Highly Reversible Zn Metal Anodes Enabled by Increased Nucleation Overpotential

被引:80
作者
Hu, Zhengqiang [1 ]
Zhang, Fengling [1 ]
Zhou, Anbin [1 ]
Hu, Xin [1 ]
Yan, Qiaoyi [1 ]
Liu, Yuhao [1 ]
Arshad, Faiza [1 ]
Li, Zhujie [3 ]
Chen, Renjie [1 ,2 ,3 ]
Wu, Feng [1 ,2 ,3 ]
Li, Li [1 ,2 ,3 ]
机构
[1] Beijing Inst Technol, Sch Mat Sci & Engn, Beijing Key Lab Environm Sci & Engn, Beijing 100081, Peoples R China
[2] Collaborat Innovat Ctr Elect Vehicles Beijing, Beijing 100081, Peoples R China
[3] Beijing Inst Technol, Adv Technol Res Inst, Jinan 250300, Peoples R China
来源
NANO-MICRO LETTERS | 2023年 / 15卷 / 01期
基金
北京市自然科学基金; 中国国家自然科学基金;
关键词
Nucleation overpotential; Complexing agent; Zn batteries; Zn deposition; ION BATTERIES; ELECTROCRYSTALLIZATION; ELECTROLYTES; INTERFACE; MECHANISM;
D O I
10.1007/s40820-023-01136-z
中图分类号
TB3 [工程材料学];
学科分类号
0805 ; 080502 ;
摘要
Dendrite formation severely compromises further development of zinc ion batteries. Increasing the nucleation overpotential plays a crucial role in achieving uniform deposition of metal ions. However, this strategy has not yet attracted enough attention from researchers to our knowledge. Here, we propose that thermodynamic nucleation overpotential of Zn deposition can be boosted through complexing agent and select sodium L-tartrate (Na-L) as example. Theoretical and experimental characterization reveals L-tartrate anion can partially replace H2O in the solvation sheath of Zn2+, increasing de-solvation energy. Concurrently, the Na+ could absorb on the surface of Zn anode preferentially to inhibit the deposition of Zn2+ aggregation. In consequence, the overpotential of Zn deposition could increase from 32.2 to 45.1 mV with the help of Na-L. The Zn-Zn cell could achieve a Zn utilization rate of 80% at areal capacity of 20 mAh cm(-2). Zn-LiMn2O4 full cell with Na-L additive delivers improved stability than that with blank electrolyte. This study also provides insight into the regulation of nucleation overpotential to achieve homogeneous Zn deposition.
引用
收藏
页数:13
相关论文
共 59 条
[41]   Interface Engineering via Ti3C2Tx MXene Electrolyte Additive toward Dendrite-Free Zinc Deposition [J].
Sun, Chuang ;
Wu, Cuiping ;
Gu, Xingxing ;
Wang, Chao ;
Wang, Qinghong .
NANO-MICRO LETTERS, 2021, 13 (01)
[42]   Simultaneous Regulation on Solvation Shell and Electrode Interface for Dendrite-Free Zn Ion Batteries Achieved by a Low-Cost Glucose Additive [J].
Sun, Peng ;
Ma, Liang ;
Zhou, Wanhai ;
Qiu, Meijia ;
Wang, Zilong ;
Chao, Dongliang ;
Mai, Wenjie .
ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2021, 60 (33) :18247-18255
[43]   Inhibiting Dendrite Growth via Regulating the Electrified Interface for Fast-Charging Lithium Metal Anode [J].
Wang, Xinyang ;
Chen, Ming ;
Li, Siyuan ;
Zhao, Chang ;
Zhang, Weidong ;
Shen, Zeyu ;
He, Yi ;
Feng, Guang ;
Lu, Yingying .
ACS CENTRAL SCIENCE, 2021, 7 (12) :2029-2038
[44]   Cyclohexanedodecol-Assisted Interfacial Engineering for Robust and High-Performance Zinc Metal Anode [J].
Wu, Zhenzhen ;
Li, Meng ;
Tian, Yuhui ;
Chen, Hao ;
Zhang, Shao-Jian ;
Sun, Chuang ;
Li, Chengpeng ;
Kiefel, Milton ;
Lai, Chao ;
Lin, Zhan ;
Zhang, Shanqing .
NANO-MICRO LETTERS, 2022, 14 (01)
[45]   Manipulating the ion-transfer kinetics and interface stability for high-performance zinc metal anodes [J].
Xie, Xuesong ;
Liang, Shuquan ;
Gao, Jiawei ;
Guo, Shan ;
Guo, Jiabao ;
Wang, Chao ;
Xu, Guiyin ;
Wu, Xianwen ;
Chen, Gen ;
Zhou, Jiang .
ENERGY & ENVIRONMENTAL SCIENCE, 2020, 13 (02) :503-510
[46]   Quasi-Solid Electrolyte Interphase Boosting Charge and Mass Transfer for Dendrite-Free Zinc Battery [J].
Xu, Xueer ;
Xu, Yifei ;
Zhang, Jingtong ;
Zhong, Yu ;
Li, Zhongxu ;
Qiu, Huayu ;
Wu, Hao Bin ;
Wang, Jie ;
Wang, Xiuli ;
Gu, Changdong ;
Tu, Jiangping .
NANO-MICRO LETTERS, 2023, 15 (01)
[47]   Reducing Water Activity by Zeolite Molecular Sieve Membrane for Long-Life Rechargeable Zinc Battery [J].
Yang, Huijun ;
Qiao, Yu ;
Chang, Zhi ;
Deng, Han ;
Zhu, Xingyu ;
Zhu, Ruijie ;
Xiong, Zetao ;
He, Ping ;
Zhou, Haoshen .
ADVANCED MATERIALS, 2021, 33 (38)
[48]   Zinc Anode for Mild Aqueous Zinc-Ion Batteries: Challenges, Strategies, and Perspectives [J].
Yang, Jinzhang ;
Yin, Bosi ;
Sun, Ying ;
Pan, Hongge ;
Sun, Wenping ;
Jia, Baohua ;
Zhang, Siwen ;
Ma, Tianyi .
NANO-MICRO LETTERS, 2022, 14 (01)
[49]   Hydrated Eutectic Electrolytes with Ligand-Oriented Solvation Shells for Long-Cycling Zinc-Organic Batteries [J].
Yang, Wuhai ;
Du, Xiaofan ;
Zhao, Jingwen ;
Chen, Zheng ;
Li, Jiajia ;
Xie, Jian ;
Zhang, Yaojian ;
Cui, Zili ;
Kong, Qingyu ;
Zhao, Zhiming ;
Wang, Cunguo ;
Zhang, Qichun ;
Cui, Guanglei .
JOULE, 2020, 4 (07) :1557-1574
[50]   Lithium Salt Dissociation Promoted by 18-Crown-6 Ether Additive toward Dilute Electrolytes for High Performance Lithium Oxygen Batteries [J].
Zhang, Fengling ;
Lai, Jingning ;
Hu, Zhengqiang ;
Zhou, Anbin ;
Wang, Huirong ;
Hu, Xin ;
Hou, Lijuan ;
Li, Bohua ;
Sun, Wen ;
Chen, Nan ;
Li, Li ;
Wu, Feng ;
Chen, Renjie .
ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2023, 62 (16)
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