Solid-state lithium metal batteries (SSLBs) using inorganic solid-state electrolytes (SSEs)
have attracted extensive scientific and commercial interest owing to their potential to provide …

The increasing demand for high-security, high-performance, and low-cost energy storage
systems (EESs) driven by the adoption of renewable energy is gradually surpassing the …

Performance degradation of ternary layered oxide cathodes largely originates from their loss
of structural integrity in cyclic usage. Mechanical damage, such as intergranular fracture of …

In the context of lithium-ion battery technology, LiNi x Mn y Co z O 2 (x≥ 0.8)(Ni-rich NMC) is
considered a promising cathode material for next-generation batteries due to its high energy …

Solid-state batteries promise higher energy density and improved safety compared with
lithium-ion batteries. However, electro-chemomechanical instabilities at the solid electrolyte …

Solid-state Li-ion batteries, based on Ni-rich oxide cathodes and Li-metal anodes, can
theoretically reach a high specific energy of 393 Wh kg− 1 and hold promise for …

In Li-ion battery research, it is common to simulate chemo-mechanical phenomena in
reduced dimensions (eg, 2-D) as opposed to fully resolve these complex physics in 3-D. It is …

The optimal design and durable utilization of lithium-ion batteries necessitates an objective
modeling approach to understand fracture and failure mechanisms. This paper presents a …

Understanding structure-property relationships of Li-ion battery cathodes is crucial for
optimizing rate-performance and cycle-life resilience. However, correlating the morphology …

Understanding structure-property relationships of Li-ion battery cathodes is crucial for
optimizing rate-performance and cycle-life resilience. However, correlating the morphology …