Interface morphogenesis with a deformable secondary phase in solid-state lithium batteries
Sun Geun Yoon, Bairav S. Vishnugopi, Douglas Lars Nelson, Adrian Xiao Bin Yong, Yingjin Wang, Stephanie Elizabeth Sandoval, T. L. Thomas, Kelsey A. Cavallaro, Pavel Shevchenko, Elif Pınar Alsaç, Congcheng Wang, Aditya Singla, Julia R. Greer, Elif Ertekin, Partha P. Mukherjee, Matthew T. McDowell
Abstract
The complex morphological evolution of lithium metal at the solid-state electrolyte interface limits performance of solid-state batteries, leading to inhomogeneous reactions and contact loss. Inspired by biological morphogenesis, we developed an interfacial self-regulation concept in which a deformable secondary phase dynamically aggregates at the interface in response to local electro-chemo-mechanical stimuli, enhancing contact. The stripping of a lithium electrode that contains 5 to 20 mole % electrochemically inactive sodium domains causes spontaneous sodium accumulation across the interface, with the sodium deforming to attain intimate electrical contact without blocking lithium transport. This process, characterized with operando x-ray tomography and electron microscopy, mitigates voiding and improves cycling at low stack pressures. The counterintuitive strategy of adding electrochemically inactive alkali metal to improve performance demonstrates the utility of interfacial self-regulation for solid-state batteries.