Dry etching method

Information

  • Patent Grant
  • 4992136
  • Patent Number
    4,992,136
  • Date Filed
    Monday, July 25, 1988
    36 years ago
  • Date Issued
    Tuesday, February 12, 1991
    33 years ago
Abstract
An article to be etched is contacted with a plasma of a mixed gas containing an etching gas and a film forming gas or a surface modification gas at a low temperature to effect the dry etching of the article, whereby the selectivity of etching can be made very high and the inclination angle of the side wall of pattern can be controlled at a desired level.
Description

BACKGROUND OF THE INVENTION
The present invention relates to a dry etching method and more particularly to a low temperature dry etching method capable of controlling the sectional shape of etched article and achieving a high etching selectivity.
The low temperature etching method wherein etching is effected by maintaining the temperature of a semiconductor substrate to be etched at 0.degree. C. or below (which is far lower than used conventionally), is described in, for example, Japanese Patent Application Kokai (Laid-Open) No. 158627/1985.
The above prior art describes that side etching can be made very small by etching silicon at low temperatures. However, it makes no mention as to the improvement of etching selectivity or the control of sectional shape of etched article. Therefore, effecting etching by simply reducing the temperature of a semiconductor substrate to be etched has heretofore made it difficult to carry out the patterning of a multilayered film at a high precision to form fine holes having a sectional shape suitable for filling.
SUMMARY OF THE INVENTION
The object of the present invention is to provide a low temperature dry etching method which solves the above-mentioned problems of the prior art and which can achieve a high etching selectivity and control the sectional shape of etched article at a high precision.
In the present invention, in order to achieve the above object, there is introduced into a reaction chamber, together with an etching gas, a gas which contains a film forming element (e.g. C or Si) and can form, at the time of etching, a film on the surface of a semiconductor substrate to be etched (the gas is hereinafter referred to as "film forming gas"), or a gas of a compound which contains an element (e.g. O or N) capable of reaction with the surface of a semiconductor substrate to be etched to form a reaction product layer on the surface (the gas is hereinafter referred to as "surface modification gas"), whereby the above semiconductor substrate is dry-etched.





BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is a graph showing the relationship between (a) the mixing ratio of CCl.sub.4 and SF.sub.6 and (b) the etching selectivity of Si/resist when Si was etched using a mixed gas of CCl.sub.4 and SF.sub.6 with a resist film used as a mask.





DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
In dry etching, when there is used, as a source gas for plasma, a mixed gas consisting of (a) an etching gas such as Cl.sub.2, SF.sub.6 or the like and (b) a gas of a halogen compound containing an element such as C, Si or the like capable of deposition on the surface of a semiconductor substrate at the time of etching to form a film thereon or a gas of a compound containing an element such as O, N or the like capable of reaction with the surface of the substrate to form a reaction product and change the properties of the surface, there take place simultaneously (1) the etching of the substrate by an etchant contained in the plasma such as F or the like and (2) the deposition of C, Si or the like on the substrate surface or the formation of an oxide layer by O or of a nitride layer by N on the substrate surface. In the side wall of the semiconductor substrate, in particular, a deposition effect or a modification phenomenon tends to appear as a result of anisotropic etching; hence, taper etching can be materialized by controlling the proportion of the gas (a) and the gas (b) and thereby the inclination of the side wall can be set at a desired level. In the reaction of the horizontal surface of the substrate, the etching rate of the resist film (mask) is substantially decreased because the temperature of the semiconductor substrate is maintained very low; consequently, etching of very high selectivity is realized
EXAMPLE 1
A semiconductor substrate was placed in the reaction chamber of a well known parallel plate plasma etching system (ordinarily referred to as "reactive ion etching system") and cooled to -100.degree. C. The polysilicon film formed on the semiconductor substrate was etched using a mixed gas consisting of CCl.sub.4 (a film forming gas) and SF.sub.6 (an etching gas), with a photoresist film used as a mask. FIG. 1 is a graph showing the relationship between (a) the mixing ratio of SF.sub.6 and CCl.sub.4 and (b) the selectivity of the polysilicon to the resist film (AZ1350J). As is appreciated from FIG. 1, the selectivity is very high (30 or above) when the CCl.sub.4 content in the mixed gas consisting of SF.sub.6 and CCl.sub.4 is 20 mol % or above [%: mol percent to (SF.sub.6 +CCl.sub.4)]. The mixed gas was very effective for the etching of the polysilicon film formed on the portions of high level difference, and good etching could be effected Besides the above CCl.sub.4, at least one member selected from carbon or silicon halides or hydrides such as CF.sub.4, CHF.sub.3, CHCl.sub.3, SiF.sub.4, SiCl.sub.4 and the like was suitable as a gas to be mixed with SF.sub.6. Thus, a very high selectivity can be obtained by effecting low temperature etching by the use of a mixed gas consisting of an etching gas and a film forming gas containing C or Si. Cl.sub.2 or Br.sub.2 can also be used as an etching gas in place of SF.sub.6.
Similar dry etching of high selectivity can be effected by adding a CO.sub.2 gas or a NH.sub.3 gas to SF.sub.6 in an amount of 5-30 mol %.
EXAMPLE 2
In selectively etching Al at a high selectivity, there is suitably used a low temperature etching method using a mixed gas consisting of a non-film-forming Cl.sub.2 gas and a film forming gas such as CCl.sub.4, SiCl.sub.4 or the like.
Very good results were obtained by adopting a mixing proportion of CCl.sub.4 or SiCl.sub.4 to Cl.sub.2, of 5-40 mol % and an etching temperature of 0.degree. to -30.degree. C. In effecting the high selectivity etching of a W or Mo film at -10.degree. C. to 0.degree. C., the use of a mixed gas consisting of SF.sub.6 and 5-30 mol % of a film forming gas (e.g. CCl.sub.4) or a surface modification gas (e.g. NH.sub.3) was found to be sufficient. In both cases, a selectively of W or Mo to photoresist, of 30 or above was obtained, and the W or Mo film could be etched selectively.
Thus, high selectivity etching can be materialized in low temperature etching by mixing an etching gas (e.g. SF.sub.6) with 5-40 mol % of a film forming gas (e.g. CCl.sub.4) or a surface modification gas (e.g. O.sub.2, NH.sub.3).
The present invention can be applied not only to the etching of the above materials but also to the etching of various other materials used in semiconductor devices, such as SiO.sub.2, Si.sub.3 N.sub.4, Mo, single-crystal silicon, gallium arsenide and the like. The present invention was effected not only in the above-mentioned parallel plate plasma etching system but also in a microwave plasma etching system and a magnetron plasma etching system, and excellent results were obtained in all the cases.
EXAMPLE 3
The taper etching of a polysilicon could be effected by etching a polysilicon film at a low temperature of -100.degree. C. using a mixed gas consisting of a SF.sub.6 gas and a CHF.sub.3 gas. The suitable mixing ratio of CHF.sub.3 to SF.sub.6 was 3-20 mol %. When the mixing ratio of CHF.sub.3 was changed, the taper angle of the side wall of the polysilicon film was changed also. That is, by changing the addition amount of CHF.sub.3 (a film forming gas), not only the selectivity but also the taper angle could be changed. In the present method, the dimension of the pattern obtained was not smaller than the dimension of the mask used, and the dimensional precision of the pattern was higher than in the conventional etching methods.
The above low temperature taper etching using a mixed gas consisting of an etching gas and a film forming gas is applicable also to films of materials other than the polysilicon, i.e. Al, SiO.sub.2, W, tungsten silicide, molybdenum silicide and single-crystal silicon. In fact, high selectivity (30 or above) and taper etching could be materialized by conducting low temperature etching using, as a plasma gas, a mixed gas consisting of at least two gases, one of them being a non-film-forming etching gas and the other being a film forming gas.
The present invention enables high selectivity etching and taper etching and accordingly is suited for patterning of high level difference and for processing of high aspect ratio, whereby filling of holes becomes easier and incidence of defectives such as disconnection due to overetching is reduced remarkably. Thus, the present invention provides a very advantageous effect in production of semiconductor devices.
In the present invention, the combination and mixing ratio of an etching gas and a film forming gas or a surface modification gas are selected appropriately depending upon the type of a material to be etched and the purpose of etching.
For instance, in the etching of W at a high etching selectivity, etching was conducted using a mixed gas comprising of SF.sub.6 and 5-40 mol % of CCl.sub.4 or NH.sub.3, and there was obtained an etching rate of at least 30 times larger than that of the photoresist film or the SiO.sub.2 film at a temperature (of W) of 0.degree. to 20.degree. C. In the etching of a polysilicon film or a single-crystal silicon substrate using a photoresist film as a mask, etching was conducted using a mixed gas consisting of SF.sub.6 and at least 20 mol % of CCl.sub.4, and there was obtained a very high etching selectivity of 30 or above at temperatures of -30.degree. to -140.degree. C. Appropriately same results were obtained also in cases of tungsten silicide and molybdenum silicide
In taper etching, the inclination angle of the side wall of the pattern obtained can be changed by changing the component ratio of the mixed gas used. For instance, when a polysilicon film or a single-crystal silicon substrate is taper-etched using a SF.sub.6 -CHF.sub.3 mixed gas, the inclination angle (against a horizontal plane) of the side wall of the pattern obtained can be changed between 75.degree. and 60.degree. by changing the CHF.sub.3 content between 15 and 20 mol %. Therefore, a pattern whose side wall has a desired inclination angle can be obtained by appropriately controlling the component ratio of the mixed gas used. This is effective for, for example, the prevention of disconnection caused by a big level difference.
In the present invention, the temperature of the article to be etched is important and no sufficient effect can be obtained when the etching of the present invention is effected at a relatively high temperature as in conventional etching methods That is, when the temperature of the article to be etched is higher than 0.degree. C., the control of the inclination angle of the side wall is very difficult even by using the above-mentioned mixed gas. Hence, it is necessary to maintain the temperature of the article to be etched at 0.degree. C. or below. The lower limit of the temperature of the article to be etched is the condensation temperature of the gas used and naturally differs by the type of the gas used.
Claims
  • 1. A dry etching method for selectively etching an article, wherein the article to be selectively etched, having a resist film as a mask, is placed in a reaction chamber of a dry etching apparatus; is contacted with a plasma of a gas to etch an exposed surface of the article, the gas being a mixed gas comprising (1) an etching gas and (2) a film forming gas or a surface modification gas and the temperature of the article to be etched being maintained at 0.degree. C. or below during etching, whereby the article can be etched with a high selectivity with respect to the resist film and with a tapered sectional shape; and is selectively etched; wherein the article to be etched is silicon; wherein the mixed gas includes the film forming gas, and the film forming gas is at least one member selected from the group consisting of CCl.sub.4, CF.sub.4, CHF.sub.3, CHCl.sub.3, SiF.sub.4 and SiCl.sub.4 ; and wherein the etching gas is SF.sub.6.
  • 2. A dry etching method according to claim 1, wherein the amount of the film forming gas is 20 mol % or more.
  • 3. A dry etching method for selectively etching an article, wherein the article to be selectively etched, having a resist film as a mask, is placed in a reaction chamber of a dry etching apparatus; is contacted with a plasma of a gas to etch an exposed surface of the article, the gas being a mixed gas comprising (1) an etching gas and (2) a film forming gas or a surface modification gas and the temperature of the article to be etched being maintained at 0.degree. C. or below during etching, whereby the article can be etched with a high selectivity with respect to the resist film and with a tapered sectional shape; and is selectively etched; wherein the article to be etched is aluminum; wherein the mixed gas includes the film forming gas, and the film forming gas is selected from CCl.sub.4 and SiCl.sub.4 ; and wherein the etching gas is Cl.sub.2.
  • 4. A dry etching method according to claim 3, wherein the amount of the film forming gas is 5-40 mol %.
  • 5. A dry etching method for selectively etching an article, wherein the article to be selectively etched, having a resist film as a mask, is placed in a reaction chamber of a dry etching apparatus; is contacted with a plasma of a gas to etch an exposed surface of the article, the gas being a mixed gas comprising (1) an etching gas and (2) a film forming gas or a surface modification gas and the temperature of the article to be etched being maintained at 0.degree. C. or below during etching, whereby the article can be etched with a high selectivity with respect to the resist film and with a tapered sectional shape; and is selectively etched; wherein the article to be etched is selected from the group consisting of a tungsten film a molybdenum film, a tungsten silicide film and a molybdenum silicide film; wherein the mixed gas includes the film forming gas, and the film forming gas is CCl.sub.4 ; and wherein the etching gas is SF.sub.6.
  • 6. A dry etching method according to claim 5, wherein the amount of the film forming gas is 5-30 mol %.
  • 7. A dry etching method for selectively etching an article, wherein the article to be selectively etched, having a resist film as a mask, is placed in a reaction chamber of a dry etching apparatus; is contacted with a plasma of a gas to etch an exposed surface of the article, the gas being a mixed gas comprising (1) an etching gas and (2) a film forming gas or a surface modification gas and the temperature of the article to be etched being maintained at 0.degree. C. or below during etching, whereby the article can be etched with a high selectivity with respect to the resist film and with a tapered sectional shape; and is selectively etched; wherein the resist film is a photoresist film; wherein said article is made of Si; said etching gas is SF.sub.6 ; and said film forming gas or surface modification gas is selected from the group consisting of CCl.sub.4, CHF.sub.3 and NH.sub.3.
  • 8. A dry etching method for selectively etching an article, wherein the article to be selectively etched, having a resist film as a mask, is placed in a reaction chamber of a dry etching apparatus; is contacted with a plasma of a gas to etch an exposed surface of the article, the gas being a mixed gas comprising (1) an etching gas and (2) a film forming gas or a surface modification gas and the temperature of the article to be etched being maintained at 0.degree. C. or below during etching, whereby the article can be etched with a high selectivity with respect to the resist film and with a tapered sectional shape; and is selectively etched; wherein the resist film is a photoresist film; wherein said article is made of Al; said etching gas is Cl.sub.2 ; and said film forming gas or surface modification gas is selected from the group consisting of SiCl.sub.4 and CCl.sub.4.
  • 9. A dry etching method for selectively etching an article, wherein the article to be selectively etched, having a resist film as a mask, is placed in a reaction chamber of a dry etching apparatus; is contacted with a plasma of a gas to etch an exposed surface of the article, the gas being a mixed gas comprising (1) an etching gas and (2) a film forming gas or a surface modification gas and the temperature of the article to be etched being maintained at 0.degree. C. or below during etching, whereby the article can be etched with a high selectivity with respect to the resist film and with a tapered sectional shape; and is selectively etched; wherein the resist film is a photoresist film; wherein said article is made of W; said etching gas is SF.sub.6 ; and said film forming gas or surface modification gas is CCl.sub.4.
Priority Claims (1)
Number Date Country Kind
62-187549 Jul 1987 JPX
US Referenced Citations (7)
Number Name Date Kind
4264409 Forget et al. Apr 1981
4615764 Bobbio et al. Oct 1986
4666555 Tsang May 1987
4678540 Uchimura Jul 1987
4726879 Bondur et al. Feb 1988
4734157 Carbaugh et al. Mar 1988
4741799 Chen et al. May 1988
Foreign Referenced Citations (1)
Number Date Country
60-158627 Aug 1985 JPX