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Revealing Morphology Evolution of Lithium Dendrites by Large‐Scale Simulation Based on Machine Learning Force Field

Wentao Zhang, Mouyi Weng, Mingzheng Zhang, Yaokun Ye, Zhefeng Chen, Simo Li, Shunning Li, Feng Pan, Lin‐wang Wang

2022Advanced Energy Materials34 citationsDOIOpen Access PDF

Abstract

Abstract Solving the dendrite growth problem is critical for the development of lithium metal anode for high‐capacity batteries. In this work, a machine learning force field model in combination with a self‐consistent continuum solvation model is used to simulate the morphology evolution of dendrites in a working electrolyte environment. The dynamic evolution of the dendrite morphology can be described in two stages. In the first stage, the energy reduction of the surface atoms induces localized reorientation of the originally single‐crystal dendrite and the formation of multiple domains. In the second stage, the energy reduction of internal atoms drives the migration of grain boundaries and the slipping of crystal domains. The results indicate that the formation of multiple domains might help to stabilize the dendrite, as a higher temperature trajectory in a single crystal dendrite without domains shows a higher dendrite collapsing rate. Several possible modes of morphological evolutions are also investigated, including surface diffusion of adatoms and configuration twists from [100] exposed surfaces to [110] exposed surfaces. In summary, reducing the surface and grain boundary energy drives the morphology evolution. Based on the analysis of these driving forces, some guidelines are suggested for designing a more stable lithium metal anode.

Topics & Concepts

Dendrite (mathematics)Materials scienceAnodeChemical physicsLithium metalCrystal (programming language)Morphology (biology)DiffusionGrain boundaryCondensed matter physicsNanotechnologyThermodynamicsComposite materialGeometryPhysical chemistryElectrodePhysicsProgramming languageMicrostructureComputer scienceMathematicsBiologyGeneticsChemistryAdvanced Battery Materials and TechnologiesAdvancements in Battery MaterialsMachine Learning in Materials Science
Revealing Morphology Evolution of Lithium Dendrites by Large‐Scale Simulation Based on Machine Learning Force Field | Litcius