First-principles calculations on LaX3 (X: Sb, Sn) as electrode material for lithium-ion batteries

Energy Storage Pub Date : 2024-05-28 DOI:10.1002/est2.657
Neha Sharma, Sadhana Matth, Raghavendra Pal, Himanshu Pandey
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Abstract

Using first-principle calculations, we investigate the rare-earth intermetallic compound LaX3 (X = Sb and Sn) as a cathode material for rechargeable lithium-ion batteries (LIBs). The calculations have been performed to look into the stability of the structure and the electronic properties of host LaX3 as well as its lithiated phases, LixLa1−xX3 (0 < x ≤ 1). In this study, we have observed a structural phase transformation of these intermetallic compounds from a cubic to a tetragonal structure upon lithiation to host structure. The ground state energy is calculated using the WIEN2k package to determine the structure stability and volume change due to lithium addition, which is further used to calculate the formation energy, open circuit voltage (OCV), and lithium-ion storage capacity. The equilibrium structural parameters for all the phases are determined by achieving a total energy convergence of 10−4 Ry. The estimated band structure along high-symmetry lines in the first Brillouin zone and the total as well as partial density of states demonstrate unequivocally that the addition of lithium does not change the metallic nature of these electrode materials. We have also calculated the theoretical lithium-ion storage capacity and OCV for all the compounds. Despite a higher value for OCV larger than 5 V, many of the investigated materials could not be found suitable from a synthesis point of view due to positive formation energies. The formation energy calculation shows that LaSb3, with a 50% concentration of Li, is the most stable compound out of those investigated here. The calculated OCV for Li0.5La0.5Sb3 is 4.27 V. This is substantially higher than the value obtained up to this point for LIBs, which ranges from 3.20 to 3.65 V/cell. These improved results related to the most stable alloy (Li0.5La0.5Sb3) investigated in this work indicate that it is necessary to check the experimental feasibility of its synthesis and actual device performance.

锂离子电池电极材料 LaX3(X:锑、锡)的第一性原理计算
我们利用第一原理计算研究了稀土金属间化合物 LaX3(X = Sb 和 Sn)作为可充电锂离子电池 (LIB) 正极材料的情况。计算的目的是研究主 LaX3 及其锂化相 LixLa1-xX3 (0 < x ≤ 1)的结构稳定性和电子特性。在这项研究中,我们观察到了这些金属间化合物在锂化成主结构后从立方结构到四方结构的结构相变。我们使用 WIEN2k 软件包计算了基态能,以确定结构的稳定性和锂添加引起的体积变化,并进一步用于计算形成能、开路电压(OCV)和锂离子存储容量。通过实现 10-4 Ry 的总能量收敛,确定了所有相的平衡结构参数。沿第一布里渊区高对称性线估算出的带状结构以及总态密度和部分态密度明确表明,锂的加入不会改变这些电极材料的金属性质。我们还计算了所有化合物的理论锂离子存储容量和 OCV。尽管大于 5 V 的 OCV 值较高,但从合成的角度来看,许多被研究的材料都因正形成能而不适合合成。形成能计算显示,锂浓度为 50%的 LaSb3 是本文所研究的化合物中最稳定的。计算得出的 Li0.5La0.5Sb3 的 OCV 为 4.27 V。这大大高于迄今为止所获得的锂离子电池 OCV 值(3.20 至 3.65 V/cell)。与本研究中最稳定的合金(Li0.5La0.5Sb3)相关的这些改进结果表明,有必要检查其合成和实际设备性能的实验可行性。
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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CiteScore
2.90
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