Spatiotemporal Resolution of Phase Formation in Thick Porous Sodium Vanadium Oxide (NaVO) Electrodes Via Energy Dispersive X-ray Diffraction

Overview

Journal J Phys Chem C Nanomater Interfaces

Publisher American Chemical Society

Date 2023 Mar 10

PMID 36895658

Authors

Gurpreet Singh

Christopher R Tang

Andrew Nicoll

Jonah Torres

Lisa M Housel

Lei Wang

Kenneth J Takeuchi

Esther S Takeuchi

Amy C Marschilok

Affiliations

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Abstract

Herein, zinc vanadium oxide (ZVO) and zinc hydroxy-sulfate (ZHS) formation as discharge products in sodium vanadium oxide (NVO) cathode materials of two distinct morphologies, NVO(300) and NVO(500), is studied with and X-ray diffraction methods. ZHS formation upon discharge is shown to be favored at higher current densities and reversible upon charge, while ZVO formation is found to be favored at lower current densities but persists throughout cycling. synchrotron-based energy dispersive X-ray diffraction (EDXRD) reveals reversible expansion of the NVO lattice due to Zn during discharge, spontaneous ZVO formation following cell assembly, and ZHS formation concomitant with H insertion at potentials less than ∼0.8 V vs Zn/Zn. With spatially resolved EDXRD, ZVO formation is show to occur near the separator region first, eventually moving to the current collector region as discharge depth increases. ZHS formation, however, is found to originate from the current collector side of the positive electrode and then propagate through the porous electrode network. This study highlights the special benefits of the EDXRD method to gain mechanistic insight into structural evolution within the electrode and at its interface.

Citing Articles

Controlling Electrodeposition in Nonplanar High Areal Capacity Battery Anodes via Charge Transport and Chemical Modulation.

Tang T, Zheng J, Archer L JACS Au. 2024; 4(4):1365-1373.

PMID: 38665677 PMC: 11040661. DOI: 10.1021/jacsau.3c00721.

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