论文信息 - Oxygen-selective immobilized liquid membranes for operation of lithium-air batteries in ambient air

Oxygen-selective immobilized liquid membranes for operation of lithium-air batteries in ambient air

Abstract In this work, nonaqueous electrolyte-based Li-air batteries with an O 2 -selective membrane have been developed for operation in ambient air of 20–30% relative humidity (RH). The O 2 gas is continuously supplied through a membrane barrier layer at the interface of the cathode and ambient air. The membrane allows O 2 to permeate through while blocking moisture. Such membranes can be prepared by loading O 2 -selective silicone oils into porous supports such as porous metal sheets and Teflon (PTFE) films. It was found that the silicone oil of high viscosity shows better performance. The immobilized silicone oil membrane in the porous PTFE film enabled the Li-air batteries with carbon black air electrodes to operate in ambient air (at 20% RH) for 16.3 days with a specific capacity of 789 mAh g −1 carbon and a specific energy of 2182 Wh kg −1 carbon. Its performance is much better than a reference battery assembled with a commercial, porous PTFE diffusion membranes as the moisture barrier layer on the cathode, which only had a discharge time of 5.5 days corresponding to a specific capacity of 267 mAh g −1 carbon and a specific energy of 704 Wh kg −1 carbon. The Li-air battery with the present selective membrane barrier layer even showed better performance in ambient air operation (20% RH) than the reference battery tested in the dry air box (

[1] M. Salomon,et al. Li-air batteries: A classic example of limitations owing to solubilities , 2007 .

[2] Yongyao Xia,et al. The effect of oxygen pressures on the electrochemical profile of lithium/oxygen battery , 2009 .

[3] D. Poncelet,et al. Enhancement of oxygen transfer rate using microencapsulated silicone oils as oxygen carriers , 1997 .

[4] P. Cloirec,et al. Mass transfer coefficients of styrene and oxygen into silicone oil emulsions in a bubble reactor , 2006 .

[5] K. M. Abraham,et al. A Polymer Electrolyte‐Based Rechargeable Lithium/Oxygen Battery , 1996 .

[6] Ji-Guang Zhang,et al. Air electrode design for sustained high power operation of Li/air batteries , 2009 .

[7] Wu Xu,et al. Optimization of Nonaqueous Electrolytes for Primary Lithium/Air Batteries Operated in Ambient Environment , 2009 .

[8] Jing Kong,et al. Superwetting nanowire membranes for selective absorption. , 2008, Nature nanotechnology.

[9] Jeffrey Read,et al. Discharge characteristic of a non-aqueous electrolyte Li/O2 battery , 2010 .

[10] D. Poncelet,et al. Microencapsulation of silicone oils within polyamide—polyethylenimine membranes as oxygen carriers for bioreactor oxygenation , 2007 .

[11] Wu Xu,et al. Optimization of Air Electrode for Li/Air Batteries , 2010 .

[12] D. Linden. Handbook Of Batteries , 2001 .