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Crystal Plane Reconstruction and Thin Protective Coatings Formation for Superior Stable Zn Anodes Cycling 1300 h

Mengke Liu, Jinyan Cai, Jun Xu, Kaiwen Qi, Qianyao Wu, Huaisheng Ao, Tiansheng Zou, Sheng‐Quan Fu, Shuqing Wang, Yongchun Zhu

2022Small23 citationsDOI

Abstract

Abstract Some new insights into traditional metal pretreatment of anticorrosion for high stable Zn metal anodes are provided. A developed pretreatment methodology is employed to prefer the crystal plane of polycrystalline Zn and create 3.26 µm protective coatings mainly consisting of organic polymers and zinc salts on Zn foils (ROZ@Zn). In this process, Zn metal exhibits a surface‐preferred (001) crystal plane proved by electron backscattered diffraction. Preferred (001) crystal planes and ROZ coatings can regulate Zn 2+ diffusion, promote flat growth of Zn, and prevent side reactions. As a result, ROZ@Zn symmetrical cells exhibit superior plating/stripping performance over 1300 h. Impressively, it is significantly prolonged over 40 times in comparison to the bare Zn symmetric cell at 5 mA cm ‐2 . Moreover, Zn//MnO 2 button cells have a high capacity retention of 96.3% after 1600 cycles and pouch cells have a high capacity 122 mAh g ‐1 after 200 cycle at 5 C. This work provides inspiration for high stable aqueous Zn metal batteries using the developed metal pretreatment of anticorrosion, which will be a viable, low‐cost, and efficient technology. More interesting, it demonstrates the availability of reconstructing crystal planes by the largely heterogeneous reaction activation of the different crystal planes to H + .

Topics & Concepts

Materials scienceMetalCrystal (programming language)CrystalliteZincPlating (geology)Stripping (fiber)AnodeChemical engineeringSingle crystalAqueous solutionCrystal growthComposite materialMetallurgyElectrodeCrystallographyChemistryOrganic chemistryComputer scienceProgramming languageEngineeringGeophysicsGeologyPhysical chemistryAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesThermal Expansion and Ionic Conductivity