Research Progress of High-entropy Carbide Ultra-high Temperature Ceramics

The development of high-speed flight technology has put forward an urgent demand for highperformance thermal structure materials. High-entropy carbides（HECs） ceramics are a fast-emerging family of materials that combine the excellent properties of high-entropy ceramics and ultra-high temperature cer...

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Veröffentlicht in:	Wu ji cai liao xue bao 2024-01, Vol.39 (6), p.591
Hauptverfasser:	CAI, Feiyan, NI, Dewei, DONG, Shaoming
Format:	Artikel
Sprache:	chi ; eng
Schlagworte:	Ablation Carbides Ceramics Entropy Fiber composites High temperature Mechanical properties Oxidation resistance Thermal resistance Thermodynamic properties Transition metals Ultrahigh temperature
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container_title	Wu ji cai liao xue bao
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creator	CAI, Feiyan NI, Dewei DONG, Shaoming
description	The development of high-speed flight technology has put forward an urgent demand for highperformance thermal structure materials. High-entropy carbides（HECs） ceramics are a fast-emerging family of materials that combine the excellent properties of high-entropy ceramics and ultra-high temperature ceramics. HECs have a broad application prospect in extreme service environments, which has received extensive attention from scholars in recent years. Compared with traditional ultra-high temperature carbides containing only one or two transition metal elements, HECs have a greater potential for development because of their improved comprehensive performance and greater designability of composition and properties. After successive exploration of HECs in recent years, researchers have obtained many interesting results, developed a variety of preparation methods, and gained comprehensive understanding of microstructure and properties. The basic theories and the laws on HECs obtained from experimental process are reviewed in this paper. Preparation methods of HECs including powders,blocks, coatings and films, as well as fiber-reinforced HECs-based composites are summarized. Research progress on the properties of HECs, such as the mechanical properties, thermal properties, and especially the oxidation and ablation resistance related to high-temperature applications, is reviewed and discussed. Finally, the scientific issues that need to be further explored in this area are emphasized, and the prospects are proposed.
doi_str_mv	10.15541/jim20230562
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High-entropy carbides（HECs） ceramics are a fast-emerging family of materials that combine the excellent properties of high-entropy ceramics and ultra-high temperature ceramics. HECs have a broad application prospect in extreme service environments, which has received extensive attention from scholars in recent years. Compared with traditional ultra-high temperature carbides containing only one or two transition metal elements, HECs have a greater potential for development because of their improved comprehensive performance and greater designability of composition and properties. After successive exploration of HECs in recent years, researchers have obtained many interesting results, developed a variety of preparation methods, and gained comprehensive understanding of microstructure and properties. The basic theories and the laws on HECs obtained from experimental process are reviewed in this paper. Preparation methods of HECs including powders,blocks, coatings and films, as well as fiber-reinforced HECs-based composites are summarized. Research progress on the properties of HECs, such as the mechanical properties, thermal properties, and especially the oxidation and ablation resistance related to high-temperature applications, is reviewed and discussed. 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High-entropy carbides（HECs） ceramics are a fast-emerging family of materials that combine the excellent properties of high-entropy ceramics and ultra-high temperature ceramics. HECs have a broad application prospect in extreme service environments, which has received extensive attention from scholars in recent years. Compared with traditional ultra-high temperature carbides containing only one or two transition metal elements, HECs have a greater potential for development because of their improved comprehensive performance and greater designability of composition and properties. After successive exploration of HECs in recent years, researchers have obtained many interesting results, developed a variety of preparation methods, and gained comprehensive understanding of microstructure and properties. The basic theories and the laws on HECs obtained from experimental process are reviewed in this paper. Preparation methods of HECs including powders,blocks, coatings and films, as well as fiber-reinforced HECs-based composites are summarized. Research progress on the properties of HECs, such as the mechanical properties, thermal properties, and especially the oxidation and ablation resistance related to high-temperature applications, is reviewed and discussed. 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High-entropy carbides（HECs） ceramics are a fast-emerging family of materials that combine the excellent properties of high-entropy ceramics and ultra-high temperature ceramics. HECs have a broad application prospect in extreme service environments, which has received extensive attention from scholars in recent years. Compared with traditional ultra-high temperature carbides containing only one or two transition metal elements, HECs have a greater potential for development because of their improved comprehensive performance and greater designability of composition and properties. After successive exploration of HECs in recent years, researchers have obtained many interesting results, developed a variety of preparation methods, and gained comprehensive understanding of microstructure and properties. The basic theories and the laws on HECs obtained from experimental process are reviewed in this paper. Preparation methods of HECs including powders,blocks, coatings and films, as well as fiber-reinforced HECs-based composites are summarized. Research progress on the properties of HECs, such as the mechanical properties, thermal properties, and especially the oxidation and ablation resistance related to high-temperature applications, is reviewed and discussed. Finally, the scientific issues that need to be further explored in this area are emphasized, and the prospects are proposed.</abstract><cop>Beijing</cop><pub>Chinese Academy of Sciences</pub><doi>10.15541/jim20230562</doi><oa>free_for_read</oa></addata></record>
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subjects	Ablation Carbides Ceramics Entropy Fiber composites High temperature Mechanical properties Oxidation resistance Thermal resistance Thermodynamic properties Transition metals Ultrahigh temperature
title	Research Progress of High-entropy Carbide Ultra-high Temperature Ceramics
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