Yuhang Ye scite author profile

To date, ionic conducting hydrogel attracts tremendous attention as an alternative to the conventional rigid metallic conductors in fabricating flexible devices, owing to their intrinsic characteristics. However, simultaneous realization of high stiffness, toughness, ionic conductivity, and freezing tolerance through a simple approach is still a challenge. Here, a novel highly stretchable (up to 660%), strong (up to 2.1 MPa), tough (5.25 MJ m−3), and transparent (up to 90%) ionic conductive (3.2 S m−1) organohydrogel is facilely fabricated, through sol–gel transition of polyvinyl alcohol and cellulose nanofibrils (CNFs) in dimethyl sulfoxide‐water solvent system. The ionic conductive organohydrogel presents superior freezing tolerance, remaining flexible and conductive (1.1 S m−1) even at −70 °C, as compared to the other reported anti‐freezing ionic conductive (organo)hydrogel. Notably, this material design demonstrates synergistic effect of CNFs in boosting both mechanical properties and ionic conductivity, tackling a long‐standing dilemma among strength, toughness, and ionic conductivity for the ionic conducting hydrogel. In addition, the organohydrogel displays high sensitivity toward both tensile and compressive deformation and based on which multi‐functional sensors are assembled to detect human body movement with high sensitivity, stability, and durability. This novel organohydrogel is envisioned to function as a versatile platform for multi‐functional sensors in the future.

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Flexible nanocellulose enhanced Li+ conducting membrane for solid polymer electrolyte

Qin

Zhang

et al. 2020

Energy Storage Materials

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Hydrogen-bonding-induced assembly of aligned cellulose nanofibers into ultrastrong and tough bulk materials

et al. 2019

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Highly stretchable, durable, and transient conductive hydrogel for multi-functional sensor and signal transmission applications

Jiang

2022

Nano Energy

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Yuhang Ye

Cellulose Nanofibrils Enhanced, Strong, Stretchable, Freezing‐Tolerant Ionic Conductive Organohydrogel for Multi‐Functional Sensors

Flexible nanocellulose enhanced Li+ conducting membrane for solid polymer electrolyte

Hydrogen-bonding-induced assembly of aligned cellulose nanofibers into ultrastrong and tough bulk materials

Highly stretchable, durable, and transient conductive hydrogel for multi-functional sensor and signal transmission applications

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