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Authors
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Guo, L.-Z.; Wu, C.-H.; Merlitz, H.; Chen, J.-J.; Yang, Z.-Z.; Forest, M. G.; Wu, C.-X.; Cao, X.-Z.
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Title
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Design of high-performance viscoelastic polymer nanocomposites using stiff nanorings
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Date
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24.06.2025
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Number
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0
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Abstract
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The pursuit of polymer nanocomposites (PNCs) that simultaneously exhibit high strength and toughness has long been hindered by the intrinsic trade-offs between these properties. Here, we introduce a groundbreaking strategy by integrating stiff nanorings (SNRs) into polymer melts, enabling unprecedented mechanical performance without relying on traditional cross-linking or filler reinforcement. Through advanced statistical rheological simulations, we reveal that threading polymer chains through SNRs transforms the melt into a gel-like hyperviscous fluid, despite the absence of permanent or transient cross-links. Under applied strain, the dynamic sliding of polymer chains along the constrained SNRs concentrates stress on the nanorings, effectively delaying chain relaxation and minimizing chain breakage. This innovative mechanism not only enhances both strength and toughness but also imparts exceptional viscoelastic properties, surpassing those of conventional polymer melts. Our findings establish SNRs as dynamic stress-dissipative units, offering a versatile and scalable platform for designing next-generation PNCs. This work opens new avenues for applications in extreme mechanical environments, from advanced manufacturing to biomedical engineering, and represents a paradigm shift in PNC science.
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Publisher
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American Chemical Society
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Wikidata
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Citation
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Macromolecules 58 (2025) 6149-6157
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DOI
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https://doi.org/10.1021/acs.macromol.5c01029
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