Exploring a universal strategy to increase Li-ion storage capacity and ionic conductivity
while maintaining a robust crystal framework is a significant challenge for advancing …

The concomitant environmental issues related to the consumption of fossil fuels underscore
the significance of accelerating the global electrification. However, the shift towards …

Fast‐charging lithium‐ion batteries are pivotal in overcoming the limitations of energy
storage devices, particularly their energy density. There is a burgeoning interest in boosting …

Implementing fast‐charging lithium‐ion batteries (LIBs) is severely hindered by the issues of
Li plating and poor rate capability for conventional graphite anode. Wadsley–Roth phase …

Niobium-based compounds with Wadsley–Roth crystallographic shear structures show
promise as fast lithium storage materials in micrometer sizes without the need for …

The Wadsley–Roth family of transition metal oxide phases are a promising class of anode
materials for Li-ion batteries due to their open crystal structures and their ability to intercalate …

Wadsley–Roth phases have emerged as highly promising anode materials for Li-ion
batteries and are an important class of phases that can form as part of the oxide scales of …

The development of new high-performing battery materials is critical for meeting the energy
storage requirements of portable electronics and electrified transportation applications …

High‐power lithium‐ion batteries (LIBs) are required for a variety of technological
applications, especially in the field of electric vehicles (EVs). Oxides based on niobium …

The TiNb2O7 Wadsley–Roth phase is a promising anode material for Li-ion batteries,
enabling fast cycling and high capacities. While already used in commercial batteries, many …