High-energy lithium-ion batteries are being increasingly applied in the electric vehicle
industry but suffer from rapid capacity fading and a high risk of thermal runaway. The …

For conventional cathode materials, cobalt plays an important role, but the cobalt content of
lithium battery cathode materials must be reduced because of the scarcity of cobalt …

Lithium-ion batteries (LIBs) have emerged as an indispensable component in the
development of green transportation such as electric vehicles (EVs) and large-scale …

Precise prediction of lithium‐ion cell level aging under various operating conditions is an
imperative but challenging part of ensuring the quality performance of emerging applications …

Lithium‐metal batteries (LMB) employing cobalt‐free layered‐oxide cathodes are a
sustainable path forward to achieving high energy densities, but these cathodes exhibit …

Next-generation battery development necessitates the coevolution of liquid electrolyte and
electrode chemistries, as their erroneous combinations lead to battery failure. In this regard …

Trace protic impurities, such as water and hydrofluoric acid (HF), can severely degrade the
stable and long cycling of lithium batteries. Therefore, the costly water removal process is …

Li metal batteries using Li metal as negative electrode and LiNi1-x-yMnxCoyO2 as positive
electrode represent the next generation high-energy batteries. A major challenge facing …

The cathode–electrolyte interphase plays a pivotal role in determining the usable capacity
and cycling stability of electrochemical cells, yet it is overshadowed by its counterpart, the …

Compensating the irreversible loss of limited active lithium (Li) is essentially important for
improving the energy‐density and cycle‐life of practical Li‐ion battery full‐cell, especially …