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高压下的设计材料。

Materials by design at high pressures.

作者信息

Xu Meiling, Li Yinwei, Ma Yanming

机构信息

Laboratory of Quantum Functional Materials Design and Application, School of Physics and Electronic Engineering, Jiangsu Normal University Xuzhou 221116 China

State Key Laboratory of Superhard Materials & International Center for Computational Method and Software, College of Physics, Jilin University Changchun 130012 China

出版信息

Chem Sci. 2021 Dec 9;13(2):329-344. doi: 10.1039/d1sc04239d. eCollection 2022 Jan 5.

DOI:10.1039/d1sc04239d
PMID:35126967
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8729811/
Abstract

Pressure, a fundamental thermodynamic variable, can generate two essential effects on materials. First, pressure can create new high-pressure phases modification of the potential energy surface. Second, pressure can produce new compounds with unconventional stoichiometries modification of the compositional landscape. These new phases or compounds often exhibit exotic physical and chemical properties that are inaccessible at ambient pressure. Recent studies have established a broad scope for developing materials with specific desired properties under high pressure. Crystal structure prediction methods and first-principles calculations can be used to design materials and thus guide subsequent synthesis plans prior to any experimental work. A key example is the recent theory-initiated discovery of the record-breaking high-temperature superhydride superconductors HS and LaH with critical temperatures of 200 K and 260 K, respectively. This work summarizes and discusses recent progress in the theory-oriented discovery of new materials under high pressure, including hydrogen-rich superconductors, high-energy-density materials, inorganic electrides, and noble gas compounds. The discovery of the considered compounds involved substantial theoretical contributions. We address future challenges facing the design of materials at high pressure and provide perspectives on research directions with significant potential for future discoveries.

摘要

压力作为一个基本的热力学变量,可对材料产生两种重要影响。其一,压力能够创造新的高压相——改变势能面。其二,压力能够产生具有非常规化学计量比的新化合物——改变成分格局。这些新相或新化合物常常展现出在常压下无法获得的奇异物理和化学性质。近期研究为在高压下开发具有特定所需性质的材料开辟了广阔空间。晶体结构预测方法和第一性原理计算可用于设计材料,从而在任何实验工作之前指导后续的合成计划。一个关键例子是近期由理论引发的发现,即创纪录的高温超氢化物超导体HS和LaH,其临界温度分别为200K和260K。本文总结并讨论了在高压下以理论为导向发现新材料的近期进展,包括富氢超导体、高能量密度材料、无机电子化物和稀有气体化合物。所讨论化合物的发现涉及大量理论贡献。我们阐述了高压下材料设计面临的未来挑战,并展望了具有重大未来发现潜力的研究方向。

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