Surface modification of carbon/carbon composites and in-situ grown SiC nanowires to enhance the thermal cycling performance of Si-Mo-Cr coating under parallel oxyacetylene torch

Jia Ping Zhang; Qian Gang Fu; Jun Ling Qu; Hua Shan Zhou; Ning Kun Liu

doi:10.1016/j.corsci.2016.06.007

Surface modification of carbon/carbon composites and in-situ grown SiC nanowires to enhance the thermal cycling performance of Si-Mo-Cr coating under parallel oxyacetylene torch

Jia Ping Zhang, Qian Gang Fu, Jun Ling Qu, Hua Shan Zhou, Ning Kun Liu

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

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

23 Scopus citations

Abstract

Before the preparation of Si-Mo-Cr coating, blasting treatment of C/C composites and in-situ grown SiC nanowires were performed. Compared with the coated C/C composites without SiC nanowires, the bonding strength of Si-Mo-Cr coating was increased by 5.7%, and the mass loss per unit area was reduced by 46.39% after 30 thermal cycles between 1600 °C and room temperature. The performance enhancement can be attributed to the improved bonding strength and the alleviation of mismatch of thermal expansion coefficient between C/C substrate and Si-Mo-Cr coating, thereby decreasing the thermal stress during thermal cycles between high and low temperatures.

Original language	English
Pages (from-to)	667-674
Number of pages	8
Journal	Corrosion Science
Volume	111
DOIs	https://doi.org/10.1016/j.corsci.2016.06.007
State	Published - 1 Oct 2016

Keywords

A. Ceramic matrix composites
B. SEM
C. High temperature corrosion

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10.1016/j.corsci.2016.06.007

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title = "Surface modification of carbon/carbon composites and in-situ grown SiC nanowires to enhance the thermal cycling performance of Si-Mo-Cr coating under parallel oxyacetylene torch",

abstract = "Before the preparation of Si-Mo-Cr coating, blasting treatment of C/C composites and in-situ grown SiC nanowires were performed. Compared with the coated C/C composites without SiC nanowires, the bonding strength of Si-Mo-Cr coating was increased by 5.7%, and the mass loss per unit area was reduced by 46.39% after 30 thermal cycles between 1600 °C and room temperature. The performance enhancement can be attributed to the improved bonding strength and the alleviation of mismatch of thermal expansion coefficient between C/C substrate and Si-Mo-Cr coating, thereby decreasing the thermal stress during thermal cycles between high and low temperatures.",

keywords = "A. Ceramic matrix composites, B. SEM, C. High temperature corrosion",

author = "Zhang, {Jia Ping} and Fu, {Qian Gang} and Qu, {Jun Ling} and Zhou, {Hua Shan} and Liu, {Ning Kun}",

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doi = "10.1016/j.corsci.2016.06.007",

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T1 - Surface modification of carbon/carbon composites and in-situ grown SiC nanowires to enhance the thermal cycling performance of Si-Mo-Cr coating under parallel oxyacetylene torch

AU - Zhang, Jia Ping

AU - Fu, Qian Gang

AU - Qu, Jun Ling

AU - Zhou, Hua Shan

AU - Liu, Ning Kun

PY - 2016/10/1

Y1 - 2016/10/1

N2 - Before the preparation of Si-Mo-Cr coating, blasting treatment of C/C composites and in-situ grown SiC nanowires were performed. Compared with the coated C/C composites without SiC nanowires, the bonding strength of Si-Mo-Cr coating was increased by 5.7%, and the mass loss per unit area was reduced by 46.39% after 30 thermal cycles between 1600 °C and room temperature. The performance enhancement can be attributed to the improved bonding strength and the alleviation of mismatch of thermal expansion coefficient between C/C substrate and Si-Mo-Cr coating, thereby decreasing the thermal stress during thermal cycles between high and low temperatures.

AB - Before the preparation of Si-Mo-Cr coating, blasting treatment of C/C composites and in-situ grown SiC nanowires were performed. Compared with the coated C/C composites without SiC nanowires, the bonding strength of Si-Mo-Cr coating was increased by 5.7%, and the mass loss per unit area was reduced by 46.39% after 30 thermal cycles between 1600 °C and room temperature. The performance enhancement can be attributed to the improved bonding strength and the alleviation of mismatch of thermal expansion coefficient between C/C substrate and Si-Mo-Cr coating, thereby decreasing the thermal stress during thermal cycles between high and low temperatures.

KW - A. Ceramic matrix composites

KW - B. SEM

KW - C. High temperature corrosion

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DO - 10.1016/j.corsci.2016.06.007

M3 - 文章

AN - SCOPUS:84983087096

SN - 0010-938X

VL - 111

SP - 667

EP - 674

JO - Corrosion Science

JF - Corrosion Science

ER -

Surface modification of carbon/carbon composites and in-situ grown SiC nanowires to enhance the thermal cycling performance of Si-Mo-Cr coating under parallel oxyacetylene torch

Abstract

Keywords

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