Anming Hu

University of Tennessee

High Performance Aluminum-Air Flow Batteries through Laser-Modified and Friction-stir Processed 3D Anode and High Effective Catalysis

Aluminum-air batteries (AAB) are regarded as one of the most promising beyond-lithium high-energy-density storage candidates. This talk introduces a three-dimensional (3D) Al7075 anode enabled by femtosecond laser and friction-stir processed (FSP) which, along with a special double-face anode architecture provides world-class performance. Electrochemical characterizations prove that the corrosion resistance of the modified 3D Al7075 FSP anode was enhanced, and electrochemically active surface area (ECSA) was increased compared with that of normal Al 7075 anode. Friction-stir processing reduced the mean grain size from 30 μm to 3 μm. Various catalysts were further investigated in MXene supporting air cathode. The discharge performance of 3D Al7075 FSP anode is shown to be quite stable, and the average values of energy density are significantly increased from 2256 mWh g-1 to 2941 mWh g-1 at 100 mA cm-2. In a double-face flowing Al-air battery system, the 3D Al7075 FSP anode exhibited significantly better electrocatalytic performance (discharge voltage of 0.76 V at 400 mA cm-2, and power density of 338 mW cm-2) than that of a commercial Al 7075 anode.

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