Hostname: page-component-84b7d79bbc-l82ql Total loading time: 0 Render date: 2024-07-30T07:31:37.270Z Has data issue: false hasContentIssue false
  • English
  • Français

High Efficiency Heat Sinks from Polycrystalline Diamond Grown by CVD Method

Published online by Cambridge University Press:  01 February 2011

Oleg A. Voronov ,
Gary S. Tompa  and
Veronika Veress
Oleg A. Voronov
Affiliation:
Structured Materials Industries, Inc., R&D, 201 Circle Drive North, Unit 102/103, Piscataway, NJ, 08854, United States, 732-302-9274, 732-302-9275
Gary S. Tompa
Affiliation:
gstompa@aol.com, Diamond Materials Inc., 120 Centennial Ave., Piscataway, NJ, 08854, United States
Veronika Veress
Affiliation:
ovoronov@aol.com, Diamond Materials Inc., 120 Centennial Ave., Piscataway, NJ, 08854, United States
Get access

Abstract

While absolute power levels in microelectronic devices are relatively modest (a few tens to a few hundred watts), heat fluxes can be significant (through 50 W/cm2 in current electronic chips and up to 2000 W/cm2 in semiconductor lasers). Diamond heat sinks enable heat transfer rates well above what is possible with standard thermal management devices. We have fabricated heat sinks using diamond, which has the highest temperature thermal conductivity of any known material. Polycrystalline diamonds manufactured by chemical vapor deposition (CVD) are machined by laser and combined with metallic or ceramic tiles. Cooling by fluid flow through micro-channels enhances heat removal. These unique attributes make diamond based heat sinks prime contenders for the next generation of high heat load sinks. Such devices could be utilized for efficient cooling in a variety of applications requiring high heat transfer capability, including semiconductor lasers, microprocessors, multi-chip modules in computers, laser-diode arrays, radar systems, and high-flux optics, among other applications. This paper will review test designs, heat flux measuring system, and measured heat removal values.

Keywords

diamondchemical vapor deposition (CVD) (chemical reaction)thermal conductivity
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 956: Symposium J – Diamond Electronics—Fundamentals to Applications , 2006 , 0956-J08-04
Copyright
Copyright © Materials Research Society 2007

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. http://web.mit.edu/hmtl/www/papers/HANNEMANN.pdfGoogle Scholar
2. Zhimin, W. and Fah, C.K., The Optimum Thermal Design of Multichannel Heat Sinks, IEEE/CPMT Electronic Packaging Technology Conference (1997), p. 123 Google Scholar
3. http://tima.imag.fr/Conferences/therminic/Therminic02/Posters/KAzar.pdf; Advanced Thermal Solutions, Inc.Google Scholar
4. Voronov, O.A., Rakhmanina, A.V., Yakovlev, E.N., “High-purity Diamond Layers Growing on the Diamond Substratum by Using the Hydrocarbon Decomposition Reactions under High Pressure,” Diamond Materials PV 97–32, The Electrochemical Society, Inc. Pennington, NJ 08534, p.2024, 1997.Google Scholar
5. Voronov, O.A., Rakhmanina, A.V., “Nucleation of Diamond Crystals from the SP2 and SP3 Hydrocarbons Decomposed under High Pressure,” Diamond Materials PV97–32, The Electrochemical Society, Inc, Pennington, NJ 08534, p.1696, 1997.Google Scholar
6. Voronov, O.A., “Diamond Compacts,” Diamond Materials PV93–17, The Electrochemical Society, Inc, Pennington, NJ 08834, p.10181025, 1993;Google Scholar
7. Spitsyn, B.V., Derjaguin, B.V. USSR Author's Certificate of Invention No 339134, July 10, 1956;Google Scholar
8. Eversole, W.G., US Patent No 3030187 and No 3030188 July 23, 1958.Google Scholar
9. Thorpe, T.P., Snail, K.A., Vardiman, R.G., Smith, T., “Advances in Technique for High Temperature Homoepitaxial Growth of Diamond Using an Oxygen-Acetylene Torch,” Diamond Materials PV 93–17, The Electrochemical Society, Inc., Pennington, NJ 08834, p.468476, 1993.Google Scholar
10. Snail, K.A., Weimer, R.A., Thorpe, T.P. “Flame Process for the Growth of Large Diamond Crystals,” Diamond Materials PV 93–17, The Electrochemical Society, Inc., Pennington, NJ 08834, p.358364, 1993.Google Scholar
11. Bush, J.V., Dismukes, J.P. “Economics of CVD Diamond,” Diamond Materials PV 93–17, The Electrochemical Society, Inc., Pennington, NJ 08834, p.880891, 1993.Google Scholar
12. Spitsyn, B.V. “The Roads to Metastable Diamond Growth,” Diamond Materials PV 93–17, The Electrochemical Society, Inc., Pennington, NJ 08834, p.345350, 1993.Google Scholar
13. Fedoseev, D.V. “Pioneering Soviet Research on Diamond Growth from the Gas Phase,” Diamond Materials PV 93–17, The Electrochemical Society, Inc, Pennington, NJ 08834, p.341344, 1993 Google Scholar
14. Yakovlev, E.N., Voronov, O.A. “The Hydrogen Concentration for the graphite and diamond growth: CH4 as species, P = 10-3-5*10+3 MPa, T = 300−1000 K,” Diamond Materials PV 93–17, The Electrochemical Society, Inc., Pennington, NJ 08834, p.916, 1993 Google Scholar
15. Qu, W. and Mudawar, I., Inter Society Conference on Thermal Phenomena, IEEE, 2002.Google Scholar
16. http://widget.ecn.purdue.edu/∼CTRC/research/pumpTech.htmlGoogle Scholar