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  1. Ion mobility and solvation complexes at liquid–solid interfaces in dilute, high concentration, and localized high concentration electrolytes

    Evolution of a lithium cation solvation complex in low concentration electrolytes (LCEs), high concentration electrolytes (HCEs), and localized high concentration electrolytes (LHCEs) reveals competition of transport, desolvation, and deposition events.
  2. Understanding Solid Electrolyte Interphase Nucleation and Growth on Lithium Metal Surfaces

    Experiments and theory are needed to decode the exact structure and distribution of components of a passivation layer formed at the anode surface of Li metal batteries, known as the Solid Electrolyte Interphase (SEI). Due to the inherent dynamic behavior as well as the lithium reactivity, the SEI structure and its growth mechanisms are still unclear. This study uses molecular simulation and computational chemistry tools to investigate the initial nucleation and growth dynamics of LiOH and Li2O that provide us with thermodynamics and structural information about the nucleating clusters of each species. Following the most favorable pathways for the additionmore » of each of the components to a given nascent SEI cluster reveals their preferential nucleation mechanisms and illustrates different degrees of crystallinity and electron density distribution that are useful to understand ionic transport through SEI blocks.« less
  3. Solvation vs. surface charge transfer: an interfacial chemistry game drives cation motion

    Electrolyte structure and ion solvation dynamics determine ionic conductivities, and ion (de)solvation processes dominate interfacial chemistry and electrodeposition barriers. In this work, we elucidate electrolyte effects facilitating or impeding Li+ diffusion and deposition, and evaluate structural and energetic changes during the solvation complex pathway from the bulk to the anode surface.
  4. Insights into lithium ion deposition on lithium metal surfaces

    Lithium metal is among the most promising anodes for the next generation of batteries due to its high theoretical energy density and high capacity. Challenges such as extreme reactivity and lithium dendrite formation have kept lithium metal anodes away from practical applications. However, the underlying mechanisms of Li ion deposition from the electrolyte solution onto the anode surface are still poorly understood due to their inherent complexity. In this work, density functional theory calculations and thermodynamic integration via constrained molecular dynamics simulations are conducted to study the electron and ion transfer between lithium metal slab and the electrolyte in absencemore » of an external field. Here, we explore the effect of the solvent chemistry and structure, distance of the solvated complex from the surface, anion–cation separation, and concentration of Li-salts on the deposition of lithium ions from the electrolyte phase onto the surface. Ethylene carbonate (EC), 1,2-dimethoxyethane (DME), 1,3-dioxolane (DOL), and mixtures of them are used as solvents. These species compete with the salt anion and the Li cation for electron transfer from the surface. It is found that the structure and properties of the solvation shell around the lithium cation has a great influence on the ability of the cation to diffuse as well as on its surrounding electron environment. DME molecules allow easier motion of the lithium ion compared with EC and DOL molecules. The slow growth approach allows the study of energy barriers for the ion diffusion and desolvation during the deposition pathway. This method helps elucidating the underlying mechanisms on lithium-ion deposition and provides a better understanding of the early stages of Li nucleation.« less
  5. Role of Inorganic Surface Layer on Solid Electrolyte Interphase Evolution at Li-Metal Anodes

    Lithium metal is an ideal anode for rechargeable lithium battery technology. However, the extreme reactivity of Li-metal with the electrolyte leads to solid electrolyte interphase (SEI) layer which often impedes the Li+ transport across the interface. The challenge is to predict the chemical, structural and topographical heterogeneity of SEI layer arising from multitude of interfacial constituents. Traditionally the pathways and products of electrolyte decomposition processes were analyzed with the basic presumption of pristine Li-metal surface for simplicity. However, ubiquitous inorganic passivation layers on Li-metal can dampen the electronic charge transfer to the electrolyte and significantly alter the SEI layer evolution.more » In this study, we analyzed the effect of nanometric Li2O, LiOH and Li2CO3 as surface passivation layer on the interfacial reactivity of Li-metal using ab initio molecular dynamics (AIMD) calculations and X-ray photoelectron spectroscopy (XPS) measurements. These nanometric layers impede the electronic charge transfer to the electrolyte and thereby provide some degree of passivation (compared to pristine lithium metal) to the redox based decomposition process. The Li2O, LiOH and Li2CO3 layers admits varying level of electron transfer from Li-metal slab and subsequent storage of the electronic charges within their structure. Nevertheless, their ability for electron transfer to the electrolyte molecules and the extent of bis(trifluoromethanesulfonyl)imide (TFSI) anion decomposition is significantly smaller than that on the pristine Li-metal. The XPS experiments showed that Li2O as major surface component had greater LiF phase formation, whereas a dominant LiOH layer shows enhanced sulfur decomposition process. Furthermore, these observations were explained based on different electronic charge transfer ability of the passivating films derived from AIMD results.« less

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"Angarita-Gomez, Stefany"

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