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Potentiodynamics of the Zinc and Proton Storage in Disordered Sodium Vanadate for Aqueous Zn-Ion Batteries

Xiaoqiang Shan, SaeWon Kim, Milinda Abeykoon, Gihan Kwon, Daniel Olds, Xiaowei Teng

2020ACS Applied Materials & Interfaces69 citationsDOIOpen Access PDF

Abstract

A rechargeable Zn-ion battery is a promising aqueous system, where coinsertion of Zn2+ and H+ could address the obstacles of the sluggish ionic transport in cathode materials imposed by multivalent battery chemistry. However, there is a lack of fundamental understanding of this dual-ion transport, especially the potentiodynamics of the storage process. Here, a quantitative analysis of Zn2+ and H+ transport in a disordered sodium vanadate (NaV3O8) cathode material has been reported. Collectively, synchrotron X-ray analysis shows that both Zn2+ and H+ storages follow an intercalation storage mechanism in NaV3O8 and proceed in a sequential manner, where intercalations of 0.26 Zn2+ followed by 0.24 H+ per vanadium atom occur during discharging, while reverse dynamics happens during charging. Such a unique and synergistic dual-ion sequential storage favors a high capacity (265 mA h g–1) and an energy density (221 W h kg–1) based on the NaV3O8 cathode and a great cycling life (a capacity retention of 78% after 2000 cycles) in Zn/NaV3O8 full cells.

Topics & Concepts

Materials scienceAqueous solutionVanadateZincIonSodiumProtonInorganic chemistryChemical engineeringMetallurgyChemistryOrganic chemistryEngineeringPhysicsQuantum mechanicsAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesAdvancements in Battery Materials
Potentiodynamics of the Zinc and Proton Storage in Disordered Sodium Vanadate for Aqueous Zn-Ion Batteries | Litcius