Yizhe Shao , Chao Dang , Haobo Qi , Ziyang Liu , Haoran Pei , Tongqing Lu , Wei Zhai
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引用次数: 0
摘要
共晶凝胶由饱和深共晶溶剂(DES)的三维聚合物网络组成,是一种前景广阔的软离子导体。我们提出了一种由植酸(PA)和氯化胆碱(ChCl)组成的新型 DES 系统,而不是对聚合物链进行改性,它能增强与聚合物网络的动态互动结合,从而创造出创新的共晶凝胶。在这里,我们采用蒸发诱导限制策略,将聚乙烯醇(PVA)网络与我们的 DES 一起封装,从而开发出多功能共晶凝胶(PETGs)。实验验证和数值计算表明,聚酰胺与 PVA 形成了高密度的动态氢键,同时屏蔽了 PVA 链之间的氢键。这就形成了一个无法检测到结晶区域的多重氢键屏蔽无定形网络(MHSN),从而促进了离子迁移,确保了高导电性。此外,由于 MHSN 的存在,我们的 PETG 还具有快速自愈合、抗冻性、自粘性、抗菌性和双重敏感性。我们展示了 PETG 在运动传感、机器学习、人机交互和能量收集方面的应用潜力。
Polyfunctional eutectogels with multiple hydrogen-bond-shielded amorphous networks for soft ionotronics
Eutectogels, consisting of three-dimensional polymeric networks saturated with deep eutectic solvents (DESs), present a promising option for soft ionic conductors. Instead of modifying polymer chains, we propose a new DES system comprising phytic acid (PA) and choline chloride (ChCl), which enhances dynamic and interactive bonding with polymeric networks to create innovative eutectogels. Here, we develop polyfunctional eutectogels (PETGs) by encapsulating polyvinyl alcohol (PVA) networks with our DES using an evaporation-induced confinement strategy. Experimental validation and numerical calculations demonstrate that PA forms high-density dynamic hydrogen bonds with PVA while shielding hydrogen bonds between PVA chains. This results in a multiple hydrogen-bond-shielded amorphous network (MHSN) with undetectable crystalline regions, thereby promoting ion migration to ensure high conductivity. Moreover, our PETG exhibits rapid self-healing, freeze resistance, self-adhesion, antibacterial properties, and dual sensitivities attributable to the MHSN. We demonstrate the potential of PETGs for applications in motion sensing, machine learning, human-machine interaction, and energy harvesting.
期刊介绍:
Matter, a monthly journal affiliated with Cell, spans the broad field of materials science from nano to macro levels,covering fundamentals to applications. Embracing groundbreaking technologies,it includes full-length research articles,reviews, perspectives,previews, opinions, personnel stories, and general editorial content.
Matter aims to be the primary resource for researchers in academia and industry, inspiring the next generation of materials scientists.
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