Direct Observation of Dendrites Nucleation in Li Metal Battery by Machine Learning Accelerated Molecular Simulations under Realistic Electrochemical Conditions

Uncontrollable dendrites growth during electrochemical cycles leads to low Coulombic efficiency and critical safety issues in Li metal batteries. Hence, a comprehensive understanding of the dendrite formation mechanism is essential for further enhancing the performance of Li metal batteries. Machine learning accelerated molecular dynamics (MD) simulations can provide atomic-scale resolution for various key processes at an ab-initio level accuracy. However, traditional MD simulation tools hardly capture Li electrochemical depositions, due to lack of an electrochemical constant potential (ConstP) condition. In this work, we propose a ConstP approach that combines a machine learning force field with the charge equilibration method to reveal the dynamic process of Li dendrites nucleation at Li metal anode surfaces. Our results show that both dead Li cluster formation and inhomogeneous Li electro-depositions can induce Li dendrites nucleation. We further reveal that the local aggregation of Li atoms in amorphous inorganic components of solid electrolyte interphase is the key factor triggering the nucleation process. Overall, our simulations provide microscopic insights for Li dendrites formations in Li metal anodes. More importantly, we present an efficient and accurate simulation method for modeling realistic ConstP conditions, which holds considerable potential for broader applications in modeling of complex electrochemical interfaces.