deposition state in mode 2 is good. I was able to.

Next, the difference in the reaction form occurring in the mode 1 and the mode 2 in which the deposition state is good will be schematically described. FIG. 12 is a diagram schematically showing the form of the reaction that occurs when the N ₂ gas flow rate is high and low when depositing the second titanium nitride film. Here, when the N ₂ gas flow rate is high, mode 1 is indicated, and when the N ₂ gas flow rate is low, mode 2 is indicated. Further, on the right side in FIG. 12, the state of the gas entering the recess is schematically shown.

As shown in FIG. 12A, in the case of mode 1, since a large amount of N ₂ gas is supplied, the N ₂ gas and H ₂ gas supplied as a reducing gas are activated by plasma. Both react to generate a large amount of active species H *, N *, NH ^* (* represents an active species), and this H *, N *, NH ^* is adsorbed on the wafer surface. Then, TiClx (X: 1 to 3) generated by decomposing TiCl ₄ by plasma reacts with H *, N *, NH ^* adsorbed on the wafer surface to reduce it, and as a result, HCl And a TiN film is deposited on the wafer surface.

In such a reaction mode, NH ^* which is an active species adheres to the surface in the recess 6 of the wafer W as described above, but the TiClx is consumed in the vicinity of the opening of the recess 6, and the recess A situation occurs where the bottom of 6 is not fully reached. As a result, in the case of mode 1, a state in which the TiN film is not sufficiently deposited on the bottom surface in the recess 6 occurs.

In contrast, as shown in FIG. 12B, in the case of mode 2, since the supplied N ₂ gas is small, TiClx (X: 1 to 3) generated by decomposing TiCl ₄ by plasma is used. ) Is larger than that in mode 1, and this TiClx is adsorbed on the wafer surface. The TiClx adsorbed on the wafer surface reacts with N ^* , H ^* and NH ^* generated by activating N ₂ and H ₂ with plasma to reduce them, and as a result, HCl is generated. At the same time, a TiN film is deposited on the wafer surface.

In such a reaction mode, TiClx adheres to the surface in the recess 6 of the wafer W as described above, but N ^* , H ^* , and NH ^* are relatively larger than TiClx, so N ^* , Even if H ^* and NH ^* are consumed in the vicinity of the opening of the recess 6, the H ^* and NH ^* remain sufficiently, reach the bottom of the recess 6 sufficiently, and a TiN film is sufficiently deposited on the bottom of the recess 6. Will be able to.

  As described above, according to the present invention, in the film forming method for forming a thin film on the surface of the object having the recess 6 formed on the surface, for example, the surface of the semiconductor wafer W, the surface of the object to be processed including the inner surface of the recess 6. A titanium film forming step of forming a titanium film using a titanium compound gas and a reducing gas, a nitriding step of forming a first titanium nitride film 104 by nitriding all of the titanium film using a nitriding gas, and a recess 6 And a titanium nitride film deposition step in which the second titanium nitride film 106 is deposited on the surface of the object to be processed including the inner surface of the object. The thin film functioning as a layer can be efficiently deposited on the bottom of the recess 6 while suppressing the deposition on the sidewall of the recess 6.

<Tungsten film formation process>
Next, the tungsten film forming process will be described. If the barrier layer 108 is formed by forming the first titanium nitride film 104 and the second titanium nitride film 106 as described above, then a tungsten film for filling the recess 6 is formed. FIG. 13 is a timing chart showing the supply timing of each gas when forming a tungsten film.

  In order to form the tungsten film, the wafer W is transferred to another tungsten film forming apparatus (not shown). The tungsten film is formed in the same manner as the film forming apparatus shown in FIG. 1, and a separately provided thermal CVD apparatus or the like may be used. Here, it is preferable to use the SFD method in which a tungsten-containing gas and a monosilane gas as a reducing gas are alternately supplied repeatedly to form a film.

  However, the wafer temperature (process temperature) at this time is adjusted to about 250 to 350 ° C., which is lower than the process temperature of about 400 to 450 ° C. in the conventional general thermal CVD process. The process pressure is adjusted to about 100 to 1000 Pa. Then, in the period P21, tungsten hexafluoride gas is supplied into the thermal CVD apparatus. At this time, the flow rate of tungsten hexafluoride gas is adjusted to 10 to 30 sccm. In this period P21, argon gas or nitrogen gas is supplied as a carrier gas together with the tungsten hexafluoride gas. The period P21 is set to 0.5 to 5 seconds, for example.

  Next, supply of tungsten hexafluoride gas is stopped from the state of the period P21, and the process proceeds to the period P22. This period P22 is a waiting time until the next period P23 is started, and this time is, for example, 0.5 to 3.0 seconds. In this period P22, it is preferable to continue supplying argon gas or nitrogen gas as a purge gas into the thermal CVD apparatus.

Subsequently, in a period P23, monosilane gas is supplied. At this time, the flow rate of the monosilane gas is adjusted to 50 to 100 sccm. In this period P23, argon gas or nitrogen gas is supplied as a carrier gas together with the monosilane gas. The period P23 is set to 0.5 to 5 seconds, for example. As the reducing gas, disilane (Si ₂ H ₆ ) gas, diborane (B ₂ H ₆ ) gas, or the like can be used instead of the monosilane gas.

  Next, the supply of monosilane gas is stopped from the state of period P23, and the process proceeds to period P24. This period P24 is a waiting time until the period P21 of the next cycle is started, and this time is, for example, 0.5 to 3.0 seconds. In this period P24, it is preferable to continue supplying argon gas or nitrogen gas as a purge gas into the thermal CVD apparatus.

  By executing the processes in the above periods P21 to P24, an extremely thin tungsten film is formed. Then, the process in the periods P21 to P24 is set as one cycle, and the cycle is repeated until the tungsten film 110 (see FIG. 3E) reaches a predetermined film thickness and the recess 6 is filled with tungsten.

  As described above, according to the SFD tungsten film forming process according to the present embodiment, tungsten hexafluoride gas and monosilane gas are alternately and repeatedly supplied to form the tungsten film 110 so as to stack an extremely thin tungsten film. Therefore, the tungsten film 110 with good characteristics can be formed even at a process temperature of 250 to 350 ° C., which is much lower than the process temperature of 400 to 450 ° C. in the conventional general CVD process.

  By the way, according to the SFD tungsten film forming process, the amount of tungsten deposited in one cycle is extremely small as described above. Therefore, for example, if a tungsten film having a thickness of 200 to 300 nm is to be formed, a considerably long process time is required. As a result, the throughput decreases. Therefore, in order to prevent this reduction in throughput, a second tungsten film forming process capable of obtaining a high film forming rate may be performed after the above SFD tungsten film forming process.

  In the second tungsten film forming process, for example, the process temperature is raised to about 400 to 450 ° C., and the process pressure is adjusted to about 2000 to 20000 Pa. Further, the monosilane gas as the reducing gas is switched to hydrogen gas, and the hydrogen gas and tungsten hexafluoride gas are supplied simultaneously and continuously together with the carrier gas. At this time, the flow rate of hydrogen gas is set to, for example, about 300 to 3000 sccm, and the flow rate of tungsten hexafluoride gas is adjusted to about 30 to 300 sccm. By using such a process recipe, the tungsten film 110 can be formed at a high film formation rate, for example, 1000 to 5000 ５ / min.

  As described above, according to the film forming process according to the present embodiment, the thin titanium film 100 is formed by the titanium film forming process, and is nitrided by the nitriding process. A titanium nitride film 104 is formed. At this time, since the titanium film is thin, all of the titanium film can be securely nitrided without leaving the titanium film. As described above, according to this embodiment, the titanium film that may actively react with fluorine contained in the tungsten hexafluoride gas used to form the tungsten film 110 is formed under the first titanium nitride film 104. Therefore, the second titanium nitride film 106 and the tungsten film 110 can be prevented from being peeled off from these base layers.

  Further, in the present embodiment, since the second titanium nitride film 106 is formed on the first titanium nitride film 104 in the titanium nitride film deposition step, the barrier function can be sufficiently exhibited, As a result, it is possible to prevent diffusion of tungsten hexafluoride used in the tungsten film forming process, which is a subsequent process, due to fluorine.

Further, when the second titanium nitride film 106 is deposited, the relationship among the N ₂ gas amount, the high frequency power for plasma generation, and the TiCl ₄ gas amount is optimized. Even inside a recess (hole), a titanium nitride film can be sufficiently formed on the bottom surface side while suppressing film formation on the side wall in the recess, preventing the inside of the recess from being blocked. can do.

  For this reason, a tungsten film can be sufficiently deposited in the concave portion in a subsequent tungsten film forming step, and the contact resistance (plug resistance) and the like can be reduced. In the above embodiment, since the titanium film forming step, the nitriding step, and the titanium nitride film depositing step are continuously performed in the same film forming apparatus, the throughput can be improved.

  In the above embodiment, Ar gas is used as the plasma stabilizing gas. However, the present invention is not limited to this, and other rare gas such as He may be used. In the above embodiment, the titanium film forming step, the nitriding step, and the titanium nitride film depositing step are continuously performed in the same film forming apparatus. However, the present invention is not limited to this, and the titanium nitride film depositing step is performed. May be performed by another film forming apparatus provided separately.

  Although the semiconductor wafer is described as an example of the object to be processed here, the semiconductor wafer includes a silicon substrate and a compound semiconductor substrate such as GaAs, SiC, GaN, and the like, and is not limited to these substrates. The present invention can also be applied to glass substrates, ceramic substrates, and the like used in display devices.

It is a section lineblock diagram showing an example of a film deposition system concerning the present invention. It is a flowchart which shows an example of the film-forming method of this invention. It is explanatory drawing for demonstrating the state of the thin film formed on the surface of a to-be-processed object by this invention method. It is a timing chart which shows the supply state of each gas at the time of formation of the 1st titanium nitride film. Is an explanatory view for explaining the relationship between the N ₂ gas flow rate and the TiCl ₄ gas flow rate when the constant RF power (RF power) in the case of depositing a second titanium nitride film. And N ₂ gas flow rate and RF power and TiCl ₄ gas flow rate is an explanatory diagram for explaining the effect of the variation of the peak of thickness in the case of forming the second titanium nitride film. It is an explanatory diagram for explaining the optimum range of the N ₂ gas flow rate to the high-frequency power at the time of depositing the second titanium nitride film. It is an explanatory diagram for explaining the optimum range of the N ₂ gas flow rate per unit area of the object with respect to the high frequency power per unit area of the object at the time of depositing the second titanium nitride film. It is an explanatory diagram for explaining the optimum range of the partial pressure of N ₂ gas to the high frequency power per unit area of the object at the time of depositing the second titanium nitride film. RF power is 800 W, is a graph showing the TiCl ₄ gas flow takes out the relationship between the _{N 2} gas flow rate and the film thickness when the 12 sccm. It is an electron micrograph which shows the deposition state of the thin film in the bottom face vicinity of a recessed part. It is a diagram schematically showing the form of the reaction which occurs when small and when N ₂ gas flow rate is high at the time of depositing the second titanium nitride film. It is a timing chart which shows the timing of supply of each gas at the time of forming a tungsten film. It is a figure which shows the general contact structure in a semiconductor wafer.

Explanation of symbols

2 Insulating layer 4 Conductive layer 6 Recessed portion 22 Deposition device 24 Processing vessel 26 Susceptor (mounting table)
32 Heater (heating means)
36 Lower electrode 40 Shower head part 56 Gas supply means 60 TiCl ₄ gas supply source 62 Ar gas supply source 64 H ₂ gas supply source 66 NH ₃ gas supply source 68 N ₂ gas supply source 72 High frequency power supply means 94 Control part 98 Memory Medium 100 Titanium film 102 Titanium silicide layer 104 First titanium nitride film 106 Second titanium nitride film 108 Barrier layer 110 Tungsten film W Semiconductor wafer (object to be processed)

Claims (22)

In a film forming method for forming a thin film on the surface of an object to be processed in which a recess is formed on the surface,
A titanium film forming step of forming a titanium film using a titanium compound gas and a reducing gas on the surface of the object to be processed including the inner surface of the recess;
A nitriding step of nitriding all of the titanium film using a nitriding gas to form a first titanium nitride film;
A titanium nitride film deposition step of depositing and forming a second titanium nitride film on the surface of the object to be processed including the inner surface of the recess;
A method for forming a thin film, comprising: 2. The method of forming a thin film according to claim 1, wherein the titanium nitride film deposition step is performed after the titanium film forming step and the nitriding step are alternately repeated a plurality of times. 3. The thin film forming method according to claim 1, wherein the titanium film forming step and the nitriding step are each performed in the presence of plasma. A conductive layer containing silicon is exposed at the bottom of the recess, and the titanium silicide layer is formed in the titanium film forming step so that silicon in the conductive layer reacts with titanium in the titanium film. 4. The thin film deposition method according to claim 1, wherein the object to be processed is set to a first temperature. 5. The method of forming a thin film according to claim 4, wherein the first temperature is in a range of 400 to 650.degree. The thin film forming method according to claim 1, wherein the titanium film formed in the titanium film forming step has a thickness of 15 nm or less. The titanium nitride film deposition step is characterized in that the second titanium nitride film is deposited in the presence of plasma using a titanium compound gas, a reducing gas, a nitrogen gas, and a plasma stabilizing gas. Item 7. The method for forming a thin film according to any one of Items 1 to 6. The flow rate Y ₁ of the nitrogen gas, the relationship between the high-frequency power X ₁ to be introduced in order to generate the plasma, said to satisfy a predetermined relational expression determined depending on the flow rate of the titanium compound gas flow rate Y ₁ the high frequency power X ₁ and the thin film forming method according to claim 7, characterized in that it is set to. 9. The method of forming a thin film according to claim 8, wherein the predetermined relational expression is the following formula 1 when the flow rate of the titanium compound gas is 20 sccm or less.
Y ₁ ≦ 7.62 · 10 ⁻⁴ · X ₁ ² −2.37 · X ₁ + 2.02 · 10 ³ (Expression 1) Thin film forming method according to claim 9, wherein the lower limit of the flow rate Y ₁ of said nitrogen gas is 1 sccm. The relationship between the flow rate Y _{2 of the} nitrogen gas per unit area of the object to be processed and the high frequency power X ₂ per unit area of the object to be processed to form the plasma is expressed by the titanium compound gas. thin film according to claim 7, wherein the flow rate Y ₂ and said high frequency power X ₂ is set so as to satisfy a predetermined relational expression determined depending on the flow rate per unit area of the object to be processed The film forming method. The predetermined relational expression is the following formula ² when the flow rate of the titanium compound gas per unit area of the object to be processed is 2.831 · 10 ⁻² sccm / cm ² or less. Item 12. A method for forming a thin film according to Item 11.
Y ₂ ≦ 5.39 · 10 ⁻¹ · X ₂ ² −2.37 · X ₂ +2.86 (Equation 2) Wherein the nitrogen gas lower limit of the flow rate _{Y 2} per unit area of the object is, thin film forming method according to claim 12, characterized in that the ^{1.415 · 10 -3 sccm / cm 2} . A relationship between the partial pressure Y _{3 of the} nitrogen gas and the high-frequency power X ₃ per unit area of the object to be processed to generate plasma is determined depending on the partial pressure of the titanium compound gas. the partial pressure Y ₃ and the RF power X ₃ and film formation method of a thin film according to claim 7, characterized in that it is set so as to satisfy the relational expression. 15. The method of forming a thin film according to claim 14, wherein the predetermined relational expression is the following formula 3 when the partial pressure of the titanium compound gas is 2.37 Pa or less.
Y ₃ ≦ 28.9 · X ₃ ² −140 · X ₃ + 1.87 · 10 ² (Expression 3) Partial lower limit of the pressure Y ₃ of the nitrogen gas, thin film forming method according to claim 15, wherein it is 0.12 Pa. The thin film forming method according to claim 1, wherein the titanium film forming step, the nitriding step, and the titanium nitride film depositing step are performed in the same film forming apparatus. . The method of forming a thin film according to claim 1, wherein the titanium compound gas is a titanium tetrachloride gas. The method of forming a thin film according to any one of claims 1 to 18, wherein the reducing gas is hydrogen gas. 20. The thin film according to claim 1, wherein after the titanium film deposition step, a tungsten film formation step is performed in which a tungsten film is formed on a surface of the object to be processed and the recess is embedded. The film forming method. In a film forming apparatus for forming a thin film on the surface of an object to be processed having a recess formed on the surface,
A processing container for containing the object to be processed;
A mounting table on which the object to be processed is mounted in the processing container and provided with a lower electrode;
A shower head portion that introduces gas into the processing vessel and also serves as an upper electrode;
A gas supply means connected to the shower head section for supplying necessary gas;
Heating means for heating the object to be processed;
An exhaust system for evacuating the inside of the processing vessel;
High-frequency power supply means for supplying high-frequency power to form plasma in the processing vessel;
A control unit for controlling the entire apparatus in order to carry out the thin film forming method according to any one of claims 1 to 20,
A film forming apparatus comprising: A processing container for storing an object to be processed;
A mounting table on which the object to be processed is mounted in the processing container and provided with a lower electrode;
A shower head portion that introduces gas into the processing vessel and also serves as an upper electrode;
A gas supply means connected to the shower head section for supplying necessary gas;
Heating means for heating the object to be processed;
An exhaust system for evacuating the inside of the processing vessel;
High-frequency power supply means for supplying high-frequency power to form plasma in the processing vessel;
When forming a thin film on the surface of an object to be processed having a recess formed on the surface using a film forming apparatus having a control unit for controlling the entire apparatus,
21. A storage medium storing a computer-readable program for controlling the entire apparatus so as to carry out the thin film forming method according to any one of claims 1 to 20.

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