The specific energy of commercial lithium (Li)-ion batteries is reaching the theoretical limit.
Future consumer electronics and electric vehicle markets call for the development of high …

Carbon materials, with their diverse allotropes, have played significant roles in our daily life
and the development of material science. Following 0D C60 and 1D carbon nanotube, 2D …

Improving Coulombic efficiency (CE) is key to the adoption of high energy density lithium
metal batteries. Liquid electrolyte engineering has emerged as a promising strategy for …

An all-solid-state battery with a lithium metal anode is a strong candidate for surpassing
conventional lithium-ion battery capabilities. However, undesirable Li dendrite growth and …

Solid‐state lithium‐metal batteries constructed by in‐situ solidification of cyclic ether are
considered to be a critical strategy for the next generation of solid‐state batteries with high …

Lithium metal anodes are an appealing choice for rechargeable batteries due to their
exceptionally high theoretical capacity of about 3860 mA hg− 1. However, the uneven …

Lithium metal anodes are ideal for realizing high-energy-density batteries owing to their
advantages, namely high capacity and low reduction potentials. However, the utilization of …

Although the lithium‐metal anode (LMA) can deliver a high theoretical capacity of≈ 3860
mAh g− 1 at a low redox potential of− 3.040 V (vs the standard hydrogen electrode), its …

The development of rechargeable batteries with high‐energy density is critical for future
decarbonization of transportation. Anode‐free Li‐ion batteries, using a bare current collector …

The advances in process engineering, nanotechnology, and materials science gradually
enable the potential applications of biomass in novel energy storage technologies such as …