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 …

For energy storage devices, high energy density, high power density, cycle stability, and
safety are the development goals. Solid‐state lithium metal batteries, with both safety and …

E-mobility, especially electric cars, has been scaling up rapidly because of technological
advances in lithium-ion batteries (LIBs). However, LIBs degrade significantly with service life …

The microstructure of a composite electrode determines how individual battery particles are
charged and discharged in a lithium-ion battery. It is a frontier challenge to experimentally …

Defect engineering on electrode materials is considered an effective approach to improve
the electrochemical performance of batteries since the presence of a variety of defects with …

Electrochemical and mechanical properties of lithium‐ion battery materials are heavily
dependent on their 3D microstructure characteristics. A quantitative understanding of the …

Lithium‐ion batteries are the most commercially successful electrochemical devices,
extensively used in intelligent electronics, electric vehicles, grid energy storages, etc …

Surface lattice reconstruction is commonly observed in nickel-rich layered oxide battery
cathode materials, causing unsatisfactory high-voltage cycling performance. However, the …

Spinel LiMn2O4 is a promising cathode material for lithium-ion batteries ascribed to its
steady bulk structure and abundant manganese sources. Nevertheless, severe capacity …

Electrification of the transportation sector relies on radical re-imagining of energy storage
technologies to provide affordable, high energy density, durable and safe systems. Next …