Lithium-ion battery (LIB) degradation is often characterized at three distinct levels:
mechanisms, modes, and metrics. Recent trends in diagnostics and prognostics have been …

Conspectus The demand for lithium ion batteries continues to expand for powering
applications such as portable electronics, grid-scale energy storage, and electric vehicles …

With research on solid‐state batteries being on the rise, also simulations and modeling
studies become more and more popular. It is therefore time to reflect upon the interplay of …

Bending of electrodes in certain cell designs (cylindrical cells or flat wound jellyrolls) leads
to curved electrodes (curvature κ). For double side-coated electrodes, this curvature leads to …

Battery performance is strongly correlated with electrode microstructure and weight loading
of the electrode components. Among them are the carbon-black and binder additives that …

Quantifying the tortuosity of porous lithium-ion electrodes is important for understanding the
rate capability of cells and for optimizing their design, particularly when designing high …

An electrolyte transport theory connects its transport properties, evolution of spatiotemporal
fields (eg, concentration), and corresponding macroscopic current and voltage responses …

Battery cell production is a key contributor to achieving a net‐zero future. A comprehensive
understanding of the various process steps and their interdependencies is essential for …

For cuboid and ellipsoid crystallites of LiFePO 4 powders, by X-ray diffraction (XRD) and
microscopic (TEM) studies, it is possible to determine the anisotropic parameters of the …

While deeply charged high-voltage cathodes can improve battery energy density,
understanding and preventing any accelerated cell degradation is crucial to practical …