应用于极端环境的高熵陶瓷

T Z Ward, R P Wilkerson, B L Musicó, A Foley, M Brahlek, W J Weber, K E Sickafus, A R Mazza
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引用次数: 0

摘要

成分复杂的材料在极端环境下的结构坚固性表现出了非凡的前景。在这些材料中,最常见的是高熵合金,其复杂的化学性质赋予了材料非同寻常的硬度、延展性和热回弹性。与这些金属-金属键系统不同,离子键和共价键的加入导致了高熵陶瓷(HECs)的发现。这些材料同样具有出色的结构、热和化学坚固性,但其功能特性却更为多样,可实现连续可控的磁学、电子学和光学现象。在这个以实验为重点的视角中,我们概述了高熵碳化物在极端环境下的功能应用潜力,其固有的稳定性可能会为固有的硬化器件设计提供一条新的途径。我们回顾了目前在高熵碳化物、含锕系元素陶瓷和高熵氧化物方面所做的工作,这些材料在耐辐射、耐高温和耐腐蚀性方面的作用表明,局部无序性为实现自愈和结构稳健性提供了途径。在此背景下,概述了创建可在恶劣环境中运行的未来电子、磁性和光学设备的新策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
High entropy ceramics for applications in extreme environments
Compositionally complex materials have demonstrated extraordinary promise for structural robustness in extreme environments. Of these, the most commonly thought of are high entropy alloys, where chemical complexity grants uncommon combinations of hardness, ductility, and thermal resilience. In contrast to these metal–metal bonded systems, the addition of ionic and covalent bonding has led to the discovery of high entropy ceramics (HECs). These materials also possess outstanding structural, thermal, and chemical robustness but with a far greater variety of functional properties which enable access to continuously controllable magnetic, electronic, and optical phenomena. In this experimentally focused perspective, we outline the potential for HECs in functional applications under extreme environments, where intrinsic stability may provide a new path toward inherently hardened device design. Current works on high entropy carbides, actinide bearing ceramics, and high entropy oxides are reviewed in the areas of radiation, high temperature, and corrosion tolerance where the role of local disorder is shown to create pathways toward self-healing and structural robustness. In this context, new strategies for creating future electronic, magnetic, and optical devices to be operated in harsh environments are outlined.
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