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Oxidation Behaviors of C-ZrB_2-SiC Composite at 2100℃ in Air and O_2 被引量:1

Oxidation Behaviors of C-ZrB_2-SiC Composite at 2100℃ in Air and O_2
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摘要 The oxidation behaviors of graphite and ZrB2-SiC modified graphite composite were investigated at 2100℃ in1X105 Pa air and 0.2X105 Pa O2. The oxidation tests were conducted in an induction heating furnace. The oxidation of these two materials followed the linear rate law. The determined radius loss rates of graphite and C-ZrB2-Si C at 2100℃ were 2.18X10-2and 1.05X10-2%/s in 1X105 Pa air, and 3.23X10 2 and 2.21X10 2%/s in 0.2X105 Pa O2, respectively. The incorporation of ZrB2 and SiC decreased remarkably the oxidation rate of graphite because the oxide scale formed on the sample surface during oxidation helps in reducing the exposed surface area of the underneath substrate. In two different atmospheres with the same oxygen partial pressure, both graphite and ZrB2-SiC experienced more severe oxidation at 2100℃ in0.2X105 Pa O2than in 1X105 Pa air. The oxidation rate-controlling step for graphite and ZrB2-SiC was proposed to be the inward diffusion of oxygen through the boundary layer and through the pores in the oxide scale, respectively. A model based on diffusion theory was established to discuss the effect of the total gas pressure on their oxidation behaviors. The oxidation behaviors of graphite and ZrB2-SiC modified graphite composite were investigated at 2100℃ in1X105 Pa air and 0.2X105 Pa O2. The oxidation tests were conducted in an induction heating furnace. The oxidation of these two materials followed the linear rate law. The determined radius loss rates of graphite and C-ZrB2-Si C at 2100℃ were 2.18X10-2and 1.05X10-2%/s in 1X105 Pa air, and 3.23X10 2 and 2.21X10 2%/s in 0.2X105 Pa O2, respectively. The incorporation of ZrB2 and SiC decreased remarkably the oxidation rate of graphite because the oxide scale formed on the sample surface during oxidation helps in reducing the exposed surface area of the underneath substrate. In two different atmospheres with the same oxygen partial pressure, both graphite and ZrB2-SiC experienced more severe oxidation at 2100℃ in0.2X105 Pa O2than in 1X105 Pa air. The oxidation rate-controlling step for graphite and ZrB2-SiC was proposed to be the inward diffusion of oxygen through the boundary layer and through the pores in the oxide scale, respectively. A model based on diffusion theory was established to discuss the effect of the total gas pressure on their oxidation behaviors.
作者 Zhongwei Zhang Cewen Nan Jingjun Xu Zenghua Gao Meishuan Li Junshan Wang
机构地区 State Key Laboratory of New Ceramics & Fine Processing Science and Technology on Advanced Functional Composites Laboratory Institute of Metal Research
出处 《Journal of Materials Science & Technology》 SCIE EI CAS CSCD 2014年第12期1223-1229,共7页 材料科学技术(英文版)
基金 supported by the National Scientific Instrument and Equipment Development Project (No. 2011YQ14014504)
关键词 Graphite-based composite Ceramic particles Ultra-high temperature oxidation Oxide scale Oxidation mechanism Graphite-based composite Ceramic particles Ultra-high temperature oxidation Oxide scale Oxidation mechanism
分类号 TB332 [一般工业技术—材料科学与工程]
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参考文献24

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同被引文献14

  • 1李翠云,李辅安.碳/碳复合材料的应用研究进展[J].化工新型材料,2006,34(3):18-20. 被引量:59
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  • 10AIAA. Recent Developments in Ultra High Temperature Ceramics at NASA Ames[C]//Aiaa/Dlr/Dglr International Space Planes & Hypersonic Systems & Technologies Conference, 2009.

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Journal of Materials Science & Technology
2014年 第12期

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