Hydrogen Bonding Competition Mediated Phase Separation with Abnormal Moisture‐Induced Stiffness Boosting

Moisture usually deteriorates polymers’ mechanical performance owing to its plasticizing effect, causing side effects in their practical load‐bearing applications. Herein, a simple binary ionogel consisting of an amphiphilic polymer network and a hydrophobic ionic liquid (IL) is developed with remar...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2024-09, Vol.20 (36), p.e2401164-n/a
Main Authors: Xu, Jian, Wu, Baohu, Hou, Lei, Wu, Peiyi
Format: Article
Language:English
Subjects:
Chemical bonds
hydrogen bond
Hydrogen bonding
Ionic liquids
ionogel
Mechanical properties
Moisture
Phase separation
Polymers
Side effects
Smart structures
Stiffening
stiffness‐switch
water‐responsive
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Summary:Moisture usually deteriorates polymers’ mechanical performance owing to its plasticizing effect, causing side effects in their practical load‐bearing applications. Herein, a simple binary ionogel consisting of an amphiphilic polymer network and a hydrophobic ionic liquid (IL) is developed with remarkable stiffening effect after moisture absorption, demonstrating a complete contrast to water‐induced softening effect of most polymer materials. Such a moisture‐induced stiffening behavior is induced by phase separation after hydration of this binary ionogel. Specifically, it is revealed that hydrogen (H)‐bonding structures play a dominant role in the humidity‐responsive behavior of the ionogel, where water will preferentially interact with polymer chains through H‐bonding and break the polymer‐IL H‐bonds, thus leading to phase separation structures with modulus boosting. This work may provide a facile and effective molecular engineering route to construct mechanically adaptive polymers with water‐induced dramatic stiffening for diverse applications. The binary ionogel composed of an amphiphilic polymer network and a hydrophobic ionic liquid demonstrates an abnormal moisture‐induced stiffness boosting, which is in complete contrast to water‐induced softening of common polymer materials. Comprehensive understanding of this moisture‐induced stiffening of the ionogel is achieved from multiscale perspectives, including molecular interactions, microphase separations, and macro mechanical performances.
ISSN:1613-6810
1613-6829
1613-6829
DOI:10.1002/smll.202401164