Atomic-scale studies of garnet-type Mg3Fe2Si3O12: Defect chemistry, diffusion and dopant properties

IF 5.4 Q2 CHEMISTRY, PHYSICAL

Journal of Power Sources Advances Pub Date : 2020-06-01 DOI:10.1016/j.powera.2020.100016

Navaratnarajah Kuganathan , Alexander Chroneos

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引用次数: 2

Abstract

Materials with low cost, environmentally benign, high structural stability and high Mg content are of considerable interest for the construction of rechargeable Mg-ion batteries. In the present study, atomistic simulations are used to provide insights into defect and diffusion properties of garnet type Mg₃Fe₂Si₃O₁₂. Calculations reveal that the Mg–Fe anti-site defect cluster (0.44 eV/defect) is the lowest energy intrinsic defect process. Three dimensional Mg-ion migration pathway with the activation energy of 2.19 eV suggests that Mg-ion diffusion in this material is slow. Favourable isovalent dopants are found to be Mn²⁺, Ga³⁺ and Ge⁴⁺ on the Mg, Fe and Si sites respectively. While the formation of Mg interstitials required for the capacity is facilitated by Al doping on the Si site, Mg vacancies needed for the vacancy assisted Mg-ion diffusion are enhanced by Ge doping on the Fe site. The electronic structures of favourable dopants are calculated and discussed using density functional theory.

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石榴石型Mg3Fe2Si3O12的原子尺度研究:缺陷化学、扩散和掺杂性能

低成本、环保、高结构稳定性和高镁含量的材料是构建可充电镁离子电池的重要研究方向。在本研究中，原子模拟被用于提供对石榴石型Mg3Fe2Si3O12的缺陷和扩散特性的见解。计算结果表明，Mg-Fe反位缺陷团簇(0.44 eV/defect)是能量最低的本构缺陷过程。三维mg离子迁移路径的活化能为2.19 eV，表明mg离子在该材料中的扩散较慢。在Mg、Fe和Si位点上，有利的同价掺杂剂分别是Mn2+、Ga3+和Ge4+。Al在Si位点上的掺杂促进了容量所需的Mg空位的形成，而Ge在Fe位点上的掺杂则增强了空位辅助Mg离子扩散所需的Mg空位。利用密度泛函理论对有利掺杂剂的电子结构进行了计算和讨论。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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