Addressing Transport Issues in Non-Aqueous Li–air Batteries to Achieving High Electrochemical Performance

Critical CO2 Concentration for Practical Lithium–Air Batteries

Revealing the mechanism of saturated ether electrolyte for improving the long-cycling stability of Na-O2 batteries - ScienceDirect

The evolution of Li 2 O 2 particles during charging and discharging.

Schematic of mass transport processes during discharging of a Li–air

In situ DEMS of aGDL on discharge in phenol-LiTFSI-TEGDME showing 2.04

Functional and stability orientation synthesis of materials and structures in aprotic Li-O2 batteries.

Functional and stability orientation synthesis of materials and structures in aprotic Li-O2 batteries.

LiTFSI Concentration Optimization in TEGDME Solvent for Lithium–Oxygen Batteries

LiTFSI Concentration Optimization in TEGDME Solvent for Lithium–Oxygen Batteries

Discharge/charge profiles of the Li–O2 cell with Ru/SP. The charge

The water catalysis at oxygen cathodes of lithium–oxygen cells

Addressing Transport Issues in Non-Aqueous Li–air Batteries to Achieving High Electrochemical Performance

LiTFSI Concentration Optimization in TEGDME Solvent for Lithium–Oxygen Batteries

A) The proposed reaction routes of capturing O 2 À by CO 2 . B),C) The