Low Coulombic efficiency, low‐capacity retention, and short cycle life are the primary
challenges faced by various metal‐ion batteries due to the loss of corresponding active …

By incorporating sacrificial lithium (Li) sources during electrode fabrication, researchers aim
to address the challenge of initial capacity loss due to the formation of a solid electrolyte …

Li 2 C 2 O 4 is recognized as a promising prelithiation reagent for compensating active
lithium owing to its residue-free, high-capacity, air-stable and cost-effective advantages …

Utilizing hyper‐lithiated materials can offer a variety of options for designing high‐energy
lithium‐ion batteries. As sacrificial cathodes, they compensate for the initial loss of Li+ at the …

The advanced lithium‐ion batteries that can tolerate zero‐volt storage (ZVS) are in high
demand for implantable medical devices and spacecraft. However, ZVS can raise the anode …

The development of high-energy-density Li-ion batteries is hindered by the irreversible
capacity loss during the initial charge-discharge process. Therefore, pre-lithiation …

Li 2 NiO 2 has garnered considerable interest as a Li-excess cathode additive for high-
energy lithium-ion batteries (LIBs), attributed to its high irreversible capacity during the initial …

Increasing lithium contents within the lattice of positive electrode materials is projected in
pursuit of high‐energy‐density batteries. However, it intensifies the release of lattice oxygen …

Sacrificial cathode additives have emerged as a tempting strategy to compensate the initial
capacity loss (ICL) in Li-ion batteries (LIBs) manufacturing. However, the utilization of …

The Li‐rich antifluorite‐type oxides Li5FeO4, Li5. 5Fe0. 5Co0. 5O4 and Li6CoO4 have been
investigated as positive electrode materials for Li‐ion batteries in a combined operando …