This in silico study on calcium salts of YB11X12−$\left(\text{YB}\right)_{11} \text{X}_{12}^{-}$ (Y = C/Si and X = –BO/OBO) anions reveals interesting reductive behavior of anions on the Ca anode. The cores of YB11(OBO)12−$\left(\text{YB}\right)_{11} \left(\left(\right. \text{OBO} \left.\right)\right)_{12}^{-}$ (Y = C/Si) anions remain stable on anode but –OBO ligands attached undergo transformation to give borate species as part of the solid electrolyte interface, highlighting their potential as promising electrolytes for calcium-ion batteries.

The development of calcium-ion batteries (CIBs) as potential successors to lithium-ion batteries has been hindered by the lack of suitable electrolytes. Conventional electrolytes often decompose on the Ca anode, forming calcium-ion impermeable passivation layers that impede reversible calcium plating and stripping. Therefore, the design of stable electrolytes or those capable of forming Ca²⁺ permeable passivation layers remains a critical challenge. The present study investigates calcium salts of YB11X12−$\left(\text{YB}\right)_{11} \text{X}_{12}^{-}$ (Y = C/Si and X = –BO/OBO) anions using density functional theory (DFT)-based simulations for CIBs. DFT calculations emphasize the oxidative stability of anions, while ab initio molecular dynamics (AIMD) simulations reveal their reductive behavior on the Ca anode. Time-dependent charge transfer analysis and projected density of states provide an atomistic perspective on electron transfer between the Ca surface and anions, aligning with observations from frontier orbital analyses. Decomposition of YB11(OBO)12−$\left(\text{YB}\right)_{11} \left(\left(\right. \text{OBO} \left.\right)\right)_{12}^{-}$ (Y = C/Si) anions during AIMD simulation reveals the formation of borate-based species as part of the solid electrolyte interface, suggesting their potential as electrolytes that enable effective calcium plating and stripping. Overall, this work paves the way for designing efficient electrolytes, offering a fresh perspective to identify optimal CIB electrolytes, and moving beyond ensuring electrolyte stability on the Ca anode.