材料科学
表面改性
复合数
软物质
纳米技术
密度泛函理论
聚合物
水溶液
离子键合
纳米片
纳米复合材料
石墨烯
化学工程
弹性体
自愈水凝胶
氢氧化物
剥脱关节
粘弹性
胶体
纳米材料
钛酸酯
双层
离子强度
氮化硼
原位聚合
吸附
纳米颗粒
堆积
混合材料
作者
Ziyue Miao,Xiaodan Hong,Olli Ikkala,Zhong‐Peng Lv,Bo Peng
标识
DOI:10.1002/advs.202518531
摘要
While zwitterionic hydrogels and aq. polymers have already been used in, e.g., bio-related, environmental, and ionic transport-related applications, it is foreseen that their characteristic ability of zwitterions to bind functional particles combined with sol-gel transitions can allow emerging potential for responsive soft composites. Here, it is first shown that polyzwitterionic poly[2-(methacryloyloxy)ethyl]dimethyl-(3-sulfopropyl)ammonium hydroxide (PDMAPS), allows organohydrogelation upon adding dimethyl sulfoxide to its aqueous solution, inducing phase-separations to form physical cross-links. Density functional theory (DFT) analysis reveals solvent-polymer interactions that drive the organohydragelation. The organohydrogels exhibit ultrahigh stretchability (>2800%), quick self-adhesion, remoldability, and tunable viscoelasticity. By modulating solvent composition and integrating functional fillers, distinct sol- and gel-like states are achieved on-demand. In the sol-like state, titanium carbide nanosheets (MXenes)-incorporated PDMAPS soft composite enable mechano-tunable electromagnetic interference shielding via nanosheet reorientation under strain. In the gel-like regime, incorporation of magneticneodymium iron boron magnet (NdFeB) microparticles yields mechano-magneto-electric transducers for strain detection, dynamic haptic functionality, as demonstrated by Morse code encoding, and high durability in repeated compressive cycles. This work introduces a versatile organohydrogel platform with tunable viscoelastic properties, suitable for on-demand functionalized soft composites, suggesting new design principles for transducing, sensing, and soft robotics.
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