Abstract
AbstractLow capacity, poor rechargeability, and premature cell death are major setbacks in the operation of Li‐O2 battery, hindering its practical application. A promising approach of meeting those challenges is via the use of redox mediators (RMs), promoting Li2O2 solution phase formation upon cell discharge and an efficient oxidation on charging. The use of dual RMs decouples the electrochemical reactions at the cathode with formation/decomposition of Li2O2, resulting in improved discharge capacity, lower charge overpotential, and cycle stability. Although Li‐O2 cell performance is no longer mitigated by an insulating Li2O2, a major inherent barrier to implement viable and functioning Li‐air batteries lies in both limited O2 mass transport and pores clogging. Here, a record discharge capacity of 6 mAh cm−2 (60% increase), by combining dual RMs with “liquid Teflon” type perfluorocarbons binary system, is demonstrated. The combination of the two materials in the cell contributes to the enhanced cell performance manifested also in lower charge overpotential values throughout dozens of cycles. This is also attributed to the unique compact and an exceptionally smooth morphology of the Li2O2 deposit layers at both ends of the air cathode.
Highlights
Low capacity, poor rechargeability, and premature cell death are major discharge, oxygen reduction takes place setbacks in the operation of Li-O2 battery, hindering its practical application
Li-O2 cell performance is no longer mitigated by an insulating Li2O2, a major inherent barrier to implement viable and functioning Li-air batteries lies in both limited O2 mass transport and pores clogging
We present that improved oxygen availability and a better surface area utilization demonstrated extensively higher discharge capacity in tetraethylene glycol dimethyl ether (TEGDME) electrolytes containing both dual redox mediators (RMs) and PFC
Summary
Poor rechargeability, and premature cell death are major discharge, oxygen reduction takes place setbacks in the operation of Li-O2 battery, hindering its practical application. Was reported to form a uniform and intimate Li2O2 deposit, being evident at areas further away from the electrode/gas interface.[25,26,27,28,29,30] Here, we present that improved oxygen availability and a better surface area utilization demonstrated extensively higher discharge capacity in TEGDME electrolytes containing both dual RMs and PFC.
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