Stabilizing the Garnet Solid-Electrolyte/Polysulfide Interface in Li–S Batteries

Abstract

Chemical and physical short circuits are the main challenges faced by lithium batteries which compromise battery performance and safety. At the cathode, solvation of active cathode materials and shuttling of unwanted chemical species in the liquid electrolyte result in “chemical short circuits”, which deteriorate the Li metal electrode and limit the deployment of new cathode materials, such as high voltage cathodes, sulfur, and air/O₂. In Li–S batteries, the repeated shuttling of polysulfides between electrodes constantly corrodes the Li metal anode and the loss of active material will result in low Coulombic efficiency. At the anode, Li dendrite penetration through the separator causes internal electronic, or “physical”, short circuits. Finally, several strategies have been reported to prevent chemical and physical short circuits by using a cathode host, small sulfur molecules, modified separators, or electrolyte additives to alleviate sulfur materials diffusion and shuttling, and finding ways to delay, confine, or block Li dendrites to extend the cycling lifetime and avoid thermal runaway in lithium metal batteries.