Fan Xiaotong, Luo Yifei, Li Ke, Wong Yi Jing, Wang Cong, Yeo Jayven Chee Chuan, Yang Gaoliang, Li Jiaofu, Loh Xian Jun, Li Zibiao, Chen Xiaodong
Institute of Sustainability for Chemicals, Energy and Environment (ISCE2), Agency for Science, Technology and Research (A*STAR), 1 Pesek Road, Jurong Island, Singapore, 627833, Republic of Singapore.
Institute of Materials Research and Engineering (IMRE), Agency for Science, Technology and Research (A*STAR), 2 Fusionopolis Way, Singapore, 138634, Republic of Singapore.
Adv Mater. 2024 Nov;36(44):e2407398. doi: 10.1002/adma.202407398. Epub 2024 Sep 14.
Ionogels are an emerging class of soft materials for flexible electronics, with high ionic conductivity, low volatility, and mechanical stretchability. Recyclable ionogels are recently developed to address the sustainability crisis of current electronics, through the introduction of non-covalent bonds. However, this strategy sacrifices mechanical robustness and chemical stability, severely diminishing the potential for practical application. Here, covalent adaptable networks (CANs) are incorporated into ionogels, where dynamic covalent crosslinks endow high strength (11.3 MPa tensile strength), stretchability (2396% elongation at break), elasticity (energy loss coefficient of 0.055 at 100% strain), and durability (5000 cycles of 150% strain). The reversible nature of CANs allows the ionogel to be closed-loop recyclable for up to ten times. Additionally, the ionogel is toughened by physical crosslinks between conducting ions and polymer networks, breaking the common dilemma in enhancing mechanical properties and electrical conductivity. The ionogel demonstrates robust strain sensing performance under harsh mechanical treatments and is applied for reconfigurable multimodal sensing based on its recyclability. This study provides insights into improving the mechanical and electrical properties of ionogels toward functionally reliable and environmentally sustainable bioelectronics.
离子凝胶是一类新兴的用于柔性电子器件的软材料,具有高离子导电性、低挥发性和机械拉伸性。最近,通过引入非共价键开发出了可回收离子凝胶,以应对当前电子产品的可持续性危机。然而,这种策略牺牲了机械强度和化学稳定性,严重降低了实际应用的潜力。在此,将共价自适应网络(CANs)引入离子凝胶中,其中动态共价交联赋予了高机械强度(拉伸强度为11.3兆帕)、拉伸性(断裂伸长率为2396%)、弹性(在100%应变下能量损耗系数为0.055)和耐久性(在150%应变下可循环5000次)。CANs的可逆特性使离子凝胶能够闭环回收多达十次。此外,离子凝胶通过导电离子与聚合物网络之间的物理交联而得到增强,打破了增强机械性能和导电性时的常见困境。该离子凝胶在苛刻的机械处理下表现出强大的应变传感性能,并基于其可回收性应用于可重构多模态传感。这项研究为改善离子凝胶的机械和电学性能以实现功能可靠且环境可持续的生物电子学提供了见解。
