Energy & Environmental Science, 9, 663-670.ħ.Fu, J., Lee, D. W.* (2016) A flexible solid-state electrolyte for wide-scale integration of rechargeable zinc-air batteries. W.* (2016) Flexible rechargeable zinc-air batteries through morphological emulation of human hair array.
W.* (2017) Electrically rechargeable zinc-air batteries: progress, challenges and perspectives.
W.* (2017) Defect Engineering of Chalcogen-Tailored Oxygen Electrocatalysts for Rechargeable Quasi-Solid-State Zinc Air Batteries. Advanced Materials, 31, 1805230.Ģ.Liu, J., Peng, L., Zhou, Y., Lv, L.,* Fu, J.,* Lin, J., Guay, D., Qiao, J.* (2019) Metal-organic frameworks derived Cu/Cu2O catalyst with ultrahigh current density for continuous-flow CO2 electroreduction, ACS Sustainable Chemistry & Engineering, 7 (18), 15739-15746.ģ.Fu, J., Hassan, F. W.* (2019) Recent Progress in Electrically Rechargeable Zinc–Air Batteries. She strives to understand material structures and properties at solid/liquid interfaces under electrochemical conditions and to establish design principles for new and improved battery materials and electrocatalysts for the electrochemical conversion reactions of oxygen, carbon dioxide, water and zinc.ġ.Bifunctional electrocatalysts for rechargeable zinc-air batteriesĢ.Advanced zinc electrodes for zinc ion batteriesģ.Solid electrolytes for flexible batteriesġ.Fu, J., Liang, R., Liu, G., Yu, A., Bai, Z.,* Yang, L., Chen, Z. Her current research interest is to employ electrochemistry, materials science and nanotechnology to tackle the challenges in electrochemical energy storage and conversion.
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