A computational study of electron transport in dynamic tetrahydrofuran and ethylene carbonate solvents on a Ca metal anode.

Calcium-ion batteries offer many advantages to the current lithium-ion technology in terms of cost, sourcing materials, and potential for higher energy density. However, calcium-ion batteries suffer from lack of a stable electrolyte due to reduction from the anode. Building off of our recent work investigating the stability of two representative electrolyte solvents, tetrahydrofuran (THF) and ethylene carbonate (EC), we now use ab initio molecular dynamics (AIMD) and the non-equilibrium Green's function technique in conjunction with density functional theory (NEGF-DFT) to investigate charge transport as the solvent molecules dynamically interact with the anode surface. THF maintained a relatively consistent conductance throughout the trajectory, although some jumps in the conductance were attributed to THF molecular rearrangement. EC exhibited a large amount of molecular decomposition, and a corresponding decrease in conductance of several orders of magnitude was noted. Through this analysis, we show that molecular decomposition and early-stage solid-electrolyte interphase (SEI) formation plays a major role in the robustness of charge transport as the system evolves in time and with temperature.