A multiscale model to understand the interface chemistry, contacts, and dynamics during lithium stripping

IF 5 2区 工程技术 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Min Feng , Xing Liu , Stephen J. Harris , Brian W. Sheldon , Yue Qi
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引用次数: 0

Abstract

A reversible Li-metal electrode, paired with a solid electrolyte, is critical for attaining higher energy density and safer batteries beyond the current lithium-ion cells. A stable stripping process may be even harder to attain as the stripping process will remove Li-atoms from the surface, and naturally reduce surface contact area, if not self-corrected by other mechanisms, such as diffusion and plastic deformation under an applied external stack pressure. Here, we capture these mechanisms occurring at multiple length- and time- scales, i.e., interface interactions, vacancy hopping, and plastic deformation, by integrating density functional theory (DFT) simulations, kinetic Monte Carlo (KMC), and continuum finite element method (FEM). By assuming the self-affine nature of multiscale contacts, we predict the steady-state contact area as a function of stripping current density, interface wettability, and stack pressure. We further estimate the exponential increase of overpotential due to contact area loss to maintain the same stripping current density. We demonstrate that a lithiophilic interface requires less stack pressure to reach the same steady-state contact area fraction than a lithiophobic interface. A “tolerable steady-state” contact area loss for maintaining stable stripping is estimated at 20 %, corresponding to a 10 % increase in overpotential. To constrain contact loss within the tolerance, the required stack pressure is 0.1, 0.5, and 2 times the yield strength of lithium metal for three distinct interfaces, lithiophilic Li/lithium oxide(Li2O), Li/lithium lanthanum zirconium oxide(LLZO), and lithiophoblic Li/lithium fluoride(LiF), respectively. The modeling results agree with experiments on the impact of the stack pressure quantitatively, while the discrepancy in stripping rate sensitivity is attributed to the simplifying interface interaction in our simulations. Overall, this multiscale simulation framework demonstrates the importance of electrochemical-mechanical coupling in understanding the dynamics of the Li/SE interface during stripping.
了解锂剥离过程中界面化学、接触和动力学的多尺度模型
可逆锂金属电极与固态电解质的搭配,对于实现超越当前锂离子电池的更高能量密度和更安全的电池至关重要。稳定的剥离过程可能更难实现,因为剥离过程会将锂原子从表面剥离,如果不通过其他机制(如外加叠层压力下的扩散和塑性变形)进行自我纠正,自然会减少表面接触面积。在这里,我们通过整合密度泛函理论(DFT)模拟、动力学蒙特卡洛(KMC)和连续有限元法(FEM),捕捉了这些在多个长度和时间尺度上发生的机制,即界面相互作用、空位跳跃和塑性变形。通过假定多尺度接触的自仿真性质,我们预测了稳态接触面积与剥离电流密度、界面润湿性和堆叠压力的函数关系。我们进一步估算了在保持相同剥离电流密度的情况下,接触面积损失导致的过电位指数增长。我们证明,要达到相同的稳态接触面积分数,亲锂界面比疏锂界面所需的叠加压力更小。保持稳定剥离的 "可容忍稳态 "接触面积损失估计为 20%,相当于过电位增加 10%。为了将接触损失控制在容许范围内,对于三种不同的界面,即亲锂锂/氧化锂(Li2O)、锂/锂镧锆氧化物(LLZO)和亲锂锂/氟化锂(LiF),所需的堆叠压力分别为金属锂屈服强度的 0.1、0.5 和 2 倍。建模结果与实验结果在叠加压力影响方面的定量结果一致,而剥离率灵敏度方面的差异则归因于模拟中简化的界面相互作用。总之,这个多尺度模拟框架证明了电化学-机械耦合在理解剥离过程中 Li/SE 界面动态方面的重要性。
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来源期刊
Journal of The Mechanics and Physics of Solids
Journal of The Mechanics and Physics of Solids 物理-材料科学:综合
CiteScore
9.80
自引率
9.40%
发文量
276
审稿时长
52 days
期刊介绍: The aim of Journal of The Mechanics and Physics of Solids is to publish research of the highest quality and of lasting significance on the mechanics of solids. The scope is broad, from fundamental concepts in mechanics to the analysis of novel phenomena and applications. Solids are interpreted broadly to include both hard and soft materials as well as natural and synthetic structures. The approach can be theoretical, experimental or computational.This research activity sits within engineering science and the allied areas of applied mathematics, materials science, bio-mechanics, applied physics, and geophysics. The Journal was founded in 1952 by Rodney Hill, who was its Editor-in-Chief until 1968. The topics of interest to the Journal evolve with developments in the subject but its basic ethos remains the same: to publish research of the highest quality relating to the mechanics of solids. Thus, emphasis is placed on the development of fundamental concepts of mechanics and novel applications of these concepts based on theoretical, experimental or computational approaches, drawing upon the various branches of engineering science and the allied areas within applied mathematics, materials science, structural engineering, applied physics, and geophysics. The main purpose of the Journal is to foster scientific understanding of the processes of deformation and mechanical failure of all solid materials, both technological and natural, and the connections between these processes and their underlying physical mechanisms. In this sense, the content of the Journal should reflect the current state of the discipline in analysis, experimental observation, and numerical simulation. In the interest of achieving this goal, authors are encouraged to consider the significance of their contributions for the field of mechanics and the implications of their results, in addition to describing the details of their work.
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