In an era of sustainable development and innovation ecosystem, a high-energy density is
one of the important requirements for the development of new energy storage modalities …

In the last decade, Li-O 2 batteries have been a research focus due to its ultrahigh energy
density as chemical power sources and being rechargeable through oxygen reduction and …

The lithium–oxygen battery (LOB) with a high theoretical energy density (∼ 3500 Wh kg–1)
has been regarded as a strong competitor for next-generation energy storage systems …

Li–O2 batteries with ultrahigh theoretical energy density have been regarded as a promising
successor to Li-ion batteries for next-generation energy storage. However, their practical …

In the pursuit of next-generation ultrahighenergy-density LiĀ O2 batteries, it is imperative to
develop an electrolyte with stability against the strong oxidation environments. N, N …

Inferior charge transport in insulating and bulk discharge products is one of the main factors
resulting in poor cycling stability of lithium–oxygen batteries with high overpotential and …

The main bottleneck in the application of biomass-based carbon material in energy field is
the development of an economical, nanoscale controllable and universal fabrication …

Uncontrollable Li dendrite growth and infinite volume fluctuation during durative plating and
stripping process gravely hinder the application of metallic Li electrode in lithium-oxygen …

Free‐standing macroporous air electrodes with enhanced interfacial contact, rapid mass
transport, and tailored deposition space for large amounts of Li2O2 are essential for …

Li–O2 batteries have a high theoretical specific energy, 3500 Wh kg− 1; however, its
practical capacity is far below this value and limited by the passivation with the insulating …