Reversibly Interlocking of Immiscible Covalent Adaptive Networks in Solid State: A Paradigm for Enhancing Interfacial Interaction of Multicomponent Polymer Systems

You, Yang; Wang, Zheng Yue; Rong, Min Zhi; Zhang, Ming Qiu

doi:10.1021/acs.macromol.3c01632

“…These methods are usually accompanied by the rupture of rubber chains, environmental pollution, and complex processes. Recently, studies into dynamic networks have suggested that reversible networks enabling interface fusion among cross-linked polymers could be a promising strategy for enhancing interactions. − However, applying these dynamic network strategies to WR recycling is also challenging because irreversible vulcanization networks still dominate the rubber industry, making it difficult to replace vulcanization networks with dynamic networks . Therefore, it is necessary to develop alternative strategies to improve interactions among WR for recycling.…”

Section: Introductionmentioning

confidence: 99%

Aliphatic C–H Insertion Strategies Enhancing Interactions among Waste Rubbers for Recycling

Guo,

Qiao,

Hu

et al. 2024

ACS Appl. Polym. Mater.

0

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The recycling of waste rubber (WR) is beneficial to the sustainable development of rubber industries. However, interactions among WR are weak, limiting the recycling of WR. In this work, our group designed bis-diazo compounds to promote interactions among WR for recycling through aliphatic C−H insertion strategies. Specifically, upon hot pressing, bis-diazo compounds produce biscarbenes which react with C−H on the surface of WR by C−H insertions, and then we obtain recycled WR materials. As a result, stress−strain curves show that the strength of recycled WR increases steadily with the increase of bis-diazo compound loading, which has reached the level of butadiene styrene rubbers. Moreover, the introduced disulfide bonds endow recycled WR with reprocessability. Stress−relaxation experiments at different temperatures show that recycled WR with disulfide bonds have unique vitrimer viscoelastic properties. The feasibility of bis-diazo compounds to enhance interactions among WR through C−H insertions opens opportunities to recycle and reinvent industrial WR.

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Dynamic Covalent Bonds Enabled Carbon Fiber Reinforced Polymers Recyclability and Material Circularity

Fan,

Zheng,

Yeo

et al. 2024

Angewandte Chemie

2

0

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Due to their remarkable features of lightweight, high strength, stiffness, high‐temperature resistance, and corrosion resistance, carbon fiber reinforced polymers (CFRPs) are extensively used in sports equipment, vehicles, aircraft, windmill blades, and other sectors. The urging need to develop a resource‐saving and environmentally responsible society requires the recycling of CFRPs. Traditional CFRPs, on the other hand, are difficult to recycle due to the permanent covalent crosslinking of polymer matrices. The combination of covalent adaptable networks (CANs) with carbon fibers (CFs) marks a new development path for closed‐loop recyclable CFRPs and polymer resins. This review summarizes the most recent developments of closed‐loop recyclable CFRPs from the unique paradigm of dynamic crosslinking polymers, CANs. These sophisticated materials with diverse functions, oriented towards CFs recycling and resin sustainability, are further categorized into several active domains of dynamic covalent bonds, including ester bonds, imine bonds, disulfide bonds, boronic ester bonds, and acetal linkages, etc. Finally, the possible strategies for the future design of recyclable CFPRs by combining dynamic covalent chemistry innovation with materials interface science are proposed.

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Dynamic Covalent Bonds Enabled Carbon Fiber Reinforced Polymers Recyclability and Material Circularity

Fan,

Zheng,

Yeo

et al. 2024

Angew Chem Int Ed

0

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Due to their remarkable features of lightweight, high strength, stiffness, high‐temperature resistance, and corrosion resistance, carbon fiber reinforced polymers (CFRPs) are extensively used in sports equipment, vehicles, aircraft, windmill blades, and other sectors. The urging need to develop a resource‐saving and environmentally responsible society requires the recycling of CFRPs. Traditional CFRPs, on the other hand, are difficult to recycle due to the permanent covalent crosslinking of polymer matrices. The combination of covalent adaptable networks (CANs) with carbon fibers (CFs) marks a new development path for closed‐loop recyclable CFRPs and polymer resins. This review summarizes the most recent developments of closed‐loop recyclable CFRPs from the unique paradigm of dynamic crosslinking polymers, CANs. These sophisticated materials with diverse functions, oriented towards CFs recycling and resin sustainability, are further categorized into several active domains of dynamic covalent bonds, including ester bonds, imine bonds, disulfide bonds, boronic ester bonds, and acetal linkages, etc. Finally, the possible strategies for the future design of recyclable CFPRs by combining dynamic covalent chemistry innovation with materials interface science are proposed.

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Reversibly Interlocking of Immiscible Covalent Adaptive Networks in Solid State: A Paradigm for Enhancing Interfacial Interaction of Multicomponent Polymer Systems

Cited by 6 publications

References 42 publications

Aliphatic C–H Insertion Strategies Enhancing Interactions among Waste Rubbers for Recycling

Aliphatic C–H Insertion Strategies Enhancing Interactions among Waste Rubbers for Recycling

Dynamic Covalent Bonds Enabled Carbon Fiber Reinforced Polymers Recyclability and Material Circularity

Dynamic Covalent Bonds Enabled Carbon Fiber Reinforced Polymers Recyclability and Material Circularity

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