Decoupling the origins of irreversible coulombic efficiency in anode-free lithium metal batteries

Anode-free lithium metal batteries are the most promising candidate to outperform lithium metal batteries due to higher energy density and reduced safety hazards with the absence of metallic lithium anode during initial cell fabrication. In general, researchers report capacity retention, reversible capacity, or rate capability of the cells to study the electrochemical performance of anode-free lithium metal batteries. However, evaluating the behavior of batteries from limited aspects may easily overlook other information hidden deep inside the meretricious results or even lead to misguided data interpretation. In this work, we present an integrated protocol combining different types of cell configuration to determine various sources of irreversible coulombic efficiency in anode-free lithium metal cells. The decrypted information from the protocol provides an insightful understanding of the behaviors of LMBs and AFLMBs, which promotes their development for practical applications. Anode-free lithium metal battery is one of the most promising candidates for next-generation high energy density battery but suffer from poor cycle life. Here the authors present an integrated protocol to dissect and quantify the irreversible coulombic efficiencies for better understanding of the battery.

Automated summary

Anode-free lithium metal batteries show potential for high energy density and reduced safety hazards, but face challenges with cycle life. The integrated protocol presented in this work allows for dissecting and quantifying irreversible coulombic efficiencies to improve understanding of the battery.