预测的新型高压锂相。

Predicted novel high-pressure phases of lithium.

机构信息

State Key Laboratory of Superhard Materials, Jilin University, Changchun 130012, China.

出版信息

Phys Rev Lett. 2011 Jan 7;106(1):015503. doi: 10.1103/PhysRevLett.106.015503.

DOI:10.1103/PhysRevLett.106.015503

Abstract

Under high pressure, "simple" lithium (Li) exhibits complex structural behavior, and even experiences an unusual metal-to-semiconductor transition, leading to topics of interest in the structural polymorphs of dense Li. We here report two unexpected orthorhombic high-pressure structures Aba2-40 (40 atoms/cell, stable at 60-80 GPa) and Cmca-56 (56 atoms/cell, stable at 185-269 GPa), by using a newly developed particle swarm optimization technique on crystal structure prediction. The Aba2-40 having complex 4- and 8-atom layers stacked along the b axis is a semiconductor with a pronounced band gap >0.8 eV at 70 GPa originating from the core expulsion and localization of valence electrons in the voids of a crystal. We predict that a local trigonal planar structural motif adopted by Cmca-56 exists in a wide pressure range of 85-434 GPa, favorable for the weak metallicity.

摘要

在高压下，“简单”的锂（Li）表现出复杂的结构行为，甚至经历了不寻常的金属-半导体转变，这使得人们对高密度 Li 的结构多晶型产生了兴趣。我们在此通过对晶体结构预测使用新开发的粒子群优化技术，报告了两种意想不到的正交高压结构 Aba2-40（40 个原子/胞，在 60-80 GPa 稳定）和 Cmca-56（56 个原子/胞，在 185-269 GPa 稳定）。具有复杂的 4 原子层和 8 原子层沿 b 轴堆积的 Aba2-40 是一种半导体，在 70 GPa 时具有明显的带隙>0.8 eV，这源于核心排斥和价电子在晶体空隙中的局域化。我们预测 Cmca-56 采用的局部三角平面结构基元在 85-434 GPa 的宽压力范围内存在，有利于弱金属性。

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预测的新型高压锂相。

Predicted novel high-pressure phases of lithium.

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