An Ultrastrong and Highly Stretchable Polyurethane Elastomer Enabled by a Zipper‐Like Ring‐Sliding Effect

Shi, Chenyu; Zhang, Qi; Yu, Chengyuan; Rao, S. Nagaraja; Yang, Shun; Tian, He; Qu, Da‐Hui

doi:10.1002/adma.202000345

Cited by 136 publications

(104 citation statements)

References 60 publications

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“…The strengthening and toughening of the PU-BPY 0.5 -Zn elastomers were further characterized by cyclic tensile tests with increasing strains but no delay time (Figure 4a). [37,50,51] The hysteresis areas for each loading-unloading cycle of the elastomers are plotted as a function of the strain in Figure 4b. The hysteresis areas for the elastomers are small when the strain is lower than 400%, meaning that the elastomers mainly undergo elastic deformation with the rupture of an extremely small amount of hydrogen and coordination bonds.…”

Section: Herein the Fabrication Of Healable Recyclable And Mechanimentioning

confidence: 99%

“…[3,34,35] In contrast, elastomers conferred with good damage tolerance can effectively prohibit the propagation of physical damage such as cuts and cracks to retain most of their mechanical properties. [31,36,37] Therefore, elastomers integrated with damage tolerance and healability are more effective than those solely integrated with healability in extending service life and enhancing reliability. The damage tolerance of elastomers or other kinds of polymer materials requires efficiently dissipating energy concentrated in the damaged regions.…”

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Healable, Recyclable, and Mechanically Tough Polyurethane Elastomers with Exceptional Damage Tolerance

et al. 2020

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There is a huge requirement of elastomers for use in tires, seals, and shock absorbers every year worldwide. In view of a sustainable society, the next generation of elastomers is expected to combine outstanding healing, recycling, and damage‐tolerant capacities with high strength, elasticity, and toughness. However, it remains challenging to fabricate such elastomers because the mechanisms for the properties mentioned above are mutually exclusive. Herein, the fabrication of healable, recyclable, and mechanically tough polyurethane (PU) elastomers with outstanding damage tolerance by coordination of multiblock polymers of poly(dimethylsiloxane) (PDMS)/polycaprolactone (PCL) containing hydrogen and coordination bonding motifs with Zn2+ ions is reported. The organization of bipyridine groups coordinated with Zn2+ ions, carbamate groups cross‐linked with hydrogen bonds, and crystallized PCL segments generates phase‐separated dynamic hierarchical domains. Serving as rigid nanofillers capable of deformation and disintegration under an external force, the dynamic hierarchical domains can strengthen the elastomers and significantly enhance their toughness and fracture energy. As a result, the elastomers exhibit a tensile strength of ≈52.4 MPa, a toughness of ≈363.8 MJ m−3, and an exceptional fracture energy of ≈192.9 kJ m−2. Furthermore, the elastomers can be conveniently healed and recycled to regain their original mechanical properties and integrity under heating.

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Section: Herein the Fabrication Of Healable Recyclable And Mechanimentioning

confidence: 99%

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Healable, Recyclable, and Mechanically Tough Polyurethane Elastomers with Exceptional Damage Tolerance

et al. 2020

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“…have been developed by the self-assembly of building blocks. Diverse noncovalent interactions include hydrogen-bonding, 12,13 π-π stacking, 14,15 van der Waals interactions, 16,17 electrostatic interactions, 18 hydrophobic effects, 19,20 host-guest interactions 21,22 and dynamic covalent bonds. [23][24][25] Precisely tuned precursor molecules organize into desired ensembles with distinct physicochemical properties via the "bottom-up" approaches.…”

Section: Introductionmentioning

confidence: 99%

Supramolecular adhesive materials from small‐molecule self‐assembly

et al. 2020

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Developing high-performance adhesive materials not only aims at industrial and social requirements but also bears the fundamental importance of understanding the chemical factors of biological adhesion to develop biomimetic adhesive materials. Owing to the wide development of supramolecular chemistry, numerous supramolecular tools are exploited and proved to be reliable in the replacement of traditional covalent materials by reversible noncovalent or dynamic covalent materials. Taking advantage of these readyto-use supramolecular toolboxes, supramolecular adhesive materials are rising and promising toward "smart" adhesives, that is, enabling responsiveness, reversibility, and recyclability. Compared with polymeric adhesive materials, low-molecular-weight adhesives feature chemically precise structure, easier engineering by molecular design, and hence higher reproducibility. However, it remains highly challenging to make high-performance adhesive materials by low-molecular-weight feedstocks. This review will focus on the recent advancement in the construction of supramolecular adhesive materials by smallmolecule self-assembly. The design guidelines and consideration on the molecular scale will be discussed and summarized on how to enhance the strength of adhesives. Meanwhile, owing to the dynamic nature of supramolecular self-assembly, several "smart" functions of such materials will be presented, such as stimuli-responsiveness and adaptiveness. Finally, current challenges and future perspectives of this emerging field will be proposed.

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“…Unfortunately, their rupture stress just reached the kPa scale meaning that they cannot be classified as tough materials. Thermoplastic polyurethane (TPU) [ 51 , 52 , 53 ] as a thermoprocessable elastomer has recently attracted attention in the preparation of tough materials, due to its chemical structure, which can be finely tuned to generate the desired transparency and mechanical properties. TPU usually has a multiphase microstructure, in which the hard domains act as reinforcing filler, and they are connected by thermally reversible crosslinks and embedded in the soft matrix.…”

Section: Introductionmentioning

confidence: 99%

Self-Healing Thermoplastic Polyurethane Linked via Host-Guest Interactions

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High toughness with self-healing ability has become the ultimate goal in materials research. Herein, thermoplastic polyurethane (TPU) was linked via host-guest (HG) interactions to increase its mechanical properties and self-healing ability. TPU linked via HG interactions was prepared by the step-growth bulk polymerization of hexamethylene diisocyanate (HDI), tetraethylene glycol (TEG), and HG interactions between permethylated amino βCD (PMeAmβCD) and adamantane amine (AdAm). TPU linked with 10 mol% of HG interactions (HG(10)) showed the highest rupture stress and fracture energy (GF) of 11 MPa and 25 MJ·m−3, which are almost 40-fold and 1500-fold, respectively, higher than those of non-functionalized TEG-based TPU (PU). Additionally, damaged HG(10) shows 87% recovery after heated for 7 min at 80 °C, and completely cut HG(10) shows 80% recovery after 60 min of reattachment at same temperature. The HG interactions in TPU are an important factor in stress dispersion, increasing both its mechanical and self-healing properties. The TPU linked via HG interactions has great promise for use in industrial materials in the near future.

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An Ultrastrong and Highly Stretchable Polyurethane Elastomer Enabled by a Zipper‐Like Ring‐Sliding Effect

Cited by 136 publications

References 60 publications

Healable, Recyclable, and Mechanically Tough Polyurethane Elastomers with Exceptional Damage Tolerance

Healable, Recyclable, and Mechanically Tough Polyurethane Elastomers with Exceptional Damage Tolerance

Supramolecular adhesive materials from small‐molecule self‐assembly

Self-Healing Thermoplastic Polyurethane Linked via Host-Guest Interactions

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