基于阴离子陷阱工程实现锌离子电池显著的晶体学取向和高效的阳离子迁移

Anion-Trap Engineering toward Remarkable Crystallographic Reorientation and Efficient Cation Migration of Zn Ion Batteries.

作者信息

Qiu Meijia, Sun Peng, Wang Yu, Ma Liang, Zhi Chunyi, Mai Wenjie

机构信息

Siyuan Laboratory, Guangzhou Key Laboratory of Vacuum Coating Technologies and New Energy Materials, Guangdong Provincial Engineering Technology Research Center of Vacuum Coating Technologies and New Energy Materials, Department of Physics, Jinan University, Guangdong, 510632, P. R. China.

Department of Materials Science and Engineering, City University of Hong Kong, 83 Tat Chee Avenue, Kowloon, Hong Kong, 999077, P. R. China.

出版信息

Angew Chem Int Ed Engl. 2022 Nov 2;61(44):e202210979. doi: 10.1002/anie.202210979. Epub 2022 Sep 14.

DOI:10.1002/anie.202210979

PMID:36036743

Abstract

Zn batteries are considered as potential candidates in future power sources, however suffer problems of rampant dendrite/by-product on Zn anodes, torpid Zn transfer/diffusion and poor energy density. Inspired by the host-guest interaction chemistry, an anion-trap agent β-cyclodextrin (β-CD) is introduced into the Zn(ClO ) electrolyte to induce dominant Zn (002) deposition and improve Zn migration behaviors. The anion ClO is revealed to be trapped inside the cavity of β-CD, impairing barriers for Zn migration and significantly elevating the Zn transference number to 0.878. Meanwhile, the β-CD@ClO complex shows the function in preferential growth of the Zn (002), blocking the approach of dendrite growth. Above combined functions lead to substantial enhancement in long-term stability and cell capacity, as proved by 10 times longer life of Zn||Zn symmetric cells and 57 % capacity increasement of Zn-MnO full cells (at 0.1 A g ) compared with that of pure Zn(ClO ) electrolyte.

摘要

锌电池被认为是未来电源的潜在候选者，然而，锌阳极上存在枝晶/副产物泛滥、锌转移/扩散迟缓以及能量密度低等问题。受主客体相互作用化学的启发，将一种阴离子捕获剂β-环糊精（β-CD）引入到Zn(ClO )电解液中，以诱导主要的Zn(002)沉积并改善锌的迁移行为。研究发现，阴离子ClO 被困在β-CD的腔内，削弱了锌迁移的障碍，并将锌迁移数显著提高到0.878。同时，β-CD@ClO 络合物显示出对Zn(002)优先生长的作用，阻止了枝晶生长的途径。上述综合作用导致长期稳定性和电池容量大幅提高，与纯Zn(ClO )电解液相比，Zn||Zn对称电池的寿命延长了10倍，Zn-MnO全电池（在0.1 A g 下）的容量增加了57 %，证明了这一点。

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基于阴离子陷阱工程实现锌离子电池显著的晶体学取向和高效的阳离子迁移

Anion-Trap Engineering toward Remarkable Crystallographic Reorientation and Efficient Cation Migration of Zn Ion Batteries.

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