Hostname: page-component-78c5997874-v9fdk Total loading time: 0 Render date: 2024-11-17T17:58:16.809Z Has data issue: false hasContentIssue false
  • English
  • Français

Metallizing and Die Attaching to Cvd Diamond

Published online by Cambridge University Press:  25 February 2011

CD Iacovangelo ,
PJ DiConza ,
EC Jerabek  and
KP Zarnoch
CD Iacovangelo
Affiliation:
Chemical Process Technology Laboratory GE Corp. R&D Center, Schenectady N.Y. 12301
PJ DiConza
Affiliation:
Chemical Process Technology Laboratory GE Corp. R&D Center, Schenectady N.Y. 12301
EC Jerabek
Affiliation:
Chemical Process Technology Laboratory GE Corp. R&D Center, Schenectady N.Y. 12301
KP Zarnoch
Affiliation:
Chemical Process Technology Laboratory GE Corp. R&D Center, Schenectady N.Y. 12301
Get access

Abstract

The high thermal conductivity of diamond (four times that of copper) and its low dielectric constant (less than alumina or aluminum nitride) makes it a desirable material for electronic substrates. The advent of CVD methods for depositing diamond in large areas at reasonable cost has spurred numerous applications for metallized CVDD. This paper describes several processes developed to provide reliable and stable metallization on CVDD including bond coats, diffusion barriers, vias, and solder die attach. Transition metals were found to provide well-adhered bond coats through carbide formation at the metal/CVDD interface. XPS depth profiles and conductivity measurements of three metallization systems: Ti/Pt/Au, WTi/Au, and Nb/Au after various heat treatments show WTi/Au to be the most stable system. Via filling was accomplished by LPCVD-W and electrolytic Cu for high and low aspect ratio holes respectively. The low thermal expansion coefficient of CVDD, -1.5 ppm/°C, presents a major challenge for reliable die attach of GaAs (5.85 ppm/°C). A novel concept for a compliant interface on CVDD which can overcome this problem will be presented.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 337: Symposium B – Advanced Metallization for Devices and Circuits—Science, Technology and Manufacturing III , 1994 , 401
Copyright
Copyright © Materials Research Society 1994

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

REFERENCES

1 AT&T, “The world's first commercial application of a novel synthetic diamond material combined with an advanced metallization bonding technique”, Wall Street Journal, B9 (October 13,1992).Google Scholar
2 General Electric,“Development of Free Standing Diamond Manufacturing Tecnology for Thermal Management Substrates”, ARPA #N00014-91-C-2167.Google Scholar
3 Eden, R.C. “Applicability of Diamond Substrates to Multi-Chip Modules”, (Intl. Soc Microelectronics Proceedings, 1, 1991) pp. 363367.Google Scholar
4 Iacovangelo, CD, EC, Jerabek, “Metallizing CVD Diamond for Electronic Substrates,” (Intl. Soc. Microelectronics Proceedings, Dallas, Texas, 1993) pp. 132137.Google Scholar
5 Park, D.S., U..S Patent No. 4,664,991, (1967).Google Scholar
6 Lee, C.H. et al. , J. Appl. Phys. 72 (8), 38083815, (1992).Google Scholar
7 Doyle, BL et al. , J. Appl. Phys. 53(9), 61866190, (1982).CrossRefGoogle Scholar
8 Oparowski, JM, RD, Sisson, RR, Biederman, Thin Solid Films, 153, 313328, (1987).Google Scholar
9 Nowicki, R.S., et al. , Thin Solid Films, 53, 195205, (1978).Google Scholar
10 Iacovangeo, CD, EC, Jerabek, RH, Wilson, GE Pat. Appl. RD23,427, (Accepted 1993).Google Scholar
11 IacovangeIo, CD,“Ceramic Metallization Using Molten Salt and Electroless Plating,” Plating and Surface Finishing, 1, 5459, (1994).Google Scholar
12 Iacovangelo, CD, US Patent No. 5,198,265, (1993).Google Scholar
13 Wilson, RH RW, Stoll, Symp on Multilevel Interconnects and Contact Tech. edited by Rothman&Herndon, , J. Electrochem. Soc., 87.9, Pennington NJ, (1987). p232.Google Scholar
14 Pipkin, NJ, US Patent No. 4,399,167 (August 16, 1983).Google Scholar
15 Wiand, RC, US Patent No. 4,776,862 (October 11, 1988).Google Scholar
16 Slutz, D, US Patent No. 4,931,363, (June 5, 1990).Google Scholar
17 Katz, A. et al. ,Materials Chemistry and Physics, 33, 281288, (1993).Google Scholar
18 Iacovangelo, CD, RA, Fillion, Wm, Burgess, GE Pat. Appl.RD22,320, (Accepted 1993).Google Scholar