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Sintering of Compacts from Nanocrystalline Diamonds Without Sintering Agent

Published online by Cambridge University Press:  10 February 2011

A. Witek
Affiliation:
High Pressure Research Center UNIPRESS, ul. Sokolowska 29, 01 142 Warsaw, Poland
B. Palosz
Affiliation:
High Pressure Research Center UNIPRESS, ul. Sokolowska 29, 01 142 Warsaw, Poland
S. Stel'Makh
Affiliation:
High Pressure Research Center UNIPRESS, ul. Sokolowska 29, 01 142 Warsaw, Poland
S. Gierlotka
Affiliation:
High Pressure Research Center UNIPRESS, ul. Sokolowska 29, 01 142 Warsaw, Poland
R. Pielaszek
Affiliation:
High Pressure Research Center UNIPRESS, ul. Sokolowska 29, 01 142 Warsaw, Poland
E. Ekimov
Affiliation:
Institute for High Pressure Physics, Russian Academy of Sciences, 142092 Troick, Russia
V. Filonenko
Affiliation:
Institute for High Pressure Physics, Russian Academy of Sciences, 142092 Troick, Russia
A. Gavriliuk
Affiliation:
Institute for High Pressure Physics, Russian Academy of Sciences, 142092 Troick, Russia
V. Gryaznov
Affiliation:
Institute for High Pressure Physics, Russian Academy of Sciences, 142092 Troick, Russia
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Abstract

Compacts of polycrystalline diamond were made in toroid-type high-pressure camera under the pressure of 8 GPa using temperatures between 800 to 2150°C without the use of additive components. Nanocrystalline commercial DALAN, and microcrystalline ASM diamond powders were used. The compacts were characterized by helium pycnometry, Vickers hardness measurements, X-ray diffraction and SEM methods.

The starting and sintered nanocrystalline grain compacts were found to have strongly one-dimensionally disordered cubic modification. The nanocrystalline powder had a bimodal grain size distribution function as determined from X-ray diffraction data and ab initio intensity calculations performed with the use of Debye functions. It was found that neither the grain size nor one-dimensional disordering change under high-pressure high-temperature conditions. There is a general tendency in a decrease of density of compacts with increase in the sintering temperature what resulting partly from graphitization above 1000–1200°C. The main factor which determines the density of the diamond compacts is closed porosity. Typically, the nanocrystalline diamond compacts sintered from 30 sec. to 6 min. have densities around 90% of the theoretical value. Their Vickers microhardness is 24 GPa and less.

Type
Research Article
Copyright
Copyright © Materials Research Society 1998

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References

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