Add to ORKGDimethyl sulfoxide (DMSO) and acetonitrile (MeCN) have recently been highlighted as promising electrolyte solvents for Li-O2 batteries. Possible reactions between these two solvents and Li2O2 are here discussed using X-ray photoelectron spectroscopy to analyze surface of the Li2O2 powder after direct contact with the solvents for different times of exposure. The results indicated that Li2O2 decomposes DMSO solvents, whereas no indication of degradation of MeCN by Li2O2 was observed
This work investigates the impact of electrochemical reactions and products on discharge capacity an...
This work investigates the impact of electrochemical reactions and products on discharge capacity an...
Identification of electrolytes compatible with both electrodes of a nonaqueous Li/O2 battery is a co...
Aprotic Li-O2 batteries offer an appealing opportunity to make use of our immediate environment; har...
One of the key factors responsible for the poor cycleability of Li–O2 batteries is a formation of by...
The chemical stability of the Li-O-2 battery components (cathode and electrolyte) in contact with li...
The chemical stability of the Li-O-2 battery components (cathode and electrolyte) in contact with li...
The stability of electrolytes is a significant limitation for cycle life performance in Li-O2 batter...
Although dimethyl sulfoxide (DMSO) has emerged as a promising solvent for Li–air batteries, enabling...
The rechargeable Li-O2 battery has attracted interest due to its high theoretical energy density (ab...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Materials Science and Engineeri...
Non-aqueous electrolytes play a prominent role in the redox reactions of the oxygen electrode in the...
Despite considerable research efforts, finding a chemically stable electrolyte mixture in the presen...
In this work Li-O2 batteries have been investigated. Their theoretical specific energy is 3500 Wh/(k...
Active research on the aprotic Li-air battery has been drawn by its high theoretical energy and powe...
This work investigates the impact of electrochemical reactions and products on discharge capacity an...
This work investigates the impact of electrochemical reactions and products on discharge capacity an...
Identification of electrolytes compatible with both electrodes of a nonaqueous Li/O2 battery is a co...
Aprotic Li-O2 batteries offer an appealing opportunity to make use of our immediate environment; har...
One of the key factors responsible for the poor cycleability of Li–O2 batteries is a formation of by...
The chemical stability of the Li-O-2 battery components (cathode and electrolyte) in contact with li...
The chemical stability of the Li-O-2 battery components (cathode and electrolyte) in contact with li...
The stability of electrolytes is a significant limitation for cycle life performance in Li-O2 batter...
Although dimethyl sulfoxide (DMSO) has emerged as a promising solvent for Li–air batteries, enabling...
The rechargeable Li-O2 battery has attracted interest due to its high theoretical energy density (ab...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Materials Science and Engineeri...
Non-aqueous electrolytes play a prominent role in the redox reactions of the oxygen electrode in the...
Despite considerable research efforts, finding a chemically stable electrolyte mixture in the presen...
In this work Li-O2 batteries have been investigated. Their theoretical specific energy is 3500 Wh/(k...
Active research on the aprotic Li-air battery has been drawn by its high theoretical energy and powe...
This work investigates the impact of electrochemical reactions and products on discharge capacity an...
This work investigates the impact of electrochemical reactions and products on discharge capacity an...
Identification of electrolytes compatible with both electrodes of a nonaqueous Li/O2 battery is a co...