Pressure Induced Thermodynamically Stable and Mechanically Robust Li-rich Unknown Li-Sn Compounds: A Step Towards Improvement of Li-Sn Batteries (1612.06770v1)

Abstract: Volume expansion and elastic softening of Sn anode on lithiation result in mechanical degradation and pulverization of Sn, affecting the overall performance of Li-Sn batteries. It can however be overcome by using exotic high pressure quenched phase as prelithiated reagent. Moreover, it is known that under pressure many unusual stoichiometric which are basically impossible at ambient pressure, can be synthesized, that may even survive the decompression from high to ambient pressure.We therefore have performed a comprehensive study using evolutionary algorithm and density functional theory based simulations to understand the lithiation of Sn anode at pressure ranging from 1 atm to 20 GPa. The ground state structures of all stable and metastable Li-Sn compounds have been identified at ambient and moderate pressures and their properties have been studied to understand the role of pressure in re-defining the reaction mechanism during charging-discharging process in Li-ion batteries. Besides the well-known existing Li-Sn compounds, our studies reveal the existence of five unreported stoichiometries (Li8Sn3, Li3Sn1, Li4Sn1, Li5Sn1, and Li7Sn1) and their associated crystal structures at ambient and high pressure. While Li8Sn3 has been identified as one of the most stable Li-Sn compound in the entire pressure range (1 atm-20 GPa), the pressure induced Li-rich compounds like Li5Sn1 and Li7Sn1 have been classified as providing higher theoretical gravimetric capacity of 1129 and 1580 mAh/g), respectively, than the capacity of the known most lithiated phase, i.e., Li17Sn4 (960 mAh/g).Most importantly, our calculations show reduction in volume expansion by ~ 50% at 20 GPa, and reveal that the application of pressure can reduce the chance of Li plating and improve the mechanical properties, which are desired to make the battery safer and its life longer.