反钝角晶 c-Na3HS 固态电解质的第一原理见解

arXiv - PHYS - Materials Science Pub Date : 2024-09-15 DOI:arxiv-2409.09690

Sananya Chakraborty, Nidhi Verma, Ashok Kumar

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摘要

我们探索了新型反钝角晶c-Na3HS作为钠离子电池固态电解质的潜力。为了研究 c-Na3HS 的动力学稳定性、相稳定性、热稳定性、机械稳定性以及离子、电子和扩散特性，我们采用了基于密度泛函理论（DFT）和非原位分子动力学（AIMD）模拟的第一性原理方法。研究的主要发现包括：壳上能量小、带隙宽达 4.35 eV 以及机械稳定性分析表明 c-Na3HS 具有中等硬度和轻微脆性。根据计算，c-Na3HS 中 Na 的活化能约为 300 meV，而在引入 Na 空性后，活化能将降至约 100 meV。通过在 Na3HS 结构中掺入空位和卤素，离子导电性可提高约 3 个数量级。因此，所得结果表明，c-Na3HS 可以作为钠离子电池的固态电解质。

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First Principles Insight into Antiperovskite c-Na3HS Solid State Electrolyte

We explore the potential of novel antiperovskite c-Na3HS to be a solid-state electrolyte for sodium-ion batteries. To investigate the dynamical stability, phase stability, thermal stability, mechanical stability and ionic, electronic and diffusive properties of c-Na3HS, the first-principles methods based on density functional theory (DFT) and ab-initio molecular dynamics (AIMD) simulations have been employed. c-Na3HS has no imaginary phonon modes indicating its dynamical stability. Key findings include small energy-above-hull, the wide band gap of 4.35 eV and mechanical stability analysis that indicates the moderately hard and a little brittle nature of c-Na3HS. The activation energy of Na in c-Na3HS is calculated to be ~300 meV that reduces to ~ 100 meV on introducing Na-vacancy. The ionic conductivity can be enhanced up to ~3 order of magnitude by vacancy and halogen doping in c-Na3HS structure. Thus, the obtained results indicate that c-Na3HS can be viable option to be utilized as solid-state electrolyte in sodium-ion batteries.

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arXiv - PHYS - Materials Science

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