Non‐Solvating and Low‐Dielectricity Cosolvent for Anion‐Derived Solid Electrolyte Interphases in Lithium Metal Batteries

Lithium (Li) metal anode holds great promise for next-generation high-energy-density batteries, while the insufficient fundamental understanding of the complex solid electrolyte interphase (SEI) is the major obstacle for the full demonstration of their potentials in working batteries. The characteristics of SEI highly depend on the inner solvation structure of lithium ions (Li+). In this contribution, we clarify the critical significance of cosolvent properties on both Li+ solvation structure and the SEI formation on working Li metal anodes. Universally, non-solvating and low-dielectricity (NL) cosolvents intrinsically enhance the interaction between anion and Li+ by affording a low dielectric environment. The abundant positively-charged anion-cation aggregates generated as the introduction of NL cosolvents are preferentially brought to the negatively-charged Li anode surface, inducing an anion-derived inorganic-rich SEI. A solvent diagram is further built to illustrate that a solvent with both proper relative binding energy toward Li+ and dielectric constant is suitable as NL cosolvent. This work elucidates the significance of fundamental physicochemical theory in guiding electrolyte design and calls for more efforts to rationally apply the cosolvents for stable Li metal batteries.