Modeling Intercalation Chemistry with Multiredox Reactions by Sparse Lattice Models in Disordered Rocksalt Cathodes

PRX Energy Pub Date : 2023-10-09 DOI:10.1103/prxenergy.2.043005

Peichen Zhong, Fengyu Xie, Luis Barroso-Luque, Liliang Huang, Gerbrand Ceder

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Abstract

Modern battery materials can contain many elements with substantial site disorder, and their configurational state has been shown to be critical for their performance. The intercalation voltage profile is a critical parameter to evaluate the performance of energy storage. The application of commonly used cluster expansion techniques to model the intercalation thermodynamics of such systems from \textit{ab-initio} is challenged by the combinatorial increase in configurational degrees of freedom as the number of species grows. Such challenges necessitate efficient generation of lattice models without over-fitting and proper sampling of the configurational space under charge balance in ionic systems. In this work, we introduce a combined approach that addresses these challenges by (1) constructing a robust cluster-expansion Hamiltonian using the sparse regression technique, including $\ell_0\ell_2$-norm regularization and structural hierarchy; and (2) implementing semigrand-canonical Monte Carlo to sample charge-balanced ionic configurations using the table-exchange method and an ensemble-average approach. These techniques are applied to a disordered rocksalt oxyfluoride Li$_{1.3-x}$Mn$_{0.4}$Nb$_{0.3}$O$_{1.6}$F$_{0.4}$ (LMNOF) which is part of a family of promising earth-abundant cathode materials. The simulated voltage profile is found to be in good agreement with experimental data and particularly provides a clear demonstration of the Mn and oxygen contribution to the redox potential as a function of Li content.

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用稀疏晶格模型模拟无序岩盐阴极中多重氧化还原反应的插层化学

现代电池材料可以包含许多具有大量位置无序的元素，其构型状态已被证明对其性能至关重要。插层电压分布是评价储能系统性能的一个重要参数。随着物种数量的增加，构型自由度的组合增加对常用的簇展开技术从头开始模拟这类系统的插层热力学提出了挑战。这些挑战需要在没有过拟合的情况下高效地生成晶格模型，并在离子体系电荷平衡的要求下对构型空间进行适当的采样。在这项工作中，我们引入了一种解决这些挑战的组合方法:(1)使用稀疏回归技术构建一个鲁棒的聚类扩展哈密顿量，包括l2范数正则化和结构层次;(2)利用表交换法和系综平均方法实现半正则蒙特卡罗对电荷平衡离子构型的采样。这些技术应用于无序岩盐氧化氟Li1.3−xMn0.4Nb0.3O1.6F0.4 (LMNOF)，这是一个有前途的地球丰富的正极材料家族的一部分。模拟的电压分布与实验数据吻合良好，特别是清晰地证明了锰和氧对氧化还原电位的贡献是锂含量的函数。美国物理学会根据知识共享署名4.0国际许可协议，于2023年8月30日接受doi:https://doi.org/10.1103/PRXEnergy.2.043005Published。这项工作的进一步分发必须保持作者的归属和已发表文章的标题，期刊引用和DOI。发表于美国物理学会物理学科标题(PhySH)研究领域电池能量存储物理系统无序系统技术凝聚态中的簇扩张点阵模型蒙特卡罗方法统计物理与热力学能源科学与技术

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PRX Energy

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