KR100881397B1 - Method for forming amorphous carbon layer and method for manufacturing pattern of semiconductor device using the same - Google Patents

Abstract

According to an aspect of the present invention, there is provided a method of forming an amorphous carbon film and a method of forming a pattern of a semiconductor device using the same, the method comprising: forming a first amorphous carbon film on a semiconductor substrate in the method of forming an amorphous carbon film for improving adhesion; Forming a second amorphous carbon film containing silicon on the amorphous carbon film.

Description

Amorphous carbon film formation method and pattern formation method of semiconductor device using the same {METHOD FOR FORMING AMORPHOUS CARBON LAYER AND METHOD FOR MANUFACTURING PATTERN OF SEMICONDUCTOR DEVICE USING THE SAME}

1 is a photograph showing a conventional problem.

2A to 2I are cross-sectional views illustrating processes of forming an amorphous carbon film and a method of forming a semiconductor device using the same according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

200: semiconductor substrate 202: etching target layer

204: first amorphous carbon film 206: second amorphous carbon film

208: hard mask 210: first antireflection film

212: sacrificial film 214: second antireflection film

216 photosensitive film pattern 218 spacer

The present invention relates to a method of forming an amorphous carbon film and a method of forming a pattern of a semiconductor device using the same, and more particularly, to a method of forming an amorphous carbon film capable of improving the adhesion of an amorphous carbon film used as a hard mask and a semiconductor device using the same. It relates to a pattern forming method.

In manufacturing a semiconductor device, various patterns including contact holes are formed through a photolithography process. As is well known, such photolithography step includes a step of forming a photoresist pattern and a step of etching the etching target layer using the photoresist pattern as a mask.

The process of forming the photoresist pattern may include applying a photoresist on the etched layer, selectively exposing the photoresist using a specific exposure mask, and a portion of the photoresist exposed or unexposed with a predetermined chemical solution. It consists of a developing process to remove.

Meanwhile, as the degree of integration of semiconductor devices increases, the size of the pattern is accompanied by a decrease in the size of the pattern. Accordingly, the technology for the photolithography process is actively being developed.

Here, the current fine pattern formation technique has been advanced by a method of selecting a short wavelength as the light source used in the exposure apparatus. For example, conventional exposure apparatuses have mainly used G-line (λ = 435 nm) or I-line (λ = 365 nm) as light sources, but these light sources have a fine line width that is required in high-density devices due to resolution limitations. It became difficult to form the pattern of.

Therefore, recently, KrF (λ = 248 nm) or ArF (λ = 193 nm) or the like having a shorter wavelength than the light sources has been used as a light source of an exposure apparatus, and furthermore, electron beams, ion beams and X-rays The same non-optical light source was used.

However, the above-mentioned method has the advantage of ease of use, but the investment cost for the equipment is very large, so that its practical application is difficult.

On the other hand, as semiconductor devices are increasingly integrated, in addition to the above-described method, a mask or an etching process is further performed by further layering a film such as a nitride film or a polysilicon film on an amorphous carbon film, which is a hard mask, in order to realize 40 nm-class fine patterning. In addition, a fine patterning method such as a step of removing the amorphous carbon film is used.

Here, the amorphous carbon film has three sigma bonds with three other carbons in a plane as a hybrid orbital function to form a hexagonal plate structure, and the remaining p orbitals have weak bonds of p orbitals and pi bonds of other atoms. sp ² is a membrane having a structure similar to the graphite structure.

Therefore, the weak pie bonds weaken the adhesion between the films, thereby stacking the nitride film and the polysilicon film, and when the heat is applied for a long time in a subsequent process, the lifting is performed as shown in FIG. Lifting phenomenon occurs.

As a result, when performing a fine patterning process of a semiconductor device using a multi-layer hard mask to which the amorphous carbon film is applied, it is difficult to easily perform the process.

The present invention provides a method of forming an amorphous carbon film capable of preventing a lifting phenomenon of the hard mask when forming a multilayer hard mask to which an amorphous carbon film is applied, and a method of forming a pattern of a semiconductor device using the same.

In addition, the present invention, when forming a multi-layer hard mask to which an amorphous carbon film is applied, an amorphous carbon film forming method that can easily perform a fine pattern forming process by preventing the lifting of the hard mask as described above and a pattern of a semiconductor device using the same It provides a formation method.

In accordance with another aspect of the present invention, there is provided a method of forming an amorphous carbon film, the method comprising: forming a first amorphous carbon film on an upper surface of a semiconductor substrate; And forming a second amorphous carbon film containing silicon on the first amorphous carbon film.

The first amorphous carbon film is formed using a gas of any one of C ₃ H ₆ , C ₅ H _8, and C ₂ H ₂ as a source.

The second amorphous carbon film is formed using a mixed gas of any one of SiH ₄ and C ₃ H ₆ , C ₅ H ₈ and C ₂ H ₂ as a source.

In addition, a method of forming a pattern of a semiconductor device using the method of forming an amorphous carbon film according to the present invention may include forming a first amorphous carbon film on a semiconductor substrate including an etching target layer; Forming a second amorphous carbon film containing silicon on the first amorphous carbon film to form a hard mask including a laminated film of the first amorphous carbon film and the second amorphous carbon film; And etching the etching target layer by using the hard mask as an etching mask.

The first amorphous carbon film is formed using a gas of any one of C ₃ H ₆ , C ₅ H _8, and C ₂ H ₂ as a source.

The second amorphous carbon film is formed using a mixed gas of any one of SiH ₄ and C ₃ H ₆ , C ₅ H ₈ and C ₂ H ₂ as a source.

Etching the etching target layer using the hard mask as an etching mask may include: sequentially forming a first antireflection film, a sacrificial film, and a second antireflection film on the hard mask; Removing the second anti-reflection film and the sacrificial film until the first anti-reflection film is exposed to have a predetermined pattern; Removing the second anti-reflection film; Forming spacers on both sides of the sacrificial layer; Removing the sacrificial layer; Etching the first anti-reflection film and the hard mask using the spacers remaining on the first anti-reflection film from which the sacrificial film is removed as a mask pattern; Removing the spacer and the first anti-reflection film; Etching the etching target layer using the hard mask as a mask pattern; And removing the hard mask.

The sacrificial film is formed of any one of an amorphous carbon film, a nitride film, or polysilicon, or at least two or more laminated films.

The spacer is formed by LP-Nit or ALD-Oxide method.

(Example)

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a method for forming a fine pattern of a semiconductor device of 40 nm or less, in which an amorphous carbon film is applied as a hard mask, wherein the hard mask includes a first amorphous carbon film and silicon, that is, a second containing SiH _4. It is formed of a laminated film of an amorphous carbon film.

In this way, unlike the conventional amorphous carbon film having the CC / C = C / C = O / CH _x bonding structure, the second amorphous carbon film containing the first amorphous carbon film and silicon as the hard mask as described above Formed by dividing the process, by forming a CC / C = C / C = O / Si-C / CH _x bond to form a diamond-like structure having a relatively strong sigma bond, thereby improving the adhesion of the amorphous carbon film You can.

Therefore, since the adhesion to the multilayer etching mask formed on the amorphous carbon film can be improved, the lifting phenomenon on the amorphous carbon film can be prevented, so that the stability in the subsequent process can be ensured.

In addition, as described above, the amorphous carbon film containing silicon, that is, SiH ₄ , forms a Si-O / Si-N bond structure with oxygen or nitrogen, whereby C-O / C- in the conventional amorphous carbon film is formed. Since the binding energy is superior to that of the N bond, the properties can be improved in terms of the binding energy, thereby further securing stability in subsequent processes.

2A to 2I are cross-sectional views illustrating processes for forming an amorphous carbon film and a method for forming a pattern of a semiconductor device using the same according to an embodiment of the present invention.

Referring to FIG. 2A, a first amorphous carbon film 204 is formed on the semiconductor substrate 200 including the etching target layer 202. The first amorphous carbon film 204 is formed using a C _x H _y gas as a source. At this time, the C _x H _y gas and the first amorphous carbon film 204 react to form CC / C = C / C = O / CH _x To form a bonding structure.

The C _x H _y gas is formed of any one of C ₃ H ₆ , C ₅ H _8, and C ₂ H ₂ .

Referring to FIG. 2B, a second amorphous carbon film 206 is thinly formed on the first amorphous carbon film 204 to form a laminate film of the first amorphous carbon film 204 and the second amorphous carbon film 206. A hard mask 208 is formed. Here, the second amorphous carbon film 206 is formed using a mixed gas of SiH ₄ and C _x H _y as a source, and any of SiH ₄ and C ₃ H ₆ , C ₅ H _8, and C ₂ H ₂ One mixed gas and the second amorphous carbon film 206 react to form a CC / C = C / C = O / Si-C / CH _x coupling structure.

In this case, when the silicon is contained in the film by the mixed gas of SiH ₄ and C _x H _y as described above, the amorphous carbon film has sp ³ together with carbon because the outermost electron number of the silicon atoms is the same as carbon. Since the sp ² bond ratio of the C = C bond is relatively replaced by the Si—C sp ³ bond to form a bond, the sp ³ bond ratio of the amorphous carbon film is increased, so that CC / C = C / A C = O / Si-C / CH _x bond structure is formed.

Thus, the amorphous carbon film has four hybrid orbital functions in the CC / C = C / C = O / Si-C / CH _x bond structure as described above, and each diamond has a strong bond structure of four different atoms and sigma bonds. By forming a structure similar to that, the adhesion of the amorphous carbon film as a hard mask can be improved accordingly.

Referring to FIG. 2C, a first anti-reflection film 210 made of a material such as SiON is formed on a hard mask 208 formed of a laminated film of the first amorphous carbon film 204 and the second amorphous carbon film 206. The sacrificial layer 212 is formed on the first antireflection layer 210.

Here, the sacrificial film 212 is preferably formed of any one film or at least two or more laminated films of an amorphous carbon film, a nitride film or polysilicon.

Referring to FIG. 2D, a second anti-reflection film 214 is formed on the sacrificial film 212, and then the second anti-reflection film 214 and the sacrificial film (214) are formed on the second anti-reflection film 214. A photosensitive film pattern 216 for patterning 212 is formed.

Referring to FIG. 2E, the second anti-reflection film 214 and the sacrificial film 212 are etched using the photoresist pattern 216 as a mask pattern until the first anti-reflection film 210 is exposed.

Referring to FIG. 2F, the photoresist pattern 216 and the first anti-reflection film 210 formed on the first anti-reflection film 210 are removed, and spacers 218 are formed on both sidewalls of the sacrificial film 212. . The spacer 218 is preferably formed by LP-Nit or ALD-Oxide.

Referring to FIG. 2G, the sacrificial layer 212 on which the spacer 218 is formed is selectively removed so that only the spacer 218 remains.

Referring to FIG. 2H, the first anti-reflection film 210, the first amorphous carbon film 204, and the second amorphous carbon using the spacer 218 remaining on the first anti-reflection film 210 as a mask pattern. The hard mask 208 including the stacked layer of the film 206 is etched until the etching target layer 202 of the semiconductor substrate 200 is exposed.

Referring to FIG. 2I, the spacer 218 and the first anti-reflection film 210 are removed, and the hard mask 208 is formed of a laminated film of the first amorphous carbon film 204 and the second amorphous carbon film 206. ) Is etched using the etching target layer 202.

Subsequently, although not illustrated, the hard mask 208 including the laminated film of the first amorphous carbon film 204 and the second amorphous carbon film 206 is removed to remove the fine pattern of the semiconductor device according to the embodiment of the present invention. To form.

As described above, according to the present invention, in the method of forming a fine pattern of a semiconductor device of 40 nm or less in which an amorphous carbon film is applied as a hard mask, the hard mask includes a first amorphous carbon film and silicon, that is, SiH ₄ By forming the laminated film of the contained second amorphous carbon film, unlike the conventional amorphous carbon film having a CC / C = C / C = O / CH _x bonding structure, CC / C = C / C = O / Si-C Since the / CH _x bond is formed to form a structure similar to diamond having a relatively strong sigma bond, the adhesion of the amorphous carbon film can be improved.

Therefore, since the adhesive force with the multilayer etching mask formed on the amorphous carbon film can be improved, the lifting phenomenon in the amorphous carbon film can be prevented, so that the stability in the subsequent process can be ensured.

In addition, since the SiH ₄ -containing amorphous carbon film forms a Si-O / Si-N bonding structure with oxygen or nitrogen, the bonding energy is superior to that of the conventional one, and thus the characteristics can be improved in terms of bonding energy. .

In the above-described embodiments of the present invention, the present invention has been described and described with reference to specific embodiments, but the present invention is not limited thereto, and the scope of the following claims is not limited to the scope of the present invention. It will be readily apparent to those skilled in the art that the present invention may be variously modified and modified.

As described above, the present invention provides a method of forming a pattern of a semiconductor device of 40 nm or less in which an amorphous carbon film is applied as a hard mask, wherein the hard mask is used as the second amorphous carbon film and the second amorphous carbon film containing silicon. Formed by dividing the process, by forming a CC / C = C / C = O / Si-C / CH _x bond, to form a diamond-like structure having a relatively strong sigma bond, thereby improving the adhesion of the amorphous carbon film You can.

Therefore, the present invention can improve the adhesion of the amorphous carbon film, so that the lifting phenomenon can be prevented, so that the stability in the subsequent step can be ensured.

In addition, according to the present invention, since the SiH ₄ -containing amorphous carbon film forms a Si-O / Si-N bond structure with oxygen or nitrogen, its properties can be improved in terms of bonding energy, further improving stability in subsequent processes. It can be secured.

Claims (9)

delete delete delete Forming a first amorphous carbon film on the semiconductor substrate including the etching target layer; Forming a second amorphous carbon film containing silicon on the first amorphous carbon film to form a hard mask including a laminated film of the first amorphous carbon film and the second amorphous carbon film; And Etching the etching target layer using the hard mask as an etching mask; Including; Etching the etching target layer using the hard mask as an etching mask, Sequentially forming a first antireflection film, a sacrificial film, and a second antireflection film on the hard mask; Removing the second anti-reflection film and the sacrificial film until the first anti-reflection film is exposed to have a predetermined pattern; Removing the second anti-reflection film; Forming spacers on both sides of the sacrificial layer; Removing the sacrificial layer; Etching the first anti-reflection film and the hard mask using the spacers remaining on the first anti-reflection film from which the sacrificial film is removed as a mask pattern; Removing the spacer and the first anti-reflection film; Etching the etching target layer using the hard mask as a mask pattern; And Removing the hard mask; Pattern forming method of a semiconductor device comprising a. The method of claim 4, wherein The first amorphous carbon film is a pattern forming method of a semiconductor device, characterized in that formed using any one of the gas of C ₃ H ₆ , C ₅ H ₈ and C ₂ H ₂ as a source. The method of claim 4, wherein The second amorphous carbon film is formed using a mixed gas of any one of SiH ₄ and C ₃ H ₆ , C ₅ H ₈ and C ₂ H ₂ as a source. delete The method of claim 4, wherein The sacrificial film may be formed of any one of an amorphous carbon film, a nitride film, and polysilicon, or at least two or more laminated films. The method of claim 4, wherein The spacer is a pattern forming method of a semiconductor device, characterized in that formed by LP-Nit or ALD-Oxide method.

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