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| Language: | English |
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2026
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| Online Access: | https://doi.org/10.5281/zenodo.18498554 |
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| author | Landry, Marie-Soleil Seshat |
| author_facet | Landry, Marie-Soleil Seshat |
| contents | <p>[PRE-EXPERIMENTAL DRAFT — EXPERIMENTAL DATA PENDING]</p> <p>Epoxy thermosets are foundational materials in structural and functional composites but remain constrained by fossil feedstocks, permanent crosslinking, and limited end-of-life options. Here, we present a [PROPOSED] complete experimental study of Hempoxy vitrimers, a family of predominantly hemp-derived epoxy bionanocomposites integrating epoxidized hempseed oil (EHO), hemp lignin, hemp cellulose derivatives, and hemp-derived carbon nanomaterials. Fifteen distinct Hempoxy variants [TO BE] synthesized and evaluated, spanning foundational bio-epoxies, advanced vitrimer nanocomposites, and function-specific prototypes. Dynamic covalent networks based on ω -hydroxy ester transesterification, imine exchange, and disulfide metathesis enabled thermal reprocessing, chemical recycling, and self-healing while retaining thermoset integrity. Hemp-derived carbon reinforcements—including biochar, carbon nanofibers (CNF), carbon nanosheets (CNS), and graphene quantum dots (GQD)—provided tunable mechanical, electrical, and thermal functionality. Across the platform, glass transition temperatures (T g ) of 45–110 → C, topology freezing temperatures (T v ) of 65–180 → C, tensile strengths of 20–110 MPa, electrical conductivities up to 30 S m ↑1 , and retention of → 85% mechanical performance after four reprocessing cycles [TARGET VALUES — EXPERIMENTAL VALIDATION REQUIRED]. Closed-loop chemical recycling via aminolysis enabled recovery of both matrix oligomers and carbon fillers. These results establish Hempoxy vitrimers as a scalable, circular, and multifunctional epoxy materials platform derived primarily from Cannabis sativa biomass.</p> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_5281_zenodo_18498554 |
| institution | Zenodo |
| language | eng |
| publishDate | 2026 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | Hempoxy Vitrimer Bionanocomposites: A Hemp-Derived, Reprocessable Epoxy Platform with Hierarchical Carbon Reinforcement Landry, Marie-Soleil Seshat Hemp composites; vitrimer epoxy; green chemistry; carbon nanosheets; circular thermosets; bio-based polymers; dynamic covalent networks <p>[PRE-EXPERIMENTAL DRAFT — EXPERIMENTAL DATA PENDING]</p> <p>Epoxy thermosets are foundational materials in structural and functional composites but remain constrained by fossil feedstocks, permanent crosslinking, and limited end-of-life options. Here, we present a [PROPOSED] complete experimental study of Hempoxy vitrimers, a family of predominantly hemp-derived epoxy bionanocomposites integrating epoxidized hempseed oil (EHO), hemp lignin, hemp cellulose derivatives, and hemp-derived carbon nanomaterials. Fifteen distinct Hempoxy variants [TO BE] synthesized and evaluated, spanning foundational bio-epoxies, advanced vitrimer nanocomposites, and function-specific prototypes. Dynamic covalent networks based on ω -hydroxy ester transesterification, imine exchange, and disulfide metathesis enabled thermal reprocessing, chemical recycling, and self-healing while retaining thermoset integrity. Hemp-derived carbon reinforcements—including biochar, carbon nanofibers (CNF), carbon nanosheets (CNS), and graphene quantum dots (GQD)—provided tunable mechanical, electrical, and thermal functionality. Across the platform, glass transition temperatures (T g ) of 45–110 → C, topology freezing temperatures (T v ) of 65–180 → C, tensile strengths of 20–110 MPa, electrical conductivities up to 30 S m ↑1 , and retention of → 85% mechanical performance after four reprocessing cycles [TARGET VALUES — EXPERIMENTAL VALIDATION REQUIRED]. Closed-loop chemical recycling via aminolysis enabled recovery of both matrix oligomers and carbon fillers. These results establish Hempoxy vitrimers as a scalable, circular, and multifunctional epoxy materials platform derived primarily from Cannabis sativa biomass.</p> |
| title | Hempoxy Vitrimer Bionanocomposites: A Hemp-Derived, Reprocessable Epoxy Platform with Hierarchical Carbon Reinforcement |
| topic | Hemp composites; vitrimer epoxy; green chemistry; carbon nanosheets; circular thermosets; bio-based polymers; dynamic covalent networks |
| url | https://doi.org/10.5281/zenodo.18498554 |