Large Area SiC Epitaxial Layer Growth in a Warm-Wall Planetary VPE Reactor-Reference-Cited by-同舟云学术

Large Area SiC Epitaxial Layer Growth in a Warm-Wall Planetary VPE Reactor

Published:2005-05 Issue: Volume:483-485 Page:137-140
ISSN:1662-9752
Container-title:Materials Science Forum
language:
Short-container-title:MSF

Author:

Burk Albert A.¹,O'Loughlin Michael J.¹,Paisley Michael J.²,Powell Adrian R.³,Brady M.F.³,Müller Stephan G.¹,Allen S.T.¹

Affiliation:

1. Cree, Incorporation

2. Cree Incorporation

3. Cree Research, Inc.

Abstract

Experimental results are presented for SiC epitaxial layer growths employing a largearea, 7x3-inch, warm-wall planetary SiC-VPE reactor. This high-throughput reactor has been optimized for the growth of uniform 0.01 to 30-micron thick, specular, device-quality SiC epitaxial layers with background doping concentrations of <1x1014 cm-3. Multi-layer device profiles such as Schottky, MESFETs, SITs, and BJTs with n-type doping from ~1x1015 cm-3 to >1x1019 cm-3, p-type doping from ~3x1015 cm-3 to >1x1020 cm-3, and abrupt doping transitions (~1 decade/nm) are regularly grown in continuous growth runs. Intrawafer layer thickness and n-type doping uniformities of <1% and <5% s/mean have been achieved. Within a run, wafer-to-wafer thickness and doping variation are ~±1% and ~±5% respectively. Long term run-to-run variations while under process control are approximately ~3% s/mean for thickness and ~5% s/mean for doping. Latest results from an even larger 6x4-inch (100-mm) reactor are also presented.

Publisher

Trans Tech Publications, Ltd.

Subject

Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics,General Materials Science

Link

https://www.scientific.net/MSF.483-485.137.pdf

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