利用量子化学和分子动力学确定锂离子电池电解质的氧化稳定性

E. Evshchik, S. Borisevich, M. G. Ilyina, E. Khamitov, Alexander V. Chernyak, T. A. Pugacheva, Valery G. Kolmakov, O. V. Bushkova, Yuri A. Dobrovolsky
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引用次数: 0

摘要

利用理论方法确定锂离子电池(LIB)电解质的氧化电位(OP)将大大加快和简化新一代高压电池的制造过程。计算 OP 的算法不仅要准确,而且要快速。我们的研究通过考虑 EC/DMC 溶剂混合物中不同盐浓度的 LiDFOB 溶液,提出了评估 LIB 电解质 OP 的理论原则。与以前版本的锂离子电池所用电解质溶液氧化电位理论测定相比,新算法的优势在于计算统计意义上的复合物,其结构由分子动力学方法确定。这种方法大大减少了需要使用量子化学方法优化几何参数的原子-分子系统的数量。因此,可以提高计算速度,降低对进行计算的计算机的功率要求。理论计算包括一套基于经典分子力学和量子化学方法的方法。为了选择在统计意义上对电化学系统的稳定性有重大贡献的复合物,对分子动力学模拟轨迹进行了全面分析。它们的几何参数(包括氧化形式)是通过质量管理方法进行优化的。因此,对氧化电位进行了评估,并描述了氧化电位与盐浓度的关系。在此,我们再次强调,很难通过计算方法获得与实验方法估算的 OP 值相等(或接近)的绝对 OP 值。尽管如此,我们还是可以发现一种趋势。理论计算的结果与实验结果完全一致。
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Determining the Oxidation Stability of Electrolytes for Lithium-Ion Batteries Using Quantum Chemistry and Molecular Dynamics
Determining the oxidation potential (OP) of lithium-ion battery (LIB) electrolytes using theoretical methods will significantly speed up and simplify the process of creating a new generation high-voltage battery. The algorithm for calculating OP should be not only accurate but also fast. Our work proposes theoretical principles for evaluating the OP of LIB electrolytes by considering LiDFOB solutions with different salt concentrations in EC/DMC solvent mixtures. The advantage of the new algorithm compared to previous versions of the theoretical determination of the oxidation potential of electrolyte solutions used in lithium-ion batteries for calculations of statistically significant complexes, the structure of which was determined by the molecular dynamics method. This approach significantly reduces the number of atomic–molecular systems whose geometric parameters need to be optimized using quantum chemical methods. Due to this, it is possible to increase the speed of calculations and reduce the power requirements of the computer performing the calculations. The theoretical calculations included a set of approaches based on the methods of classical molecular mechanics and quantum chemistry. To select statistically significant complexes that can make a significant contribution to the stability of the electrochemical system, a thorough analysis of molecular dynamics simulation trajectories was performed. Their geometric parameters (including oxidized forms) were optimized by QM methods. As a result, oxidation potentials were assessed, and their dependence on salt concentration was described. Here, we once again emphasize that it is difficult to obtain, by calculation methods, the absolute OP values that would be equal (or close) to the OP values estimated by experimental methods. Nevertheless, a trend can be identified. The results of theoretical calculations are in full agreement with the experimental ones.
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