Hongkui Zheng scite author profile

Conversion‐type materials have been considered as potentially high‐energy‐density alternatives to commercially dominant intercalation‐based electrodes for rechargeable ion batteries and have attracted tremendous research effort to meet the performance for viable energy‐storage technologies. In situ transmission electron microscopy (TEM) has been extensively employed to provide mechanistic insights into understanding the behavior of battery materials. Noticeably, a great portion of previous in situ TEM studies has been focused on conversion‐type materials, but a dedicated review for this group of materials is missing in the literature. Herein, recent developments of in situ TEM techniques for investigation of dynamic phase transformation and associated structural, morphological, and chemical evolutions during conversion reactions with alkali ions in secondary batteries are comprehensively summarized. The materials of interest broadly cover metal oxides, chalcogenides, fluorides, phosphides, nitrides, and silicates with specific emphasis on spinel metal oxides and recently emerged 2D metal chalcogenides. Special focus is placed on the scientific findings that are uniquely obtained by in situ TEM to address fundamental questions and practical issues regarding phase transformation, structural evolution, electrochemical redox, reaction mechanism, kinetics, and degradation. Critical challenges and perspectives are discussed for advancing new knowledge that can bridge the gap between prototype materials and real‐world applications.

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Erratum: Spin-ordering and magnetoelastic coupling in the extended kagome system YBaCo4O7[Phys. Rev. B83, 094412 (2011)]

Khalyavin¹,

Manuel²,

Ouladdiaf³

et al. 2011

Phys. Rev. B

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Origin of anomalous high-rate Na-ion electrochemistry in layered bismuth telluride anodes

Cui

Zheng

Zhang

et al. 2021

Matter

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In situ transmission electron microscopy and artificial intelligence enabled data analytics for energy materials

Zheng

2022

Journal of Energy Chemistry

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Hongkui Zheng

A high-entropy phosphate catalyst for oxygen evolution reaction

In Situ TEM Study on Conversion‐Type Electrodes for Rechargeable Ion Batteries

Erratum: Spin-ordering and magnetoelastic coupling in the extended kagome system YBaCo4O7[Phys. Rev. B83, 094412 (2011)]

Origin of anomalous high-rate Na-ion electrochemistry in layered bismuth telluride anodes

In situ transmission electron microscopy and artificial intelligence enabled data analytics for energy materials

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