Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-23T09:24:05.802Z Has data issue: false hasContentIssue false
  • English
  • Français

Recent Developments in SiC Homoepitaxy Using Dichlorosilane for High Power Devices

Published online by Cambridge University Press:  01 February 2011

Iftekhar Chowdhury ,
MVS Chandrasekhar ,
Paul B Klein ,
Joshua D Caldwell  and
Tangali Sudarshan
Iftekhar Chowdhury
Affiliation:
[email protected], University of South Carolina, Electrical Engineering, Columbia, South Carolina, United States
MVS Chandrasekhar
Affiliation:
[email protected], University of South Carolina, Electrical Engineering, Columbia, South Carolina, United States
Paul B Klein
Affiliation:
[email protected], Naval Research Laboratory, Washington, District of Columbia, United States
Joshua D Caldwell
Affiliation:
[email protected]@gmail.com, Naval Research Laboratory, Washington, District of Columbia, United States
Tangali Sudarshan
Affiliation:
[email protected], University of South Carolina, Electrical Engineering, Columbia, South Carolina, United States
Get access

Abstract

Thick and high quality 4H-SiC epilayers have been grown in a vertical hot-wall chemical vapor deposition system at a high growth rate on (0001) 8 0 off-axis substrates. We discuss the use of dichlorosilane as the Si-precursor for 4H-SiC epitaxial growth as it provides the most direct decomposition route into SiCl 2, which is the predominant growth species in chlorinated chemistries. The RMS roughness of the films ranged from 0.5-2.0 nm with very few morphological defects (carrots, triangular defects, etc.) being introduced, while enabling growth rates of 30-100 μm/hr, 5-15 times higher than most conventional growths. A specular surface morphology was attained by limiting the hydrogen etch rate until the system was equilibrated at the desired growth temperature. Site-competition epitaxy was observed over a wide range of C/Si ratios, with doping concentrations as low as 2x10 14 cm -3 being recorded. X-ray rocking curves indicated that the epilayers were of high crystallinity, with linewidths as narrow as 7.8 arcsec being observed, while microwave photoconductive decay (μPCD) measurements indicated that these films had high injection (ambipolar) carrier lifetimes in the range of 2 μs. These films also appeared to be free of polytype inclusions.

Keywords

chemical vapor deposition (CVD) (deposition)epitaxyelectronic material
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1246: Symposium B – Silicon Carbide 2010-Materials, Processing and Devices , 2010 , 1246-B04-06
Copyright
Copyright © Materials Research Society 2010

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

[1] Ryu, S.H. and Krishnaswami, S., IEEE Electron Device Letters 25, 556558 (2004).Google Scholar
[2] Zhao, J.H., Alexandrov, P., Zhang, J. and Li, X., IEEE Electron Device Letters 25, 474476 (2004).Google Scholar
[3] Das, M.K., Sumakeris, J.J., Hull, B.A., Richmond, J., Krishnaswami, S. and Powell, A.R., Materials Science Forum 483–485, 965968 (2005).Google Scholar
[4] Zhao, J.H., Alexandrov, P. and Li, X., IEEE Electron Device Letters 24, 402404 (2003).Google Scholar
[5] Via, F. la, Galvagno, G., Foti, G., Mauceri, M., Leone, S., Pistone, G., Abbondanza, G., Veneroni, A., Masi, M. and Valente, G.L., Chemical Vapor Deposition 12, 509515 (2006).Google Scholar
[6] Vorob'ev, A.N., Karpov, S.Y., Bord, O.V., Zhmakin, A.I., Lovtsus, A.A. and Makarov, Y.N., Diamond & Related Materials 9, 472475 (2000).Google Scholar
[7] Ito, M., Storasta, L., and Tsuchida, H., Applied Physics Express 1, 015001 (2008).Google Scholar
[8] Hori, T., Danno, K. and Kimoto, T., Journal of Crystal Growth 306, 297302 (2007).Google Scholar
[9] Crippa, D., Valente, G.L., Ruggiero, A., Neri, L., Reitano, R., Calcagno, L., Foti, G., Mauceri, M., Leone, S. and Pistone, G., Materials Science Forum 483–485, 6772 (2005).Google Scholar
[10] Koshka, Y., Lin, H. D., Melnychuk, G. and Wood, C., Journal of Crystal Growth 294, 260267 (2006).Google Scholar
[11] Aylward, G. and Findlay, T., SI Chemical data, 4th ed. (Wiley, 1998), p. 125.Google Scholar
[12] Myers, R., Kordina, O., Shishkin, Z., Rao, S., Everly, R. and Saddow, S.E., Materials Science Forum 483–485, 7376 (2005).Google Scholar
[13] Dhanaraj, G., Dudley, M., Chen, Y., Ragothamachar, B., Wu, B. and Zhang, H., Journal of Crystal Growth 287, 344348 (2006).Google Scholar
[14] Leone, S., Mauceri, M., Pistone, G., Abbondanza, G., Portuese, F., Abagnale, G., Valente, G.L., Crippa, D., Barbera, M., Reitano, R., Foti, G. and Via, F. la, Materials Science Forum 527–529, 179182 (2006).Google Scholar
[15] Macmillan, M.F., Loboda, M.J., Chung, G., Carlson, E. and Wan, J., Materials Science Forum 527–529, 175178 (2006).Google Scholar
[16] Valente, G., Cavallotti, C., Masi, M. and Carra, S., Journal of Crystal Growth 230, 247257 (2001).Google Scholar
[17] Su, M. and Schlegel, H.B., Journal of physical chemistry 97, 87328735 (1993).Google Scholar
[18] Arthur, N.L., Potzinger, P., Reimann, B. and Steenbergen, H.P., Journal of the Chemical Society, Faraday Transactions II 85, 14471463 (1989).Google Scholar
[19] Ellison, A., Zhang, J., Peterson, J., Henry, A., Wahab, Q., Bergman, J.P., Makarov, Y.N., Vorob'ev, A., Vehanen, A. and Janzén, E., Materials Science & Engineering B 61-62, 113120 (1999).Google Scholar
[20] Larkin, D.J., Neudeck, P.G., Powell, J.A. and Matus, L.G., Applied Physics Letters 65, 1659 (1994).Google Scholar
[21] Grosse, P., Basset, G., Calvat, C., Couchaud, M., Faure, C., Ferrand, B., Grange, Y., Anikin, M., Bluet, J.M., Chourou, K. and Madar, R., Materials Science & Engineering B 61-62, 5862 (1999).Google Scholar
[22] Zhang, J., Storasta, L., Bergman, J.P., Son, N.T. and Janzén, E., Journal of Applied Physics 93, 4708 (2003)Google Scholar
[23] Ghandhi, S.K. and Field, R.J., Journal of crystal growth 69, 619622 (1984).Google Scholar
[24] Kumagawa, M., Kuwabara, H. and Yamada, S., Japanese Journal of Applied Physics 8, 421428 (1969).Google Scholar
[25] Ellison, A., Zhang, J., Henry, A. and Janzen, E., Journal of Crystal Growth 236, 225238 (2002).Google Scholar
[26] Powell, J.A., Larkin, D.J. and Abel, P.B., Journal of Electronic Materials 24, 295301 (1995).Google Scholar
[27] Pedersen, H., Leone, S., Henry, A., Beyer, F.C., Darakchieva, V. and Janzén, E., Journal of Crystal Growth 307, 334340 (2007).Google Scholar
[28] Fujihira, K., Kimoto, T. and Matsunami, H., Applied Physics Letters 80, 1586 (2002).Google Scholar
[29] Klein, P.B., Journal of Applied Physics 103, 033702–14 (2008).Google Scholar
[30] Kimoto, T., Danno, K. and Suda, J., Physica Status Solidi (B) 245, 13271336 (2008).Google Scholar