The aging of lithium-ion batteries (LIBs) is synergistically influenced by multiple
chemical/mechanical degradation mechanisms. Therefore, conventional models that …

This study presents a comprehensive investigation of calendar aging degradation in
commercial 21,700 cylindrical lithium-ion cells with a LiNi 0.8 Mn 0.1 Co 0.1 O 2 (NMC811) …

The addition of silicon into graphite lithium-ion battery anodes has the potential to increase
cell energy density. However, understanding the complex degradation behaviour in these …

Conventional lithium-ion cell state analysis methods face challenges in applicability,
efficiency, and convergence for online state evaluation of cells with silicon‑carbon …

With the increasing use of silicon-based materials in commercial lithium-ion batteries, the
structural design of electrodes has become crucial, necessitating advanced electrode …

The widespread deployment of electric vehicles (EVs), as well as the growing requirements
both from manufacturers and consumers, necessitate an increase in energy density with …

In the design and optimization process of lithium-ion battery electrodes, microscopic
performance characterization is extremely crucial. The current multiphysics field coupling …

Accurate modelling of Li-ion batteries is essential for optimising performance and safety
across a range of applications, from electric vehicles (EVs) to grid storage. This paper …

Si-based materials have gained attention as negative electrode materials for lithium-ion
batteries. However, it is still difficult to model and predict their degradation phenomena using …

Mechanical degradation and thermal stability are two of the crucial challenges for the safety
and reliability in the large-scale battery packs for electric vehicles. However, the use of the …