The insufficient cyclic efficiency and poor safety have prohibited the commercial applications of the lithium-metal anode because of its uncontrolled dendrite growth at the surface. A mechanically stable and highly ionic conductive solid electrolyte interphase (SEI) holds great promise to address the issues. Herein, a viable surface engineering approach is proposed for stabilizing the Li anode via a scalable artificial method. The surface of Li metal is functionalized by constructing a mechanically tough and electron-insulating metal-organic framework (MOF) of the MIL-125(Ti) layer. In-situ optical microscopy reveals its crucial role in inhibiting dendritic Li growth. Because of the intrinsic insulativity and highly ordered micropores of MIL-125(Ti), the Li+ ions acquire electrons under the coating layer, resulting in a uniform and dense Li deposition behavior. The symmetric cell of the MOF-modified Li electrode delivers a long life span of 2000 h with an overpotential of less than 20 mV at 0.5 mA cm-2. When paired with the same MOF-derived sulfur cathode, decent cycling retention is available as well. This work demonstrates a feasible strategy for the development of a stable Li-metal anode with alleviative dendritic growth.
Keywords: electronic shield; lithium dendrites; lithium−sulfur battery; metal−organic framework; solid electrolyte interphase; surface engineering.