In Situ TEM Investigations of the Microstructural Changes and Radiation Tolerance in SiC Nanowhiskers Irradiated with He Ions at High Temperatures

AMI: Acta Materialia Pub Date : 2021-05-15 DOI:10.2139/ssrn.3674678

E. Aradi, J. Lewis-Fell, G. Greaves, Stephen E. Donnelly, J. Hinks

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引用次数: 6

Abstract

Abstract Using in-situ transmission electron microscopy (TEM) with ion irradiation, we investigated the microstructural changes in silicon carbide nanowhiskers (SiC NWs) which were used as a model system for nanoporous SiC. Irradiations were carried out using 6 keV He ions at temperatures between 500 and 1000°C and doses up to 20 dpa. These results are compared with the irradiation effects in SiC thin foils under the same conditions to establish differences in their response to radiation damage. The irradiation temperature played a significant role in the evolution of different microstructures; at 500°C, small defect clusters were observed in the NWs together with a segregation of carbon at the surface of the NWs mapped using energy-filtered TEM (EFTEM). At 800°C, small He bubbles (2–4 nm in diameter) were observed in the NW matrix while He platelets and bubble discs formed in the foils. At 1000°C, several changes were observed in the NWs including bubbles at twin boundaries, voids and oxygen-rich precipitates. The large surface area to volume ratio enhances defect recombination supressing the defect density in the SiC NWs compared to the foils indicating high radiation tolerance; however, elemental segregation and precipitation may limit its application in advanced nuclear reactors.

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高温下He离子辐照SiC纳米晶须组织变化及耐辐射性能的原位透射电镜研究

摘要采用离子辐照原位透射电子显微镜(TEM)研究了作为纳米多孔碳化硅模型体系的碳化硅纳米晶须(SiC NWs)的微观结构变化。使用6 keV He离子在500至1000°C的温度和高达20 dpa的剂量下进行辐照。将这些结果与相同条件下SiC薄膜的辐照效应进行比较，以确定其对辐射损伤的响应差异。辐照温度对不同显微结构的演化有显著影响;在500°C时，使用能量过滤透射电镜(EFTEM)在NWs表面观察到小的缺陷团簇和碳的偏析。在800℃时，在NW基体中观察到直径为2 ~ 4nm的He小气泡，薄片中形成He血小板和He气泡盘。在1000℃时，NWs中观察到一些变化，包括孪晶界的气泡、空洞和富氧沉淀。与高耐辐射箔相比，较大的表面积体积比增强了SiC NWs中的缺陷复合，抑制了缺陷密度;然而，元素偏析和析出可能限制其在先进核反应堆中的应用。

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AMI: Acta Materialia

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