Oxidation induced emissivity evolution of silicon carbide based thermal protection materials in hypersonic environments

Liping Liu; Lingwei Yang; Haojun Ma; Jie Luo; Xueren Xiao; Changhao Zhao; Jun Zhang; Guolin Wang; Yiguang Wang

doi:10.1080/21870764.2021.1999559

Oxidation induced emissivity evolution of silicon carbide based thermal protection materials in hypersonic environments

Liping Liu, Lingwei Yang^*, Haojun Ma, Jie Luo, Xueren Xiao, Changhao Zhao, Jun Zhang, Guolin Wang, Yiguang Wang

^*此作品的通讯作者

先进结构技术研究院

科研成果: 期刊稿件 › 文章 › 同行评审

8 引用（Scopus）

摘要

The emissivity of typical SiC-based thermal protection materials was measured in-situ at a wide temperature range (800 ~ 2300°C) inside a plasma wind tunnel that was capable of simulating hypersonic environments on-ground. Based on it, the evolution mechanism dominated by dynamic oxidation was discussed. The results suggest an emissivity of C_f/SiC 0.84 ~ 0.88 at 858 ~ 1502°C, prior to “temperature jump”. If “temperature jump” emerged, the emissivity was decreased rapidly to ≈0.76. The emissivity drop was explained by the microstructural transition of the oxidized surfaces that were triggered by the dissipation of SiO₂ oxide scale at 1600 ~ 1900°C. Similar emissivity evolution was observed in SiC_f/SiC after “temperature jump”. The effect of temperature on the emissivity of ZrB₂-SiC was more pronounced. It was increased from ≈0.73 to ≈0.98 at 1009 ~ 1297°C, and was plateaued at 1298 ~ 1497°C, ≈0.98. This was a consequence of the formation of higher percentage SiO₂-rich layers. However, due to the dissipation of SiO₂ and B₂O₃, the emissivity of ZrB₂-SiC was declined at higher temperatures, from ≈0.98 (≈1497°C) to ≈0.85 (≈1768°C).

源语言	英语
页（从-至）	1506-1515
页数	10
期刊	Journal of Asian Ceramic Societies
卷	9
期	4
DOI	https://doi.org/10.1080/21870764.2021.1999559
出版状态	已出版 - 2021

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Liu, L., Yang, L., Ma, H., Luo, J., Xiao, X., Zhao, C., Zhang, J., Wang, G., & Wang, Y. (2021). Oxidation induced emissivity evolution of silicon carbide based thermal protection materials in hypersonic environments. Journal of Asian Ceramic Societies, 9(4), 1506-1515. https://doi.org/10.1080/21870764.2021.1999559

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title = "Oxidation induced emissivity evolution of silicon carbide based thermal protection materials in hypersonic environments",

abstract = "The emissivity of typical SiC-based thermal protection materials was measured in-situ at a wide temperature range (800 ~ 2300°C) inside a plasma wind tunnel that was capable of simulating hypersonic environments on-ground. Based on it, the evolution mechanism dominated by dynamic oxidation was discussed. The results suggest an emissivity of Cf/SiC 0.84 ~ 0.88 at 858 ~ 1502°C, prior to “temperature jump”. If “temperature jump” emerged, the emissivity was decreased rapidly to ≈0.76. The emissivity drop was explained by the microstructural transition of the oxidized surfaces that were triggered by the dissipation of SiO2 oxide scale at 1600 ~ 1900°C. Similar emissivity evolution was observed in SiCf/SiC after “temperature jump”. The effect of temperature on the emissivity of ZrB2-SiC was more pronounced. It was increased from ≈0.73 to ≈0.98 at 1009 ~ 1297°C, and was plateaued at 1298 ~ 1497°C, ≈0.98. This was a consequence of the formation of higher percentage SiO2-rich layers. However, due to the dissipation of SiO2 and B2O3, the emissivity of ZrB2-SiC was declined at higher temperatures, from ≈0.98 (≈1497°C) to ≈0.85 (≈1768°C).",

keywords = "Emissivity, plasma wind tunnel, radiation property, thermal protection system",

author = "Liping Liu and Lingwei Yang and Haojun Ma and Jie Luo and Xueren Xiao and Changhao Zhao and Jun Zhang and Guolin Wang and Yiguang Wang",

note = "Publisher Copyright: {\textcopyright} 2021 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group on behalf of The Korean Ceramic Society and The Ceramic Society of Japan.",

year = "2021",

doi = "10.1080/21870764.2021.1999559",

language = "English",

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T1 - Oxidation induced emissivity evolution of silicon carbide based thermal protection materials in hypersonic environments

AU - Liu, Liping

AU - Yang, Lingwei

AU - Ma, Haojun

AU - Luo, Jie

AU - Xiao, Xueren

AU - Zhao, Changhao

AU - Zhang, Jun

AU - Wang, Guolin

AU - Wang, Yiguang

PY - 2021

Y1 - 2021

N2 - The emissivity of typical SiC-based thermal protection materials was measured in-situ at a wide temperature range (800 ~ 2300°C) inside a plasma wind tunnel that was capable of simulating hypersonic environments on-ground. Based on it, the evolution mechanism dominated by dynamic oxidation was discussed. The results suggest an emissivity of Cf/SiC 0.84 ~ 0.88 at 858 ~ 1502°C, prior to “temperature jump”. If “temperature jump” emerged, the emissivity was decreased rapidly to ≈0.76. The emissivity drop was explained by the microstructural transition of the oxidized surfaces that were triggered by the dissipation of SiO2 oxide scale at 1600 ~ 1900°C. Similar emissivity evolution was observed in SiCf/SiC after “temperature jump”. The effect of temperature on the emissivity of ZrB2-SiC was more pronounced. It was increased from ≈0.73 to ≈0.98 at 1009 ~ 1297°C, and was plateaued at 1298 ~ 1497°C, ≈0.98. This was a consequence of the formation of higher percentage SiO2-rich layers. However, due to the dissipation of SiO2 and B2O3, the emissivity of ZrB2-SiC was declined at higher temperatures, from ≈0.98 (≈1497°C) to ≈0.85 (≈1768°C).

AB - The emissivity of typical SiC-based thermal protection materials was measured in-situ at a wide temperature range (800 ~ 2300°C) inside a plasma wind tunnel that was capable of simulating hypersonic environments on-ground. Based on it, the evolution mechanism dominated by dynamic oxidation was discussed. The results suggest an emissivity of Cf/SiC 0.84 ~ 0.88 at 858 ~ 1502°C, prior to “temperature jump”. If “temperature jump” emerged, the emissivity was decreased rapidly to ≈0.76. The emissivity drop was explained by the microstructural transition of the oxidized surfaces that were triggered by the dissipation of SiO2 oxide scale at 1600 ~ 1900°C. Similar emissivity evolution was observed in SiCf/SiC after “temperature jump”. The effect of temperature on the emissivity of ZrB2-SiC was more pronounced. It was increased from ≈0.73 to ≈0.98 at 1009 ~ 1297°C, and was plateaued at 1298 ~ 1497°C, ≈0.98. This was a consequence of the formation of higher percentage SiO2-rich layers. However, due to the dissipation of SiO2 and B2O3, the emissivity of ZrB2-SiC was declined at higher temperatures, from ≈0.98 (≈1497°C) to ≈0.85 (≈1768°C).

KW - Emissivity

KW - plasma wind tunnel

KW - radiation property

KW - thermal protection system

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ER -

Oxidation induced emissivity evolution of silicon carbide based thermal protection materials in hypersonic environments

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