Linking Pressure to Electrochemical Evolution in Solid-State Conversion Cathode Composites.
Elif Pınar Alsaç, Arpan Kumar Sharma, Sun Geun Yoon, Bairav S Vishnugopi, Congcheng Wang, Talia A Thomas, Douglas Lars Nelson, Udochukwu D Eze, Won Joon Jeong, John Harris, Partha P Mukherjee, Matthew T McDowell
Abstract
Open AccessConversion-type cathodes, such as sulfur, FeS2, and FeF3, offer high theoretical capacities in solid-state lithium batteries but are hindered by substantial volume changes during cycling, leading to interfacial contact loss, crack formation, and microstructural degradation. Here, we investigate the relationships between electrochemical, mechanical, and structural evolution in solid-state electrode composites with these three active materials. Using real-time stack-pressure monitoring, synchrotron X-ray absorption spectroscopy, and electrokinetic modeling, we elucidate how stress evolution is linked to reversible and irreversible redox reactions. Nonlinear stack pressure evolution in cells with sulfur, FeS2, and FeF3 electrode composites is found to arise from material-specific volume changes, the balance of volume change between the working and counter electrode, and the formation of distinct reaction intermediates. The three materials exhibit distinct stack pressure evolution, which is closely related to the different reaction processes in the materials, as demonstrated with X-ray absorption spectroscopy measurements. Through mesoscale modeling, we relate the experimental measurements to species evolution at the particle scale and track the dynamic coexistence of intermediate phases. Our findings highlight the importance of designing for volume changes of a given active material in solid-state battery systems.