Compositionally complex carbide ceramics: A perspective on irradiation damage

Extensive experimental and computational studies have demonstrated outstanding physical and chemical properties of the novel materials of compositionally complex carbides (CCCs), enabling their promising applications in advanced fission and fusion energy systems. This perspective provides a comprehe...

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Veröffentlicht in:	Journal of applied physics 2024-05, Vol.135 (20)
Hauptverfasser:	Trinh, Lanh, Wang, Fei, Bawane, Kaustubh, Hattar, Khalid, Hua, Zilong, Malakkal, Linu, He, Lingfeng, Wadle, Luke, Lu, Yongfeng, Cui, Bai
Format:	Artikel
Sprache:	eng
Schlagworte:	Amorphization Ceramics Chemical properties Clusters Damage assessment Defects Extreme environments High entropy alloys High entropy carbide ceramics MATERIALS SCIENCE Phase stability Radiation damage Stainless steels Thermal conductivity Zirconium carbide
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container_title	Journal of applied physics
container_volume	135
creator	Trinh, Lanh Wang, Fei Bawane, Kaustubh Hattar, Khalid Hua, Zilong Malakkal, Linu He, Lingfeng Wadle, Luke Lu, Yongfeng Cui, Bai
description	Extensive experimental and computational studies have demonstrated outstanding physical and chemical properties of the novel materials of compositionally complex carbides (CCCs), enabling their promising applications in advanced fission and fusion energy systems. This perspective provides a comprehensive overview of radiation damage behavior reported in the literature to understand the fundamental mechanisms related to the impact of multi-principal metal components on phase stability, irradiation-induced defect clusters, irradiation hardening, and thermal conductivity of compositionally complex carbides. Several future research directions are recommended to critically evaluate the feasibility of designing and developing new ceramic materials for extreme environments using the transformative “multi-principal component” concept. Compared to the existing materials for nuclear applications including stainless steels, nickel alloys, ZrC, SiC, and potentially high-entropy alloys, as well as certain other compositionally complex ceramic families. CCCs appear to be more resistant to amorphization, growth of irradiation defect clusters, and void swelling.
doi_str_mv	10.1063/5.0202275
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subjects	Amorphization Ceramics Chemical properties Clusters Damage assessment Defects Extreme environments High entropy alloys High entropy carbide ceramics MATERIALS SCIENCE Phase stability Radiation damage Stainless steels Thermal conductivity Zirconium carbide
title	Compositionally complex carbide ceramics: A perspective on irradiation damage
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