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Reviving Zn<sup>0</sup> Dendrites to Electroactive Zn<sup>2+</sup> by Mesoporous MXene with Active Edge Sites

Fanxing Bu, Zhihao Sun, Wanhai Zhou, Yanyan Zhang, Yongjin Chen, Bing Ma, Xiaoxu Liu, Pei Liang, Chenglin Zhong, Ruizheng Zhao, Hongpeng Li, Lipeng Wang, Tengsheng Zhang, Boya Wang, Zaiwang Zhao, Jie Zhang, Wei Li, Yasseen S. Ibrahim, Yasser A. Hassan, Ahmed A. Elzatahry, Dongliang Chao, Dongyuan Zhao

2023Journal of the American Chemical Society166 citationsDOI

Abstract

Zinc metal-based aqueous batteries (ZABs) offer a sustainable, affordable, and safe energy storage alternative to lithium, yet inevitable dendrite formation impedes their wide use, especially under long-term and high-rate cycles. How the battery can survive after dendrite formation remains an open question. Here, we pivot from conventional Zn dendrite growth suppression strategies, introducing proactive dendrite-digesting chemistry via a mesoporous Ti 3 C 2 MXene (MesoTi 3 C 2 )-wrapped polypropylene separator. Spectroscopic characterizations and electrochemical evaluation demonstrate that MesoTi 3 C 2, acting as an oxidant, can revive the formed dead Zn 0 dendrites into electroactive Zn 2+ ions through a spontaneous redox process. Density functional theory reveals that the abundant edge-Ti–O sites in our MesoTi 3 C 2 facilitate high oxidizability and electron transfer from Zn 0 dendrites compared to their in-plane counterparts. The resultant asymmetrical cell demonstrates remarkable ultralong cycle life of 2200 h at a practical current of 5 mA cm –2 with a low overpotential (<50 mV). The study reveals the unexpected edge effect of mesoporous MXenes and uncovers a new proactive dendrite-digesting chemistry to survive ZABs, albeit with inevitable dendrite formation.

Topics & Concepts

OverpotentialChemistryMesoporous materialDendrite (mathematics)ElectrochemistryElectron transferNanotechnologyChemical engineeringElectrodeMaterials sciencePhotochemistryCatalysisPhysical chemistryOrganic chemistryMathematicsEngineeringGeometryAdvanced battery technologies researchMXene and MAX Phase MaterialsAdvanced Battery Materials and Technologies