Single-phase (Hf0.84Ta0.16)C solid solution nanowires growth via catalyst-assisted chemical vapor deposition

Hui Chen; Yulei Zhang; Yanqin Fu; Jian Zhang; Kang Shuai

doi:10.1111/jace.18747

Single-phase (Hf_0.84Ta_0.16)C solid solution nanowires growth via catalyst-assisted chemical vapor deposition

Hui Chen, Yulei Zhang, Yanqin Fu, Jian Zhang, Kang Shuai

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

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

6 Scopus citations

Abstract

Fabricating one-dimensional (1D) ceramic nanostructure with superior performance is an important approach to broaden their applications. In this paper, the synthesis of single-phase (Hf_0.84Ta_0.16)C solid solution nanowires via catalyst-assisted chemical vapor deposition was proposed for the first time. The [0 1 1̄] growth direction of (Hf_0.84Ta_0.16)C solid solution nanowires was discussed in detail and its corresponding growth mechanism was identified to be top-type vapor–liquid–solid mechanism. More impressively, our work could widen the application ranges of ceramic nanowires and propose the new thinking of fabricating ultrahigh melting point nanostructure.

Original language	English
Pages (from-to)	689-698
Number of pages	10
Journal	Journal of the American Ceramic Society
Volume	106
Issue number	1
DOIs	https://doi.org/10.1111/jace.18747
State	Published - Jan 2023

Keywords

(HfTa)C solid solution nanowires
CVD
solid solution
VLS mechanism

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abstract = "Fabricating one-dimensional (1D) ceramic nanostructure with superior performance is an important approach to broaden their applications. In this paper, the synthesis of single-phase (Hf0.84Ta0.16)C solid solution nanowires via catalyst-assisted chemical vapor deposition was proposed for the first time. The [0 1 {\=1}] growth direction of (Hf0.84Ta0.16)C solid solution nanowires was discussed in detail and its corresponding growth mechanism was identified to be top-type vapor–liquid–solid mechanism. More impressively, our work could widen the application ranges of ceramic nanowires and propose the new thinking of fabricating ultrahigh melting point nanostructure.",

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AU - Chen, Hui

AU - Zhang, Yulei

AU - Fu, Yanqin

AU - Zhang, Jian

AU - Shuai, Kang

PY - 2023/1

Y1 - 2023/1

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AB - Fabricating one-dimensional (1D) ceramic nanostructure with superior performance is an important approach to broaden their applications. In this paper, the synthesis of single-phase (Hf0.84Ta0.16)C solid solution nanowires via catalyst-assisted chemical vapor deposition was proposed for the first time. The [0 1 1̄] growth direction of (Hf0.84Ta0.16)C solid solution nanowires was discussed in detail and its corresponding growth mechanism was identified to be top-type vapor–liquid–solid mechanism. More impressively, our work could widen the application ranges of ceramic nanowires and propose the new thinking of fabricating ultrahigh melting point nanostructure.

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Single-phase (Hf_0.84Ta_0.16)C solid solution nanowires growth via catalyst-assisted chemical vapor deposition

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Keywords

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