材料科学
储能
电解质
溶剂化
偶极子
纳米技术
离子键合
扩散
离子
化学物理
热力学
物理化学
有机化学
物理
电极
功率(物理)
化学
作者
Yiheng Qi,Chuang Bao,X. D. Li,Jianhua Yan,Kefa Cen,Zheng Bo,Huachao Yang
标识
DOI:10.1002/adma.202509768
摘要
Electrochemical energy storage (EES) devices often exhibit poor low-temperature performance due to high interfacial desolvation energy barriers. While conventional strategies targeting ion-dipole interactions have improved desolvation kinetics, they suffer from a fundamental trade-off with bulk-phase ion diffusion. Here, a dipole-engineered electrolyte paradigm is proposed to overcome desolvation barriers for enhanced ultralow-temperature energy storage. Following this new paradigm, a weakly-dipolar-interacting electrolyte (WDIE) is developed by regulating dipole-dipole interactions within ionic solvates between primary and co-solvents. Through comprehensive experimental characterization and theoretical analyses, the interplay between dipole-dipole interactions and solvation dynamics across both interfacial and bulk phases is elucidated. Specifically, WDIE transforms the ionic solvate from conventional double-layer to distinctive mono-layer with attenuated solvent coordination number, effectively lowering solvent residence time and desolvation energy barriers. Simultaneously, it promotes solvent cluster dissociation, disrupting cross-linked electrolyte networks and enhancing bulk ion diffusion. As a proof of concept, WDIE-based supercapacitors exhibit optimized ultralow temperature performance, which retain 97.15% capacity from 20 to -70 °C, surpassing moderately- and strongly-dipolar-interacting electrolytes and ranking among the best reported. Moreover, theoretical calculations further demonstrate the broad applicability of this strategy when ionic radius exceeds 3.84 Å. This work demonstrates a scalable dipole-engineered electrolyte paradigm to overcome low-temperature EES limitations.
科研通智能强力驱动
Strongly Powered by AbleSci AI