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Supramolecular Semi-convertible Hydrogel Enabled Self-Healing Responsive Lubrication Under Dynamic Shearing

Xuewei Zhang, Kaiyao Shi, Xuhao Yang, Jian Wang, Huan Liu, Wenlong Song, Shutao Wang

2023CCS Chemistry19 citationsDOIOpen Access PDF

Abstract

Open AccessCCS ChemistryRESEARCH ARTICLES4 Jan 2023Supramolecular Semi-Convertible Hydrogel Enabled Self-Healing Responsive Lubrication under Dynamic Shearing Xuewei Zhang, Kaiyao Shi, Xuhao Yang, Jian Wang, Huan Liu, Wenlong Song and Shutao Wang Xuewei Zhang , Kaiyao Shi , Xuhao Yang , Jian Wang , Huan Liu , Wenlong Song and Shutao Wang https://doi.org/10.31635/ccschem.023.202202670 SectionsSupplemental MaterialAboutPDF ToolsAdd to favoritesDownload CitationsTrack Citations ShareFacebookTwitterLinked InEmail The cartilage-inspired hydrogel has attracted great interests due to its tunable mechanic and low friction, however, it is incapable of self-healing under a complex dynamic shearing environment. In this work, a self-healing semi-convertible hydrogel is developed, which can recover the unique active lubricating function under shearing. Based on the cooperating strategy of noncovalent and covalent bonding, the prepared semi-convertible hydrogel composes of three interpenetrated networks including i) shear-responsive N-fluorenylmethoxycarbonyl-L-tryptophan supramolecular network, ii) self-healing polyhydroxyethyl acrylamide network and iii) rigid polyvinyl alcohol covalent network. The shear-responsive lubricating function and mechanical property can be self-healed under shearing environment through the noncovalent hydrogen bonding assembly of polyhydroxyethyl acrylamide associated by the π-π assembly of N-fluorenylmethoxycarbonyl-L-tryptophan. The as-developed semi-convertible hydrogel provides a self-healing model comparing with traditional self-healing lubricating materials through encapsulating lubricant microcapsules or infusing lubricants onto surfaces. We demonstrated a proof-of-concept on the self-healing lubrication of simplified artificial worn cartilage model under dynamic shearing condition. This study will offer a potential strategy on designing the self-healing soft devices under dynamic stimuli far beyond the lubricating materials. Download figure Download PowerPoint Previous articleNext article FiguresReferencesRelatedDetails Issue AssignmentVolume 0Issue jaPage: 1-31Supporting Information Copyright & Permissions© 2023 Chinese Chemical Society Downloaded 0 times PDF downloadLoading ...

Topics & Concepts

Shearing (physics)Self-healingSupramolecular chemistryLubricationNanotechnologyPolymer scienceMaterials scienceComputer scienceComposite materialChemistryMedicineOrganic chemistryMoleculePathologyAlternative medicinePolymer composites and self-healingSynthesis and properties of polymersLubricants and Their Additives