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[1] K. A. Stewart,et al. Dynamic Ablative Networks: Shapeable Heat-Shielding Materials. , 2023, ACS applied materials & interfaces.
[2] Chadron M. Friesen,et al. Shaken Not Stirred: Perfluoropyridine-Polyalkylether Prepolymers , 2022, Macromolecules.
[3] M. Urban,et al. Combined Reprocessability and Self-Healing in Fluorinated Acrylic-Based Covalent Adaptable Networks (CANs) , 2022, ACS Applied Polymer Materials.
[4] K. A. Stewart,et al. Controlling Dynamics of Associative Networks through Primary Chain Length , 2022, Macromolecules.
[5] B. Sumerlin,et al. Janus Cross-links in Supramolecular Networks. , 2022, Journal of the American Chemical Society.
[6] Xinyue Zhang,et al. Fully Bio-Based High-Performance Thermosets with Closed-Loop Recyclability , 2022, ACS Sustainable Chemistry & Engineering.
[7] L. Avérous,et al. Biobased vitrimers: towards sustainable and adaptable performing polymer materials , 2022, Progress in Polymer Science.
[8] Jiang Li,et al. Effects of inorganic nanofibers and high char yield fillers on char layer structure and ablation resistance of ethylene propylene diene monomer composites , 2021, Composites Part A: Applied Science and Manufacturing.
[9] R. Sijbesma,et al. Reversible crosslinking and fast stress relaxation in dynamic polymer networks via transalkylation using 1,4-diazabicyclo[2.2.2] octane , 2021, Polymer Chemistry.
[10] Loren C. Brown,et al. Toward Taming the Chemical Reversibility of Perfluoropyridine through Molecular Design with Applications to Pre- and Postmodifiable Polymer Architectures , 2021 .
[11] F. D. Du Prez,et al. Covalent Adaptable Networks Using β-Amino Esters as Thermally Reversible Building Blocks. , 2021, Journal of the American Chemical Society.
[12] Jonathan M. Millican,et al. Plastic Pollution: A Material Problem? , 2021, Macromolecules.
[13] Maarten M. J. Smulders,et al. The effect of polarity on the molecular exchange dynamics in imine-based covalent adaptable networks , 2021, Polymer Chemistry.
[14] L. Ceseracciu,et al. Biobased, Biodegradable, Self-Healing Boronic Ester Vitrimers from Epoxidized Soybean Oil Acrylate , 2020, ACS Applied Polymer Materials.
[15] Ren Liu,et al. Synthesis of Vanillin-Based Polyimine Vitrimers with Excellent Reprocessability, Fast Chemical Degradability, and Adhesion , 2020 .
[16] K. A. Stewart,et al. Pyridine-functionalized linear and network step-growth fluoropolymers , 2020 .
[17] B. Harvey,et al. Synthesis and Characterization of High-Performance, Bio-Based Epoxy–Amine Networks Derived from Resveratrol , 2020 .
[18] William R. Dichtel,et al. Reprocessable Cross-Linked Polymer Networks: Are Associative Exchange Mechanisms Desirable? , 2020, ACS central science.
[19] Yinghua Jin,et al. Robust, high-barrier, and fully recyclable cellulose-based plastic replacement enabled by a dynamic imine polymer , 2020 .
[20] Xinli Jing,et al. Recyclable, Self-healable, and Highly Malleable Poly(urethane-urea)s with improved Thermal and Mechanical Performances. , 2020, ACS applied materials & interfaces.
[21] Yangju Lin,et al. Renewable castor oil and DL-limonene derived fully bio-based vinylogous urethane vitrimers , 2020 .
[22] Q. Fang,et al. Sustainable alternative to bisphenol A epoxy resin: high-performance recyclable epoxy vitrimers derived from protocatechuic acid , 2020 .
[23] B. Sumerlin,et al. Polystyrene-Based Vitrimers: Inexpensive and Recyclable Thermosets , 2020 .
[24] R. Lambeth,et al. Exploiting the Site Selectivity of Perfluoropyridine for Facile Access to Densified Polyarylene Networks for Carbon-Rich Materials. , 2020, ACS macro letters.
[25] K. A. Stewart,et al. Perfluoropyridine as a Scaffold for Semifluorinated Thiol‐ene Networks with Readily Tunable Thermal Properties , 2020, Macromolecular Chemistry and Physics.
[26] Hao‐Bin Zhang,et al. Fully Biobased Vitrimers from Glycyrrhizic Acid and Soybean Oil for Self-Healing, Shape Memory, Weldable, and Recyclable Materials , 2020 .
[27] William R. Dichtel,et al. Incorporating Functionalized Cellulose to Increase the Toughness of Covalent Adaptable Networks. , 2020, ACS applied materials & interfaces.
[28] C. M. Bates,et al. Dynamic Bottlebrush Polymer Networks: Self-Healing in Super-Soft Materials. , 2020, Journal of the American Chemical Society.
[29] Q. Fang,et al. Gel–Sol Transition of Vanillin-Based Polyimine Vitrimers: Imparting Vitrimers with Extra Welding and Self-Healing Abilities , 2020 .
[30] U. Ojha,et al. Catalyst-Free Partially Bio-Based Polyester Vitrimers , 2020 .
[31] Xinxin Yang,et al. A fully bio-based epoxy vitrimer: Self-healing, triple-shape memory and reprocessing triggered by dynamic covalent bond exchange , 2020 .
[32] Y. Qiu,et al. Vanillin-Based Epoxy Vitrimer with High Performance and Closed-Loop Recyclability , 2020 .
[33] Thomas H. Epps,et al. Block Copolymer Vitrimers. , 2019, Journal of the American Chemical Society.
[34] L. Leibler,et al. Dynamic covalent chemistry in polymer networks: a mechanistic perspective , 2019, Polymer Chemistry.
[35] B. Sumerlin,et al. Adaptable Crosslinks in Polymeric Materials: Resolving the Intersection of Thermoplastics and Thermosets. , 2019, Journal of the American Chemical Society.
[36] Y. Ni,et al. Vitrimer-Cellulose Paper Composites: A New Class of Strong, Smart, Green and Sustainable Materials. , 2019, ACS applied materials & interfaces.
[37] Yinghua Jin,et al. Rapid Fabrication of Malleable Fiber Reinforced Composites with Vitrimer Powder , 2019, ACS Applied Polymer Materials.
[38] L. Avérous,et al. A fully bio-based polyimine vitrimer derived from fructose , 2019, Green Chemistry.
[39] Shusen You,et al. Facile in situ preparation of high-performance epoxy vitrimer from renewable resources and its application in nondestructive recyclable carbon fiber composite , 2019, Green Chemistry.
[40] B. Sumerlin,et al. Catalyst-Free Vitrimers from Vinyl Polymers , 2019, Macromolecules.
[41] Weilin Xu,et al. Vanillin-Based Polyschiff Vitrimers: Reprocessability and Chemical Recyclability , 2018, ACS Sustainable Chemistry & Engineering.
[42] J. Kalow,et al. Vitrimeric Silicone Elastomers Enabled by Dynamic Meldrum's Acid-Derived Cross-Links. , 2018, ACS macro letters.
[43] Tuan Liu,et al. Eugenol-Derived Biobased Epoxy: Shape Memory, Repairing, and Recyclability , 2017 .
[44] Yinghua Jin,et al. Tuning the physical properties of malleable and recyclable polyimine thermosets: the effect of solvent and monomer concentration , 2017 .
[45] A. Chauhan,et al. Modular and rapid access to amphiphilic homopolymers via successive chemoselective post-polymerization modification , 2017 .
[46] S. Rowan,et al. Effect of Sterics and Degree of Cross-Linking on the Mechanical Properties of Dynamic Poly(alkylurea–urethane) Networks , 2017 .
[47] J. Kenny,et al. Science and technology of polymeric ablative materials for thermal protection systems and propulsion devices: A review , 2016 .
[48] B. Sumerlin,et al. Multifunctional Homopolymers: Postpolymerization Modification via Sequential Nucleophilic Aromatic Substitution , 2016 .
[49] B. Sumerlin,et al. Efficient and Chemoselective Synthesis of ω,ω-Heterodifunctional Polymers. , 2015, ACS macro letters.
[50] Ludwik Leibler,et al. Chemically crosslinked yet reprocessable epoxidized natural rubber via thermo-activated disulfide rearrangements , 2015 .
[51] Wei Zhang,et al. Heat‐ or Water‐Driven Malleability in a Highly Recyclable Covalent Network Polymer , 2014, Advanced materials.
[52] S. Mohanty,et al. Recent developments in elastomeric heat shielding materials for solid rocket motor casing application for future perspective , 2018 .
[53] Z. Guan,et al. Olefin metathesis for effective polymer healing via dynamic exchange of strong carbon-carbon double bonds. , 2012, Journal of the American Chemical Society.
[54] J. Kenny,et al. Ablative properties of carbon black and MWNT/phenolic composites: A comparative study , 2012 .