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Revisiting the Interface Dynamics of MXene/Rubber Elastomers: Multiscale Mechanistic Insights into Collaborative Bonding for Robust Self-Healing Sensors

Lixian Song, Dong Liu, Huan Zhang, Yang Wang, Bo Zhao, Wenbin Kang, Yutian Zhu, Yanying Wei, Yingze Song

2025Nano Letters12 citationsDOI

Abstract

Sophisticated flexible strain sensors based on MXene/rubber with self-healing capabilities are poised to transform future deformable electronics by restoring impaired performance after repeated deformation. Despite their potential, integrating excellent self-healing properties with superior mechanical strength in a single system remains a significant challenge due to simplistic interface architectures with weak bonds and limited understanding of MXene/rubber interface dynamics. To address this, a novel metal coordination bonding scheme has been developed, synergizing with dynamic hydrogen bonding to enhance interface bonding strength, enabling both outstanding mechanical and self-healing properties. Using in situ synchrotron radiation techniques, a multiscale investigation of MXene/rubber interface dynamics provides valuable insights, linking bonding strength to mechanical performance. These findings not only deepen our understanding of interface evolution in deformable electrodes but also offer a promising path for designing advanced self-healable strain sensors with superior mechanical properties.

Topics & Concepts

ElastomerSelf-healingMaterials scienceMolecular dynamicsNatural rubberNanotechnologyInterface (matter)Dynamics (music)Composite materialChemistryComputational chemistryPhysicsAlternative medicineAcousticsPathologyCapillary actionMedicineCapillary numberAdvanced Sensor and Energy Harvesting MaterialsMXene and MAX Phase MaterialsDielectric materials and actuators
Revisiting the Interface Dynamics of MXene/Rubber Elastomers: Multiscale Mechanistic Insights into Collaborative Bonding for Robust Self-Healing Sensors | Litcius