EP1438442A1

EP1438442A1 - Dual-source, single-chamber method and apparatus for sputter deposition

Info

Publication number: EP1438442A1
Application number: EP02776033A
Authority: EP
Inventors: Roman Chistyakov
Original assignee: EI Du Pont de Nemours and Co
Current assignee: EIDP Inc
Priority date: 2001-09-27
Filing date: 2002-09-27
Publication date: 2004-07-21
Also published as: CN1561405A; WO2003027352A1; JP2005504172A; KR20040044994A

Abstract

The present invention relates to a dual-source, single-chamber method and apparatus for epitaxial sputter deposition of epilayers and high quality films. The apparatus for performing the method includes a first sputtering source (2) for the sputtering of an epitaxial film on a substrate (6). A second sputtering source 4 is for the sputtering of reactive materials to create a getter on a cryogenic shroud (8). The first sputtering source (4) and the substrate (6) are surrounded by the cryogenic shroud (8).

Description

Title of Invention

Dual-Source, Single-Chamber Method and

Apparatus for Sputter Deposition

This application claims the benefit of U.S. Provisional Application No. 60/325,332, filed September 27, 2001, which is incorporated in its entirety as a part hereof .

Field of the Invention

This invention relates to a dual-source, single-chamber method and apparatus for epitaxial sputter deposition of epilayers and high quality films

Background of the Invention

One of the problems encountered in using a sputtering process for the formation of a thick epitaxial film (i.e., thickness over one micrometer) is the difficulty of keeping ultra high vacuum conditions in the presence of a sputter gas for a long time. Ultra high vacuum conditions are characterized by a low level of the partial pressure of any contaminating gasses present in the deposition chamber.

In U.S. Patent 3,811,794, a vacuum sublimation pump is described for use in the removal of contaminant gases from a chamber. To create pumping conditions, it is proposed to continuously form a titanium film that would absorb any contaminant gases. It is proposed to heat a titanium filament above its sublimation temperature in order to create the titanium film, but the film is deposited on the walls of the chamber . It has now been found that it is advantageous to remove contaminant gases from a film deposition chamber by providing a pump to remove contaminant gases within the chamber in which deposition occurs.

Brief Summary of the Invention

One embodiment of this invention is an apparatus for film deposition containing (a) a target for sputtering an epitaxial film, (b) a target for sputtering a pumping getter, and (c) a cryogenic shroud interposed between the epitaxial film target and the pumping getter target .

Various other embodiments of this invention are (a) an apparatus for creating a vacuum in a sputter deposition chamber containing a cylindrical, cryogenic pumping getter disposed within the sputter deposition chamber; (b) an apparatus for film deposition containing, within a single sputtering chamber, (i) a target for sputtering an epitaxial film, and (ii) a target for sputtering a pumping getter; (c) an apparatus for film deposition containing, within a single sputtering chamber, (i) a target, for sputtering an epitaxial film, that generates contaminants, and (ii) a shroud disposed about the epitaxial film target to reduce the concentration of contaminants within the chamber; and (d) an apparatus for film deposition containing (i) a target for sputtering an epitaxial film, (ii) a target for sputtering a pumping getter, and (iii) a pumping getter interposed between the epitaxial film target and the pumping getter target. The pumping getter may be cylindrical.

Various other embodiments of this invention are a method of depositing a film by the use of the apparatus of this invention, such as (a) a method of depositing a film by sputtering, in a single sputtering chamber, (i) an epitaxial film material onto a substrate, and (ii) a pumping getter material onto a pumping getter; (b) a method of reducing contamination in a sputtering chamber by sputtering pumping getter material onto a cryogenic pumping getter disposed within the sputter deposition chamber; or (c) a method of reducing contamination in a sputtering chamber by sputtering pumping getter material onto a pumping getter disposed between a target containing the pumping getter material and a target containing material for sputtering an epitaxial film.

Brief Description of the Drawings

Fig. 1 is a cross sectional view of a film deposition device.

Detailed Description of the Invention

This invention provides an improved approach for growing high quality thick epilayers using sputtering. This method is particularly useful in the situation in which the sputtering process time is so long that the pumping speed of an ultra high vacuum pump could change while sputtering is on-going. Instead of using a sublimation process, or a roughing pump (which reduces pressure to about 10^"3 Torr) , or a thermal molecular pump (which reduces pressure to about 10^"7 to about 10^"9 Torr) , a sputtering process is used in this invention. This approach of this invention typically reduces pressure to about 10^"11 to about 10^"12 Torr. Specifically, a film of a reactive material (a pumping getter) is formed using a sputtering process. The gas used to sputter the getter may be the same as the gas also used to sputter a desired product such as an epitaxial film. A typical example of such gas is argon . In this invention, a sputtering process for growing an epitaxial film and a separate sputtering process for creating a film for a pumping getter are provided in the same sputtering chamber. A sputtering chamber is therefore proved herein that includes two sputtering sources. As shown in Fig. 1, the first sputtering source 2 is for the sputtering of an epitaxial film. The second sputtering source 4 is for the sputtering of reactive materials, such as titanium chromium or titanium-molybdenum, to create a getter. The first sputtering source and substrate 6 are surrounded by a cryogenic shroud 8, such as a shroud cooled by liquid nitrogen or helium. The second sputtering source is mounted outside of the cryogenic shroud. During the deposition of epitaxial film material, the reactive material, functioning as a pumping getter, effectively absorbs contaminant gases such as H₂, N₂, CO, C0₂, water vapor and the like. As a result of the significantly lower levels of these reactive, contaminant gases being present during film deposition according to the invention, the purity and overall quality of epitaxial films deposited is substantially higher (relative to otherwise similar films produced by other or prior art processes) . The pumping speed of the getter film, which may be sputtered simultaneously with the epitaxial film, is substantially constant .

The cryogenic shroud is typically a stainless steel cylinder, filled with a coolant such as liquid nitrogen, that is open on the ends. Contaminant gases may flow out of the open ends. Shields protect the open ends and prevent penetration of the sputtered getter material from entering the space enclosed by the interior of the cylindrically-shaped shroud. The ionized sputtering gas that is utilized to sputter an epitaxial film within the shroud creates a high gas pressure on the inside compared with the outside. This condition also helps prevent the sputtered getter material from penetrating inside the shroud and contaminating the epitaxial film.

The sputtering chamber of this device includes two sputtering sources . The first sputtering source is for the sputtering of an epitaxial film. The second sputtering source is for the sputtering of reactive materials such as titanium to create getters. This is the getter pump. The sputtering source for the getter material deposition might be a typical RF (radio frequency) diode sputtering source, or AC, such as at about 13.56 MHz. The getter target thickness must be large enough to provide continuous and simultaneous sputtering of the getter material during the sputtering of the epitaxial film.

The first sputtering source and the substrate are surrounded by a cryogenic shroud, such as a liquid nitrogen shroud. The second sputtering source is mounted outside of the cryogenic shroud. The sputtering of said getter occurs on the outside surface of the cryogenic shroud. During the process of depositing an epitaxial film, the getter effectively absorbs reactive, contaminant gases such as H₂, N₂, CO, C0₂, and water vapor that affect the quality of the growing epilayer. A set of shields prevents penetration of the getter material atoms inside the cryogenic shroud, and helps keep the growing epitaxial film free of getter material contamination. The ionized sputtering gas that is utilized to sputter an epitaxial film within the shroud creates a high gas pressure on the inside compared with the outside. This condition also helps prevent the sputtered getter material from penetrating inside the shroud and contaminating the epitaxial film. In this invention, the first sputtering source 2 and the second sputtering source 4 are preferably, but not necessarily, oriented at approximately ninety degrees with respect to each other, as shown in Figure 1. This arrangement may be desirable inasmuch as the getter material typically deposits on the outside of the shroud, the epitaxial film material deposits on the substrate, the substrate is typically placed to be essentially perpendicular to the walls of the shroud.

In operation, this invention involves an apparatus for film deposition containing (a) a target for sputtering an epitaxial film, (b) a target for sputtering a pumping getter, and (c) a cryogenic shroud interposed between the epitaxial film target and the pumping getter target. In such an apparatus, the cryogenic shroud may be a pumping getter, or the pumping getter may be sputter deposited on the cryogenic shroud. The cryogenic shroud may be a metallic, cylindrically shaped vessel, and may be cooled by liquid nitrogen. The pumping getter target may be a ring, band, coil or collar disposed about the cryogenic shroud, and the material of the pumping getter target may be titanium. The epitaxial film target and the pumping getter target may be located in a single sputtering chamber, and the epitaxial film may have a thickness of greater than one micrometer.

In other embodiments, the invention provides (a) an apparatus for creating a vacuum in a sputter deposition chamber containing a cylindrical, cryogenic pumping getter disposed within the sputter deposition chamber; (b) an apparatus for film deposition containing, within a single sputtering chamber, (i) a target for sputtering an epitaxial film, and (ii) a target for sputtering a pumping getter; (c) an apparatus for film deposition containing, within a single sputtering chamber, (i) a target, for sputtering an epitaxial film, that generates contaminants, and (ii) a shroud disposed about the epitaxial film target to reduce the concentration of contaminants within the chamber; or (d) an apparatus for film deposition containing (i) a target for sputtering an epitaxial film, (ii) a target for sputtering a pumping getter, and (iii) a pumping getter interposed between the epitaxial film target and the pumping getter target. The pumping getter may be cylindrical.

The invention also provides a method of depositing a film by the use of the apparatus of this invention, such as (a) a method of depositing a film by sputtering, in a single sputtering chamber, (i) an epitaxial film material onto a substrate, and (ii) a pumping getter material onto a pumping getter; (b) a method of reducing contamination in a sputtering chamber by sputtering pumping getter material onto a cryogenic pumping getter disposed within the sputter deposition chamber; or (c) a method of reducing contamination in a sputtering chamber by sputtering pumping getter material onto a pumping getter disposed between a target containing the pumping getter material and a target containing material for sputtering an epitaxial film.

In these methods, the epitaxial film and pumping getter may be sputtered simultaneously, and the deposition may occur for at least one hour.

Claims

ClaimsWhat is claimed is:

1. An apparatus for film deposition comprising (a) a target for sputtering an epitaxial film, (b) a target for sputtering a pumping getter, and (c) a cryogenic shroud interposed between the epitaxial film target and the pumping getter target.

2. An apparatus according to Claim 1 wherein the cryogenic shroud comprises a pumping getter.

3. An apparatus according to Claim 1 wherein the pumping getter is sputter deposited on the cryogenic shroud.

4. An apparatus according to Claim 1 wherein the cryogenic shroud comprises a metallic, cylindrically shaped vessel.

5. An apparatus according to Claim 1 wherein the pumping getter target is a ring, band, coil or collar disposed about the cryogenic shroud.

6. An apparatus according to Claim 1 wherein the pumping getter target comprises titanium.

7. An apparatus according to Claim 1 wherein the cryogenic shroud is cooled by liquid nitrogen.

8. An apparatus according to Claim 1 wherein the epitaxial film target and the pumping getter target are located in a single sputtering chamber.

9. An apparatus according to Claim 1 wherein the epitaxial film has a thickness of greater than one micrometer.

10. An apparatus for creating a vacuum in a sputter deposition chamber comprising a cylindrical, cryogenic pumping getter disposed within the sputter deposition chamber.

11. An apparatus for film deposition comprising, within a single sputtering chamber, (a) a target for sputtering an epitaxial film, and (b) a target for sputtering a pumping getter.

12. An apparatus for film deposition comprising, within a single sputtering chamber, (a) a target, for sputtering an epitaxial film, that generates contaminants, and (b) a shroud disposed about the epitaxial film target to reduce the concentration of contaminants within the chamber.

13. An apparatus for film deposition comprising (a) a target for sputtering an epitaxial film, (b) a target for sputtering a pumping getter, and (c) a pumping getter interposed between the epitaxial film target and the pumping getter target .

14. An apparatus according to Claim 13 wherein the pumping getter is cylindrical.

15. A method of depositing a film comprising sputtering, in a single sputtering chamber, (a) an epitaxial film material onto a substrate, and (b) a pumping getter material onto a pumping getter.

16. A method according to Claim 15 wherein the deposition occurs for at least one hour.

17. A method according to Claim 15 wherein the epitaxial film and pumping getter are sputtered simultaneously.

18. A method of reducing contamination in a sputtering chamber comprising sputtering pumping getter material onto a cryogenic pumping getter disposed within the sputter deposition chamber.

19. A method according to Claim 18 wherein the pumping getter material is sputtered simultaneously with the sputtering of an epitaxial film material .

20. A method of reducing contamination in a sputtering chamber comprising sputtering pumping getter material onto a pumping getter disposed between a target containing the pumping getter material and a target containing material for sputtering an epitaxial film.

21. A method according to Claim 20 wherein the pumping getter material is sputtered simultaneously with the sputtering of the epitaxial film material.

22. A method of depositing an epitaxial film comprising sputtering the film with the apparatus of Claim 1.