Despite their rapid emergence as the dominant paradigm for electrochemical energy
storage, the full promise of lithium-ion batteries is yet to be fully realized, partly because of …

Lithium‐ion batteries exhibit a coupled set of electrochemical, thermal, and mechanical
interactions ranging over different length scales. Microstructure‐scale electrode …

Lithium metal and lithium-rich alloys are high-capacity anode materials that could boost the
energy content of rechargeable batteries. However, their development has been hindered …

Conspectus For the past two decades, conversion and alloying-type materials have been
heralded as the natural heir to commercially available graphite anodes due to their ability to …

Next-generation high-performance lithium-ion batteries (LIBs) with high energy and power
density, long cycle life and uncompromising safety standards require new electrode …

The intercalation compounds are generally considered as ideal electrode materials for
lithium-ion batteries thanks to their minimum volume expansion and fast lithium ion diffusion …

Conspectus Undesired reactions at the interface between a transition metal oxide cathode
and a nonaqueous electrolyte bring about challenges to the performance of Li-ion batteries …

Conspectus Lithium-ion batteries (LIBs) are nearly ubiquitous energy storage solutions,
powering devices ranging from consumer electronics to electric vehicles. To advance these …

Intercalation-induced phase transformations in Li-ion battery electrode materials give rise to
multi-phase coexistence regimes within individual particles, generating significant lattice …

Transitioning to electrified transport requires improvements in sustainability, energy density,
power density, lifetime, and approved the cost of lithium-ion batteries, with significant …