Rechargeable lithium batteries (RLBs) have revolutionized energy storage technology.
However, short lifetime and safety issues have hampered their further commercialization …

Whether attempting to eliminate parasitic Li metal plating on graphite (and other Li‐ion
anodes) or enabling stable, uniform Li metal formation in 'anode‐free'Li battery …

The lithium-ion batteries used in electric vehicles have a shorter lifespan than other vehicle
components, and the degradation mechanism inside these batteries reduces their life even …

Rechargeability and operational safety of commercial lithium (Li)-ion batteries demand
further improvement. Plating of metallic Li on graphite anodes is a critical reason for Li-ion …

The solid-electrolyte interphase (SEI) enables the remarkable capacity retention of lithium-
ion batteries, yet a comprehensive quantitative description of the SEI composition remains …

Rapid charging of Li-ion batteries is limited by lithium plating on graphite anodes, whereby
Li+ ions are reduced to Li metal on the graphite particle surface instead of inserting between …

The solid electrolyte interphase (SEI) on lithium metal anodes (LMA) plays a critical role in
affording a long lifespan required for aprotic lithium‐oxygen (Li–O2) batteries. Nevertheless …

Capacity losses in Li anodes derive from the formation of electronically isolated Li0 and
parasitic reactions that form the solid electrolyte interphase (SEI). Loss quantification has …

Conditions such as the temperature and pressure experienced by lithium-ion battery
components are dependent on cell geometry and can vary widely within a large cell. The …

Fast charging promotes Li dendrite formation and its growth on graphite anodes, which
affects cell performance in Li-ion batteries (LIBs). This work reports the formation of a robust …