Concentration polarization induced phase rigidification in ultralow salt colloid chemistry to stabilize cryogenic Zn batteries

The breakthrough in electrolyte technology stands as a pivotal factor driving the battery revolution forward. The colloidal electrolytes, as one of the emerging electrolytes, will arise gushing research interest due to their complex colloidal behaviors and mechanistic actions at different conditions...

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Bibliographic Details
Published in:Nature communications 2024-11, Vol.15 (1), p.9465-16, Article 9465
Main Authors: Hao, Baojiu, Zhou, Jinqiu, Yang, Hao, Zhu, Changhao, Wang, Zhenkang, Liu, Jie, Yan, Chenglin, Qian, Tao
Format: Article
Language:English
Subjects:
119/118
140/133
147/135
147/3
639/4077/4079/891
639/638/161/891
Aqueous electrolytes
Cathodic polarization
Coalescence
Colloid chemistry
Electrolytes
Electrolytic cells
Freezing
Freezing point
Humanities and Social Sciences
Interface stability
Melting points
Metal concentrations
multidisciplinary
Multilayers
Nonaqueous electrolytes
Polarization
Salts
Science
Science (multidisciplinary)
Side reactions
Zinc
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Summary:The breakthrough in electrolyte technology stands as a pivotal factor driving the battery revolution forward. The colloidal electrolytes, as one of the emerging electrolytes, will arise gushing research interest due to their complex colloidal behaviors and mechanistic actions at different conditions (aqueous/nonaqueous solvents, salt concentrations etc.). Herein, we show “beyond aqueous” colloidal electrolytes with ultralow salt concentration and inherent low freezing points to investigate its underlying mechanistic principles to stabilize cryogenic Zn metal batteries. Impressively, the “seemingly undesired” concentration polarization at the interface would disrupt the coalescence stability of the electrolyte, leading to a mechanically rigid interphase of colloidal particle-rich layer, positively inhibiting side reactions on either side of the electrodes. Importantly, the multi-layered pouch cells with cathode loading of 10 mg cm –2 exhibit undecayed capacity at various temperatures, and a relatively high capacity of 50 mAh g –1 could be well maintained at −80 °C. Here, the authors design a “beyond aqueous” colloidal electrolyte with ultralow salt concentration and inherent low freezing point and investigate its colloidal behaviors and underlying mechanistic principles to stabilize cryogenic Zn metal battery.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-024-53885-z