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Understanding rate-dependent textured growth in zinc electrodeposition via high-throughput in situ x-ray diffraction

Yifan Ma, Jakub Pepas, Guangxing Zhang, Zhaonan Liu, Yang Su, Jianming Bai, Hongjie Zhong, Tianyi Li, Wenqian Xu, Minju Kang, John E. Carsley, Josh Kacher, Hailong Chen

2025Nature Communications18 citationsDOIOpen Access PDF

Abstract

Zn-ion batteries with aqueous electrolytes are promising for large-scale energy storage as they are low-cost, environment-friendly and safe. The commercialization of Zn-ion batteries is hindered by several challenges such as the formation of detrimental Zn dendrites. High current density is previously thought to stimulate the dendritic growth of metals such as Li in electrodeposition. However, our study finds that for metallic Zn negative electrode in Zn-ion batteries, high-current deposition results in a dense and flat Zn layer with a (002) texture, which extends the cycling life. Low-current deposition, on the other hand, leads to a porous and dendritic morphology and a short cycling life. Using a synchrotron-based high-throughput in situ X-ray diffraction method we recently developed, Zn deposition under different conditions is systematically investigated, and a texture formation mechanism is proposed. Based on these findings, we suggest guidelines for designing cycling protocols that enable long-lasting Zn-ion batteries. Zinc-ion batteries face challenges like dendrite formation, limiting their performance. Here, authors reveal that high-current deposition forms (002) textured Zn, enhancing cycling life, and propose guidelines for optimizing battery cycling protocols based on advanced in situ XRD analysis.

Topics & Concepts

Materials scienceElectrolyteTexture (cosmology)Deposition (geology)PorosityElectrodeChemical engineeringSynchrotronNanotechnologyIn situAqueous solutionZincDiffractionElectroplatingLayer (electronics)MetallurgyChemistryComputer scienceComposite materialOpticsPhysicsEngineeringBiologyPhysical chemistrySedimentPaleontologyOrganic chemistryImage (mathematics)Artificial intelligenceAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesPerovskite Materials and Applications
Understanding rate-dependent textured growth in zinc electrodeposition via high-throughput in situ x-ray diffraction | Litcius