Cui Hongyu, Gao Ming, Cao Guoqin, Liu Fanfan, Hu Junhua, Ban Jinjin
School of Materials Science and Engineering, State Center for International Cooperation on Designer Low-Carbon & Environmental Materials (CDLCEM), Zhengzhou University, Zhengzhou, Henan, 450001, P. R. China.
School of Computational Science and Electronics, Hunan Institute of Engineering, Xiangtan, 411104, P. R. China.
Adv Sci (Weinh). 2024 Aug;11(29):e2402005. doi: 10.1002/advs.202402005. Epub 2024 May 30.
The application of portable aluminum-air batteries (AABs) in extreme environments is an inevitable demand for future development. Aqueous electrolyte freezing is a major challenge for low-temperature operations. Conventionally, enlightened by the organic system in metal ion batteries, blindly increasing the concentration is regarded as an efficient technique to reduce the freezing point (FP). However, the underlying contradiction between the adjusting mechanism of the FP and OH transportation is ignored. Herein, the aqueous alkali solution of CsOH is researched as a prototype to disclose the intrinsic conductive behavior and related solvent structure evolution. Different from these inorganic electrolyte systems, the concept of a critical anti-freezing concentration (CFC) is proposed based on a specific temperature. The relationship between hydrogen bond reconstruction and de-solvation behavior is analyzed. A high conductivity is obtained at -30 °C, which is also a recorded value in an intrinsic aqueous AAB. The homogenous dissolution of the Al anode is also observed. As a general rule, the CFC concept is also applied in both the KOH and NaOH systems.
便携式铝空气电池(AABs)在极端环境中的应用是未来发展的必然需求。水性电解质冻结是低温运行面临的主要挑战。传统上,受金属离子电池中有机体系的启发,盲目提高浓度被视为降低冰点(FP)的有效技术。然而,冰点调节机制与OH传输之间的潜在矛盾被忽视了。在此,以CsOH的碱水溶液为原型进行研究,以揭示其本征导电行为及相关溶剂结构演变。与这些无机电解质体系不同,基于特定温度提出了临界抗冻浓度(CFC)的概念。分析了氢键重构与去溶剂化行为之间的关系。在-30°C时获得了高电导率,这也是本征水性AAB中的记录值。还观察到Al阳极的均匀溶解。一般来说,CFC概念也适用于KOH和NaOH体系。
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