Title: Statically and Dynamically Stable Lithium-sulfur Batteries

The commercialization of lithium-sulfur (Li-S) batteries is hampered by several intrinsic materials challenges: low electronic and ionic conductivity of the active material, severe polysulfide migration from the cathode to the anode, and instability of the Li-metal anode. The poor conductivity limits the electrochemical utilization of the active material and often necessitates a high content of electrochemically inactive, conductive carbon or functional polymers in the cathode region, which lowers the practical energy density. The polysulfide migration causes static and dynamic instabilities with high capacity fade, poisoning of the Li-metal surface, and poor cycling efficiency, hindering the practical viability of Li-S batteries. Recently, it is becoming obvious that the development of practically viable high-energy-density Li-S batteries is determined largely by attaining the necessary cell-design parameters. The essential extrinsic parameters include a sulfur loading of at least 5 mg cm-2, a sulfur content of over 65 wt.%, and a low electrolyte/sulfur (E/S) ratio of less than 11 milliliter per gram. To overcome the above challenges, our group has demonstrated in this project that innovations in polysulfide-filter-coated separators and advanced electrode substrates greatly enhance the electrochemical utilization and efficiency with reasonably high sulfur loadings and low E/S ratios in the cells. This is because Li-S batteries involve conversion reactions unlike the insertion-reaction electrodes in commercial Li-ion batteries, so cell components/designs directly borrowed from Li-ion batteries may need new architectures or chemical/physical characteristics to be adapted to sulfur cathodes. Our cell-component design provides the fabricated Li-S cells with enhanced electrochemical performance: high utilization of the active material, extended cycle life, and good storage properties. More importantly, these custom cell configurations allow the cells to employ the easily prepared sulfur cathodes with a high sulfur loading (up to 60 mg cm-2) and a high sulfur content (80 wt.%) with a low E/S ratio of as low as 4.0 milliliter per gram. Our progress illustrates that the approaches presented and developed in this project offer practically viable solutions for the Li-S technology development.