JPH08222569A - Copper wiring manufacture, semiconductor device, and copper wiring manufacture device - Google Patents

Abstract

PURPOSE: To form copper wiring by simple process without using a wet process. CONSTITUTION: A barrier layer 5 and a high polymer film 6 are made in this order on an insulating film 3 grown on a substrate 2, and a groove 4 provided in the insulating film 3 is charged with a high polymer film 6, and the high polymer film is etched back, and the barrier layer is etched, protecting the barrier layer within the groove 4 with the high polymer film, and next the high polymer film is ashed, whereupon a wafer where base barrier layer 7 consisting of the barrier layer 5 is made in the groove can be obtained. Performing selective growth of copper for this wafer will grow a copper film only on the surface of the base barrier layer, and charge the groove with a copper film, so copper wiring can be made without performing wet processing.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technology for manufacturing fine copper wiring, a copper wiring manufacturing apparatus that can be used for manufacturing the same, and a semiconductor device having the copper wiring manufactured by the technology. The present invention relates to a copper wiring manufacturing method, a copper wiring manufacturing apparatus, and a semiconductor device having the copper wiring, which can be processed in a vacuum atmosphere with a simple manufacturing process.

[0002]

2. Description of the Related Art At present, as a wiring for connecting elements in a semiconductor integrated circuit, a wiring mainly made of aluminum (Al) is used for ease of processing.

However, since the wiring made of aluminum has weak resistance to electromigration and stress migration, it frequently breaks as the wiring becomes finer, which is a serious problem.

As a countermeasure against this, it has been proposed to form a wiring by using tungsten (W) or molybdenum (Mo) as a material, which has higher resistance to electromigration and stress migration than aluminum wiring. When these are applied to a fine wiring pattern, the voltage drop caused by the wiring becomes too large, causing the problem of heat generation in the wiring, and the large resistance value means that the signal transmission delays. There was a new problem such as being connected to.

Therefore, studies have begun on using copper (Cu), which has a small resistance value and excellent physical properties such as electromigration resistance and stress migration resistance, as a wiring material.

However, copper, which has excellent physical properties, is also LS
There are the following inconveniences when trying to use for I wiring,
It has been considered difficult to put it into practical use as a wiring material for semiconductor integrated circuits.

Diffusion is fast in silicon or a silicon oxide film. Poor adhesion to silicon oxide film. It is easily oxidized and corroded. Since the vapor pressure of the halogen compound of copper is low, the etching gas that can etch the conventional aluminum wiring cannot be used, and the fine processing cannot be performed by anisotropic dry etching.

However, in recent years, for example, titanium nitride (T
When a barrier layer such as an iN) thin film or a titanium tungsten (TiW) thin film is formed as a base thin film and a copper thin film is formed on the barrier layer, the barrier layer prevents diffusion of copper into the substrate. It has been found that the adhesiveness is improved together with this, and that if such a barrier layer is also formed on the copper thin film, the corrosion resistance of the copper wiring is also improved. There is a prospect for a solution.

Regarding the remaining problem of the fine processing of copper, for example, a wiring pattern is formed using a heat-resistant inorganic resist or the like on a copper thin film entirely formed on the surface of a substrate,
A solution of performing dry etching at a high temperature of 250 ° C. to 300 ° C. has been proposed, but the process becomes complicated,
Furthermore, there are many problems such as poor resolution and damage to copper wiring.

Further, regarding the formation of the wiring made of copper, a CVD reaction in which a copper thin film is formed on the entire surface of a semiconductor substrate, a resist similar to that conventionally used is applied and patterned, and then copper is deposited. A method of forming a copper wiring on a substrate by performing etching by a chemical reaction opposite to that has been proposed. This method has an advantage that etching can be performed at a relatively low temperature of 200 ° C. or lower,
Since the etching due to the reverse reaction of CVD is isotropic, several μ
Since it is difficult to perform a fine processing of m or less, it has not yet been put to practical use.

On the other hand, as a technique replacing the conventional etching technique, a method of forming fine copper wiring using a chemical mechanical polishing method (hereinafter referred to as CMP method) has been proposed. This method has the same idea as inlaying in the field of traditional crafts, and the CMP method will be briefly described with reference to the drawings.

Referring to FIG. 4A, reference numeral 102 denotes a silicon substrate, which has an insulating film 103 made of a silicon thermal oxide film. A groove 104 is provided in the insulating film 103, a barrier layer 105 is formed on the surface thereof, and a copper thin film 106 is conformally formed on the barrier layer 105 by a CVD method.

The surface of this substrate is polished with a polishing liquid (C
MP), as shown in FIG. 4B, the copper thin film 106 and the barrier layer 105, which were on the surface of the insulating film 103, were removed by polishing and filled in the groove 104. Only the copper wiring thin film 106 ′ and the underlying barrier layer 10 on the peripheral and bottom surfaces of the copper wiring thin film 106 ′.
5'is left in the groove 104.

Next, as shown in FIG. 4C, a protective film 107 having the same composition as that of the barrier layer 105 is formed on the entire surface of the substrate, and then the copper film is formed as shown in FIG. 4D. When the resist film 108 is provided so as not to remove the protective film 107 on the wiring thin film 106 ′ and etching is performed, an unnecessary portion of the protective film 107 is removed to form the cap layer 107 ′. For example, as shown in FIG. 4E, a copper wiring 109 in which the copper thin film wiring 106 'is encapsulated by the underlying barrier layer 105' and the cap layer 107 'is formed in the groove.

The width of the copper wiring 109 is the same as that of the groove 1.
Since the width can be made equal to the width of 04, if the groove width is miniaturized by anisotropic etching, the copper wiring 109 can also be miniaturized.

As described above, in order to make full use of copper wiring having excellent electric characteristics as a wiring material for semiconductor integrated circuits, its fine processing technology is very important, but it is used in the current aluminum processing process. Since the existing dry etching technique cannot be applied, the wet polishing technique such as the above-mentioned CMP method is regarded as promising at present.

[0017]

However, the above C
The MP method is a wet process premised on the use of a polishing liquid. Unlike the vacuum process, which can perform substrate processing in a clean atmosphere, such wet processing has various problems such as dust being generated during polishing and inevitably adhering to the substrate, which greatly reduces yield and reliability. Is newly generated.

Therefore, the present invention provides a semiconductor device having fine copper wiring which can be manufactured by a process in a clean atmosphere without using a wet process, a manufacturing method for manufacturing the copper wiring, and a manufacturing apparatus which can be used for the method. Technology to provide.

[0019]

In order to solve the above problems, the method according to the first aspect of the present invention is a copper wiring manufacturing method in which copper wiring is formed in a groove provided in an insulating film formed on a substrate. In the method, a barrier layer is formed on the surface of the insulating film, a polymer thin film is formed on the surface of the barrier layer, the inside of the groove is filled with the polymer thin film, and the surface is flattened. The polymer thin film is etched back, leaving the portion filled in, and the exposed barrier layer is etched to form a base barrier layer in the groove, and then the polymer left in the groove is removed. The underlying barrier layer is exposed, and a copper thin film is selectively grown on the exposed underlying barrier layer to form a copper wiring,

An invention method according to claim 2 is the method for producing copper wiring according to claim 1, characterized in that a cap layer is formed on the surface of the copper wiring.

According to a third aspect of the present invention, there is provided a device provided with an insulating film formed on a substrate, a groove provided in the groove, a base barrier layer formed in the groove, and the groove provided via the base barrier layer. A copper wiring having a copper thin film formed by filling the inside thereof, wherein the underlying barrier layer is such that a portion of the barrier layer formed on the surface of the substrate is inside the groove. Formed by etching using a polymer thin film as a mask, wherein the copper thin film is selectively formed on the underlying barrier layer by a selective growth method,

The invention device according to claim 4 is the semiconductor device according to claim 3, wherein in the copper wiring, the copper thin film is encapsulated by a cap layer and the underlying barrier layer provided on the surface of the copper thin film. Characterized in that

According to a fifth aspect of the present invention, there is provided a barrier layer deposition chamber for depositing a barrier layer, a vapor deposition polymerization chamber for depositing a polymer thin film by a vapor deposition polymerization method, and a copper thin film for selectively growing a copper thin film. In a copper wiring manufacturing apparatus in which a film forming chamber and an etching chamber for etching the barrier layer and the polymer thin film are arranged around a substrate transfer chamber in which a substrate transfer robot is placed, a substrate is transferred by the substrate transfer robot. When the substrate is transported and processed in each chamber, each chamber is evacuated and the substrate is not exposed to the atmosphere.

[0024]

When the barrier layer and the polymer thin film are formed in this order on the surface of the insulating film formed on the substrate, the polymer thin film is formed inside the groove provided in the insulating film through the barrier layer. Can be filled.

When the polymer thin film is formed by the vapor deposition polymerization method, the surface becomes flat. Therefore, the polymer thin film on the surface of the insulating film is left by ashing the polymer thin film, leaving the polymer thin film in the groove. Etching back can be performed.

The ashing of the polymer thin film does not etch the barrier layer and exposes the barrier layer on the surface of the oxide film. The exposed barrier layer is removed by dry etching to expose the surface of the oxide film. Can be made. Since the polymer thin film is not ashed by the gas used for etching the barrier layer, the underlying barrier layer made of the barrier layer remains in the groove.

At this time, since the polymer thin film still remains in the groove, if the polymer thin film is removed by ashing again, the surface of the underlying barrier layer is exposed in the groove. When selective growth of the copper thin film is performed, copper does not grow on the exposed oxide film surface, a copper thin film is formed only on the underlying barrier layer, and the copper is formed in the groove via the underlying barrier layer. Copper wiring can be formed by filling with a copper thin film. At this time, since the copper thin film is not formed on the entire surface, the copper wirings can be separated without performing wet etching of the copper thin film, and the copper wirings can be made fine by making the width of the groove fine.

A protective film is formed on the surface of the substrate on which the copper wiring is formed, and etching is performed so that the cap layer made of the protective film remains on the surface of the copper thin film filled in the groove. Since copper wiring encapsulated with the underlying barrier layer can be formed, copper atoms do not diffuse in the insulating film and copper corrosion does not occur.

Also, film formation of the barrier layer, vapor deposition polymerization of the polymer thin film, selective growth of the copper thin film, etching of the barrier layer, etchback and ashing of the polymer thin film, and capping. Since the layers can be formed in a reduced pressure atmosphere, a chamber for performing each process is connected through the substrate transfer chamber, and the substrate transfer chamber and the chamber for performing each process are in a vacuum state, and the process can be performed without exposing to the atmosphere. Since the process treatment can be performed in a clean atmosphere, the yield is not reduced due to dust adhesion, and a highly reliable copper wiring can be obtained.

[0030]

Embodiments of the present invention will be described with reference to the drawings. 1A to 1I are process diagrams for explaining one embodiment of the method of the present invention for producing a copper thin film wiring having a fine width.

Referring to FIG. 1A, reference numeral 41 denotes a wafer, which has an insulating film 3 made of a silicon oxide film having a thickness of 1.0 μm formed on a substrate 2 made of silicon single crystal. . A width of 0.35 μm and a depth of 0.7 μm are formed on the insulating film 3 by photolithography and dry etching.
A plurality of grooves 4 (aspect ratio = 2) are provided so as to form a line and space.

The semiconductor manufacturing apparatus 30 shown in FIG. 2 is a copper wiring manufacturing apparatus according to an embodiment of the present invention, and is for continuously processing the wafer 41 in a vacuum to form a copper wiring. Is. The semiconductor manufacturing apparatus 30 has a substrate transfer chamber 31 in which a substrate transfer robot 39 is provided, and the cassette chamber 3 is centered on the substrate transfer chamber 31.
2, barrier layer deposition chamber 33, vapor deposition polymerization chamber 34, etching chamber 35 for reactive ion etching, selective CV
Copper thin film deposition chamber 36 for performing D, and cap layer deposition chamber 37
Are arranged in this order in the counterclockwise direction in the drawing, and each chamber is placed in a high vacuum state by a vacuum pump (not shown).

The cassette chamber 32 is opened with each chamber other than the cassette chamber 32 kept at a high vacuum, the wafer 41 is placed in the cassette chamber 32, and then the wafer is placed in a vacuum state.
The substrate 41 was carried into the barrier layer deposition chamber 33 by the substrate transfer robot 39.

In the barrier layer film forming chamber 33, a TiN target is arranged at a distance of 300 mm from the loaded wafer, and an argon gas is introduced into the barrier layer film forming chamber 44 so that the barrier layer film forming chamber 44 is filled with argon gas. An order of magnitude lower, 0.35 × 10
When the TiN target was sputtered at a pressure of ⁻² Pa, a TiN thin film with a film thickness of 700 Å could be formed in the groove 4 with good coverage, as shown in FIG. 1 (b). A wafer 42 on which the barrier layer 5 consisting of was deposited was obtained.

Next, the wafer 42 was carried into the vapor deposition polymerization chamber 34 from the barrier layer film forming chamber 33. In the vapor deposition polymerization chamber 34, a raw material monomer A made of pyromellitic dianhydride and a raw material monomer B made of 4,4′-diaminodiphenyl ether are placed in separate containers and arranged in each container. The raw material monomers A and B are heated and evaporated by a wound heater to 6.5 × 10 ⁻⁴ P
The wafer 42 placed opposite to the containers of the raw material monomers A and B was opened by opening the shielding plate when the pressure was stable at a.
Then, vapor was adhered to the surface provided with the groove 4 to cause a polymerization reaction of the raw material monomer A and the raw material monomer B to generate a polyimide precursor on the surface of the wafer 42.

Since the temperature of the wafer 42 is kept at 80 ° C. and the reaction is carried out in the reaction rate-determining region, 10
By the polymerization reaction for one minute, the polymer thin film 6 having a flat surface was formed as shown in FIG. The polymer thin film 6 is composed of a polyimide precursor film, and the film forming rate at this time is 0.
It was 2 μm / min.

Wafer 4 on which the polymer thin film 6 is formed
3 is carried into the etching chamber 35, and the substrate temperature is 50 ° C.
Then, oxygen gas was introduced to a pressure of 1.5 Pa to generate plasma. The polymer layer is ashed by oxygen plasma, but the barrier layer 5 is not etched by oxygen plasma. Therefore, the wafer 44 shown in FIG.
As described above, the etch back was achieved in which the parliament layer 5 remained as it was and the polymer thin film 6 remained only inside the groove 4.

At this time, since just etching is difficult,
The height of the surface of the polymer thin film 6 left inside the groove 4 is lower than the height of the surface of the insulating film 3.

Next, while the wafer 44 was placed in the etching chamber 35, the oxygen gas supply was switched to the CF ₄ gas supply to generate plasma. In this case, the barrier layer 5 is etched by plasma of a fluorine-based gas, but the polymer thin film 6 is not ashed.
Like the wafer 45 shown in FIG. 1E, the insulating film 3
The barrier layer 5 on the surface is removed, and the underlying barrier layer 7 is formed on the bottom surface and the inner peripheral surface of the groove 4 protected by the polymer thin film 6.

When the supply of CF ₄ gas is stopped again and the supply of oxygen gas is switched to generate oxygen gas plasma, the polymer thin film 6 remaining in the groove 4 is ashed. As shown in 1 (f), a wafer 46 in which the underlying barrier layer 7 was exposed was obtained. At this time, the pressure was 35 Pa and the substrate temperature was 50 ° C.

This wafer 46 is placed in the selective CVD chamber 36.
Then, a positive monovalent copper organic complex gas is introduced, and a copper thin film 8 is selectively grown only on the surface of the barrier layer 7, and as shown in FIG. And the copper thin film 8 were filled. Here, hexafluoroacetylacetonate copper () vinyltrimethylsilane is used as the positive monovalent organic copper complex, the substrate temperature is 150 ° C., and the film forming pressure is 130 Pa.
The film forming reaction was carried out under the conditions of.

Then, the wafer 46 is loaded into the cap layer deposition chamber 37, the substrate temperature is kept at 350 ° C.
(NMe ₂ ) ₄ gas (“Me” represents a methyl group.
"t" represents an ethyl group. same as below. ) And NH ₃ gas were introduced, and the cap layer 9 made of a TiN thin film was formed by the CVD reaction of the following formula. 6Ti (NMe ₂ ) ₄ (g) + 8NH ₃ (g) → 6TiN (s) + 24NHMe ₂ (g) + N ₂ (g)

The CVD reaction in the above equation is reaction rate-determining, and T
Since the iN thin film grows conformally, a wafer 48 having a flat surface as shown in FIG. 1 (h) was obtained.

Finally, when the wafer 48 is loaded into the etching chamber 35 and is dry-etched by CF ₄ gas plasma, the TiN thin film 9 on the surface of the oxide film 3 is removed and only the copper thin film 8 is covered. Since the TiN thin film remains, the copper thin film 8 is encapsulated by the cap layer 10 composed of the remaining TiN thin film and the underlying barrier layer 7, as shown in the wafer 49 of FIG. 1 (i). The copper wiring 11 is formed, and the wafer 49 having the copper wiring 11 is taken out from the cassette chamber 32, and the process work is completed.

Since the copper wiring 11 has the same width as the groove width, if the groove 4 is miniaturized, the copper wiring 11 can also be miniaturized. Further, wet etching unlike the CMP method is not performed, and a clean atmosphere in vacuum is used. Since it can be processed with, the yield and reliability are high. Further, since the copper wiring 11 is encapsulated by the underlying barrier layer 7 and the cap layer 10, it is resistant to corrosion.

When the TiN thin films 5 and 9 are formed by the CVD method, Ti (NEt ₂ ) ₄ gas is used instead of Ti (NMe ₂ ) ₄ gas.
₄ gas is used, or NH ₃ gas is replaced with hydrazine (N ₂ H
₄ ) gas or methylhydrazine (N ₂ H ₃ CH ₃ ) gas may be used, or TiCl ₄ / NH ₃ based source gas or other Ti-containing organometallic gas may be used as source gas. . Further, instead of the TiN thin film, TiW, Ta, M
A thin film of a refractory metal or a refractory metal compound such as o or W, which can be easily removed by dry etching, can be used for the underlying barrier layer 7 and the cap layer 10.

Further, in the raw material monomers A and B, 4,4'-diphenylmethane diisocyanate and 4,
A polymer thin film made of polyurea may be formed by using 4′-diaminodiphenylmethane instead of the polyimide thin film, and a copolymerized polymer thin film may also be used. This polymer thin film can be widely used in the present invention as long as it can fill the groove and has a flat surface. An ordinary plasma asher can be used instead of RIE for etching the polymer thin film.

Furthermore, the cap layer deposition chamber 37 is C
Although it is an apparatus for forming a film by the VD method, it is also possible to use an ordinary sputtering apparatus for sputtering a TiN target. On the contrary, the barrier layer deposition chamber 33 may be replaced with a sputtering device, and a CVD device for depositing a barrier layer such as TiN by a CVD method, such as the cap layer deposition chamber 37, may be used.

The wafer 48 is taken out of the cassette chamber 32, and a resist film 13 patterned so as to protect the TiN thin film 9 on the copper wiring thin film 8 as shown by a wafer 50 in FIG. 3 (k). With CF ₄
Dry etching is performed by gas plasma to remove unnecessary portions of the TiN thin film 9 to form a cap layer 10 ′ as shown by a wafer 51 in FIG.
The copper wiring thin film 8 may be encapsulated with 0'and the underlying barrier layer 7 to obtain a copper wiring 11 '. At this time, the TiN thin film 9 can be left in a desired region because the resist film can protect the film even where the groove 4 is not provided.

[0050]

According to the present invention, since the treatment can be carried out in a vacuum atmosphere and the wet treatment is not required, the yield and reliability are improved, and the process is simplified, so that the throughput is improved.

[Brief description of drawings]

FIG. 1 is a process chart for explaining one embodiment of the method of the present invention.

FIG. 2 shows an example of a semiconductor manufacturing apparatus that can be used to carry out the method.

FIG. 3 is a process chart for explaining another embodiment of the method of the present invention.

FIG. 4 is a process diagram for explaining the CMP method.

[Explanation of symbols]

2 ... Substrate 3 ... Insulating film 4 ... Groove 5 ...
Barrier layer 6 Polymer thin film 7 Base barrier layer 8 Copper thin film 10, 10 'Cap layer 11, 11' Copper wiring 30 Copper manufacturing equipment 31 Substrate transfer chamber 33 …… Barrier layer deposition chamber 34 …… Vapor deposition polymerization chamber 35 …… Etching chamber 36 …… Copper thin film deposition chamber 39 …… Substrate transfer robot

Continuation of the front page (51) Int.Cl. ⁶ Identification number Reference number within the agency FI Technical display location C23C 16/34 H01L 21/302 J 21/88 R (72) Inventor Makoto Murata 2500 Hagien, Chigasaki, Kanagawa Japan In Vacuum Technology Co., Ltd. (72) Inventor Liu Ken Ken 2500, Hagizono, Chigasaki City, Kanagawa Japan Vacuum Technology Co., Ltd.

Claims (5)

[Claims] 1. A copper wiring manufacturing method for forming a copper wiring in a groove provided in an insulating film formed on a substrate, comprising: forming a barrier layer on the surface of the insulating film; A polymer thin film is formed on the groove, the groove is filled with the polymer thin film, and the surface is flattened. The polymer thin film is etched back leaving the portion filled in the groove, and the exposed barrier is exposed. After the layer is etched to form an underlying barrier layer in the groove, the polymer left in the groove is removed to expose the underlying barrier layer, and a copper thin film is selectively grown on the exposed underlying barrier layer. A method of manufacturing a copper wiring, which comprises: forming a copper wiring. 2. The copper wiring manufacturing method according to claim 1, wherein a cap layer is formed on the surface of the copper wiring. 3. A groove formed in an insulating film formed on a substrate, a base barrier layer formed in the groove, and copper filled in the groove via the base barrier layer. A copper wiring having a thin film, wherein the underlying barrier layer is formed by etching a portion of the barrier layer formed on the surface of the substrate in the groove using a polymer thin film filled in the groove as a mask. The semiconductor device is characterized in that the copper thin film is selectively formed on the underlying barrier layer by a selective growth method. 4. The semiconductor device according to claim 3, wherein the copper wiring is formed by encapsulating the copper thin film with a cap layer and the underlying barrier layer provided on the surface of the copper thin film. 5. A barrier layer deposition chamber for depositing a barrier layer, a vapor deposition polymerization chamber for depositing a polymer thin film by vapor deposition polymerization, a copper thin film deposition chamber for selectively growing a copper thin film, and the barrier. An etching chamber for etching the layer and the polymer thin film is a copper wiring manufacturing apparatus arranged around the substrate transfer chamber in which the substrate transfer robot is placed, and the substrate is transferred by the substrate transfer robot in each chamber. A copper wiring manufacturing apparatus, wherein each chamber is evacuated to vacuum during processing, and the substrate is not exposed to the atmosphere.