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Article Abstract
Developing fast-charging Zn-air batteries is crucial for widening their application but remains challenging owing to the limitation of sluggish oxygen evolution reaction (OER) kinetics and insufficient active sites of electrocatalysts. To solve this issue, a reconstructed amorphous FeCoNiS electrocatalyst with high density of efficient active sites, yielding low OER overpotentials of 202, 255, and 323 mV at 10, 100, and 500 mA cm , respectively, is developed for fast-charging Zn-air batteries with low charging voltages at 100-400 mA cm . Furthermore, the fabricated 3241.8 mAh (20 mA cm , 25 °C) quasi-solid Zn-air battery shows long lifetime of 500 h at -10 and 25 °C as well as 150 h at 40 °C under charging 100 mA cm . The detailed characterizations combine with density functional theory calculations indicate that the defect-rich crystalline/amorphous ternary metal (oxy)hydroxide forms by the reconstruction of amorphous multi-metallic sulfide, where the electron coupling effect among multi-active sites and migration of intermediate O* from Ni site to the Fe site breaks the scaling relationship to lead to a low theoretical OER overpotential of 170 mV, accounting for the outstanding fast-charging property. This work not only provides insights into designing advanced OER catalysts by the self-reconstruction of the pre-catalyst but also pioneers a pathway for practical fast-charging Zn-air batteries.
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Article Synopsis
- Developing efficient electrocatalysts is key for fast-charging Zn-air batteries, as traditional oxygen evolution reactions (OER) are slow and lack enough active sites.
- A new amorphous FeCoNiS electrocatalyst has been created, demonstrating low OER overpotentials and enabling fast charging with low voltage requirements.
- The resulting quasi-solid Zn-air battery shows impressive capacity and longevity, performing well under various temperatures and charge conditions, while advanced methods reveal how its unique structure contributes to improved charging efficiency.
In Situ Anchoring Co-N-C Nanoparticles on Co N Nanosheets toward Ultrastable Flexible Self-Supported Bifunctional Oxygen Electrocatalyst Enables Recyclable Zn-Air Batteries Over 10 000 Cycles and Fast Charging.
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Building Energy Research Group, Department of Building and Real Estate, Research Institute for Sustainable Urban Development (RISUD) and Research Institute for Smart Energy (RISE), The Hong Kong Polytechnic University, Hung Hom, Kowloon, Hong Kong, 999077, China.
Zn-air batteries (ZABs) are very promising for flexible energy storage, but their application is limited to the primary battery. Developing an efficient and non-noble metal cathode toward oxygen reduction/evolution reactions (ORR/OER) is of great significance for the commercial application of rechargeable ZABs. Herein, a flexible self-supported integrated bifunctional cathode is presented in which the Co-N-C nanoparticles are in situ anchored on Co N nanosheets via a facile and scalable strategy.
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