Tough and Multi‐Recyclable Cross‐Linked Supramolecular Polyureas via Incorporating Noncovalent Bonds into Main‐Chains

Qin, Bo; Zhang, Shuai; Sun, Peng; Tang, Bohan; Yin, Zihe; Cao, Xiaoyan; Chen, Quan; Xu, Jiang‐Fei; Zhang, Xi

doi:10.1002/adma.202000096

Cited by 206 publications

(190 citation statements)

References 56 publications

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“…Xi Zhang and coworkers designed and fabricated both reversible noncovalent bonds and permanent covalent cross-links to improve mechanical stength of elastomer to 34.0 MPa (ref. 33 ). For most self-healing materials, their mechanical strength is still relatively low and not capable of meeting the requirement of structural materials.…”

Section: Introductionmentioning

confidence: 99%

Ultrarobust, tough and highly stretchable self-healing materials based on cartilage-inspired noncovalent assembly nanostructure

2021

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Self-healing materials integrated with excellent mechanical strength and simultaneously high healing efficiency would be of great use in many fields, however their fabrication has been proven extremely challenging. Here, inspired by biological cartilage, we present an ultrarobust self-healing material by incorporating high density noncovalent bonds at the interfaces between the dentritic tannic acid-modified tungsten disulfide nanosheets and polyurethane matrix to collectively produce a strong interfacial interaction. The resultant nanocomposite material with interwoven network shows excellent tensile strength (52.3 MPa), high toughness (282.7 MJ m‒3, which is 1.6 times higher than spider silk and 9.4 times higher than metallic aluminum), high stretchability (1020.8%) and excellent healing efficiency (80–100%), which overturns the previous understanding of traditional noncovalent bonding self-healing materials where high mechanical robustness and healing ability are mutually exclusive. Moreover, the interfacical supramolecular crosslinking structure enables the functional-healing ability of the resultant flexible smart actuation devices. This work opens an avenue toward the development of ultrarobust self-healing materials for various flexible functional devices.

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Section: Introductionmentioning

confidence: 99%

Ultrarobust, tough and highly stretchable self-healing materials based on cartilage-inspired noncovalent assembly nanostructure

2021

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“…The results agree with computational and interdiffusion studies on other glassy polymers ( 8 ). Similar investigations with chemically more complex polymers are exceedingly difficult, and healing of polymers containing dynamic bonds is therefore typically probed by macroscopic experiments, such as the qualitative observation of the disappearance of scratches ( 3 , 4 , 21 ), or by comparing the mechanical properties of damaged and healed samples ( 14 – 18 , 22 ). For example, the recovery of the elongation at break, tensile strength, and/or toughness is established by tensile tests ( 14 , 21 , 23 – 25 ) or fracture mechanics ( 26 – 28 ).…”

Section: Introductionmentioning

confidence: 99%

Dynamics and healing behavior of metallosupramolecular polymers

et al. 2021

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Self-healing or healable polymers can recuperate their function after physical damage. This process involves diffusion of macromolecules across severed interfaces until the structure of the interphase matches that of the pristine material. However, monitoring this nanoscale process and relating it to the mechanical recovery remain elusive. We report that studying diffusion across healed interfaces and a correlation of contact time, diffusion depth, and mechanical properties is possible when two metallosupramolecular polymers assembled with different lanthanoid salts are mended. The materials used display similar properties, while the metal ions can be tracked with high spatial resolution by energy-dispersive x-ray spectrum imaging. We find that healing actual defects requires an interphase thickness in excess of 100 nm, 10 times more than previously established for self-adhesion of smooth films of glassy polymers.

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“…Beneting from the dynamic nature, good directionality, versatility and high stability, multiple H-bonded motifs have been integrated into the polymeric scaffolds to fabricate H-bond cross-linked polymeric materials with tunable microstructures and high-performances. [75][76][77][78][79][80][81][82] To further apply Azo-UPy for the construction of photocontrollable macromolecular systems, a linear polymer Azo-UPy-P was then synthesized, with the side chains being modied with Azo-UPy (Fig. 3a).…”

Section: Application Of Azo-upy For Photocontrollable Macro-/ Moleculmentioning

confidence: 99%

Towards photoswitchable quadruple hydrogen bonds via a reversible “photolocking” strategy for photocontrolled self-assembly

et al. 2021

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Tough and Multi‐Recyclable Cross‐Linked Supramolecular Polyureas via Incorporating Noncovalent Bonds into Main‐Chains

Cited by 206 publications

References 56 publications

Ultrarobust, tough and highly stretchable self-healing materials based on cartilage-inspired noncovalent assembly nanostructure

Ultrarobust, tough and highly stretchable self-healing materials based on cartilage-inspired noncovalent assembly nanostructure

Dynamics and healing behavior of metallosupramolecular polymers

Towards photoswitchable quadruple hydrogen bonds via a reversible “photolocking” strategy for photocontrolled self-assembly

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