生物电子学
材料科学
纳米技术
热稳定性
纤维素
离子液体
热电效应
柔性电子器件
离子键合
超级电容器
数码产品
离子电导率
热电材料
离子强度
塞贝克系数
桥接(联网)
生物相容性材料
细菌纤维素
储能
能量收集
自组装
生物相容性
机械强度
表征(材料科学)
工作(物理)
热导率
化学工程
相容性(地球化学)
人工肌肉
热稳定性
电导率
温度梯度
大气温度范围
灵敏度(控制系统)
电压
智能材料
热的
印刷电子产品
作者
Xiaona Li,Zhihan Tong,Yuxuan Qiu,Zihao Zheng,Suqing Zeng,Dawei Zhao,Haipeng Yu
标识
DOI:10.1038/s41467-025-64966-y
摘要
Cellulose-based ionogels are promising for flexible electronics and energy devices, yet their performance is often constrained by the trade-offs among mechanical robustness, ionic conductivity, and thermal stability. Here, we propose a synergistic strategy that integrates dual-ions complexation with crystallization-induced molecular assembly to fabricate a cellulose ionogel. This strategy results in a comprehensive ionogel (noted as Cry-gel) with high mechanical strength (2.3 MPa in tension and 5.3 MPa in compression) and high ionic conductivity (96.8 mS cm-1). Moreover, the Cry-gel can maintain impressive structural stability across a temperature range of -40 to 80 °C. Flexible thermoelectric devices and smart sensors derived from Cry-gels demonstrate a voltage of 0.28 V at a temperature gradient of 60 K, an impressive Seebeck coefficient of 6 mV K-1, and high sensitivity to pressure, temperature, touch, and human pulse. This work provides a paradigm for creating multifunctional sustainable materials, effectively bridging the gap between high-performance ionogels and their applications in cutting-edge bioelectronics and energy harvesting systems.
科研通智能强力驱动
Strongly Powered by AbleSci AI