High-purity β-sic powder for the single-crystal growth of SiC

Eunjin Jung; Yoon Joo Lee; Soo Ryong Kim; Woo Teck Kwon; Jun Kyu Kim; Doo Jin Choi; Younghee Kim

High-purity β-sic powder for the single-crystal growth of SiC

Eunjin Jung, Yoon Joo Lee, Soo Ryong Kim, Woo Teck Kwon, Jun Kyu Kim, Doo Jin Choi, Younghee Kim

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

High-purity β-SiC powder suitable for growing SiC single crystals was successfully synthesized from sol-gel precursors by carbothermal reduction. This was achieved through a two or three stage process that incorporated initial gasification, followed by gas phase reaction. To minimize the high loss that is typical of this process, and caused by the rate of evaporation in being faster than the gas phase reaction speed, the chemical structure of the precursor and heat treatment process were optimized. This found that a combination of tetraethyl orthosilicate and trimethyl phenylsilicate precursors, and a two-stage heat treatment, increases the production yield from 49.0% up to 84.4%. Furthermore, the purity of the β-SiC was also increased to 99.7%, with a metallic impurity content of just 130 ppm.

Original language	English
Pages (from-to)	447-450
Number of pages	4
Journal	Journal of Ceramic Processing Research
Volume	15
Issue number	6
Publication status	Published - 2014

Bibliographical note

Publisher Copyright:
© 2014, Journal of Ceramic Processing Research. All rights reserved.

All Science Journal Classification (ASJC) codes

Ceramics and Composites

Cite this

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title = "High-purity β-sic powder for the single-crystal growth of SiC",

abstract = "High-purity β-SiC powder suitable for growing SiC single crystals was successfully synthesized from sol-gel precursors by carbothermal reduction. This was achieved through a two or three stage process that incorporated initial gasification, followed by gas phase reaction. To minimize the high loss that is typical of this process, and caused by the rate of evaporation in being faster than the gas phase reaction speed, the chemical structure of the precursor and heat treatment process were optimized. This found that a combination of tetraethyl orthosilicate and trimethyl phenylsilicate precursors, and a two-stage heat treatment, increases the production yield from 49.0% up to 84.4%. Furthermore, the purity of the β-SiC was also increased to 99.7%, with a metallic impurity content of just 130 ppm.",

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AU - Jung, Eunjin

AU - Lee, Yoon Joo

AU - Kim, Soo Ryong

AU - Kwon, Woo Teck

AU - Kim, Jun Kyu

AU - Choi, Doo Jin

AU - Kim, Younghee

PY - 2014

Y1 - 2014

N2 - High-purity β-SiC powder suitable for growing SiC single crystals was successfully synthesized from sol-gel precursors by carbothermal reduction. This was achieved through a two or three stage process that incorporated initial gasification, followed by gas phase reaction. To minimize the high loss that is typical of this process, and caused by the rate of evaporation in being faster than the gas phase reaction speed, the chemical structure of the precursor and heat treatment process were optimized. This found that a combination of tetraethyl orthosilicate and trimethyl phenylsilicate precursors, and a two-stage heat treatment, increases the production yield from 49.0% up to 84.4%. Furthermore, the purity of the β-SiC was also increased to 99.7%, with a metallic impurity content of just 130 ppm.

AB - High-purity β-SiC powder suitable for growing SiC single crystals was successfully synthesized from sol-gel precursors by carbothermal reduction. This was achieved through a two or three stage process that incorporated initial gasification, followed by gas phase reaction. To minimize the high loss that is typical of this process, and caused by the rate of evaporation in being faster than the gas phase reaction speed, the chemical structure of the precursor and heat treatment process were optimized. This found that a combination of tetraethyl orthosilicate and trimethyl phenylsilicate precursors, and a two-stage heat treatment, increases the production yield from 49.0% up to 84.4%. Furthermore, the purity of the β-SiC was also increased to 99.7%, with a metallic impurity content of just 130 ppm.

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High-purity β-sic powder for the single-crystal growth of SiC

Abstract

Bibliographical note

All Science Journal Classification (ASJC) codes

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