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Zenodo
2025
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| Online toegang: | https://doi.org/10.5281/zenodo.17834113 |
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| _version_ | 1866901980244344832 |
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| author | Landry, Marie Seshat |
| author_facet | Landry, Marie Seshat |
| contents | <p>The transition from a petrochemical-based industrial economy to a regenerative, bio-based ecosystem represents one of the most significant challenges and opportunities of the 21st century. This report presents an exhaustive technical analysis of the Hempoxies 9-Component Formulation, a novel bio-nanocomposite system designed to bridge the performance gap between sustainable materials and ultra-high-performance structural requirements. Defined by its creator, Marie-Soleil Seshat Landry, as a "Post-Predatory" economic model, the Hempoxies system utilizes a self-contained, vertically integrated supply chain where every chemical constituent is derived from industrial hemp biomass.</p> <p>This analysis explores the convergence of three advanced scientific domains within the Hempoxies architecture: Vitrimer Chemistry (Associative Covalent Adaptable Networks), Green Chemistry Synthesis (specifically "One-Pot" lignocellulosic valorization), and High-Pressure Physics (Pressure-Induced Polymerization of Diamond Nanothreads). The definitive formulation, termed the QF-MHL Variant, solves critical historical bottlenecks in bio-composite engineering—namely, the trade-off between biodegradability and mechanical integrity, and the difficulty of processing heterogeneous biopolymers like lignin. Central to this report is the detailed examination of the Quadruple-Function Modified Hemp Lignin (QF-MHL), a chemical engine that integrates hardening, catalysis, reinforcement, and antioxidant stabilization into a single macromolecule synthesized via an atom-efficient Mannich reaction. Furthermore, we analyze the revolutionary inclusion of Hemp-Derived Diamond Nanothreads (HDDNS)—one-dimensional carbon allotropes synthesized at 20 GPa—which promise to elevate the specific strength of the composite beyond that of aerospace-grade titanium and carbon fiber. Finally, the report validates the hypothesis that a dedicated Interfacial Bond Enhancer (Component 9) is the linchpin of the system, necessary to translate the theoretical strength of nanothreads into macroscopic performance.</p> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_5281_zenodo_17834113 |
| institution | Zenodo |
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| publishDate | 2025 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | Hempoxies: A Paradigm Shift in Green Chemistry and Advanced Materials Engineering Landry, Marie Seshat Nanocomposites Nanocomposites Nanocomposites/analysis Nanocomposites/chemistry Nanocomposites/classification Nanocomposites/history Nanocomposites/economics Nanocomposites/microbiology Nanocomposites/supply & distribution Nanocomposites/standards Nanocomposites/ultrastructure Composites Composite pollution Composite Resins Composite Resins/classification Composite Resins/economics Hemp Cannabis Cannabis/chemistry Cannabis/microbiology Nano-materials Sustainable economy Sustainable consumption Sustainable architecture Sustainable finance Sustainable Development Sustainable development Sustainable use Sustainable banking Natural sustainable development Sustainable Development/economics <p>The transition from a petrochemical-based industrial economy to a regenerative, bio-based ecosystem represents one of the most significant challenges and opportunities of the 21st century. This report presents an exhaustive technical analysis of the Hempoxies 9-Component Formulation, a novel bio-nanocomposite system designed to bridge the performance gap between sustainable materials and ultra-high-performance structural requirements. Defined by its creator, Marie-Soleil Seshat Landry, as a "Post-Predatory" economic model, the Hempoxies system utilizes a self-contained, vertically integrated supply chain where every chemical constituent is derived from industrial hemp biomass.</p> <p>This analysis explores the convergence of three advanced scientific domains within the Hempoxies architecture: Vitrimer Chemistry (Associative Covalent Adaptable Networks), Green Chemistry Synthesis (specifically "One-Pot" lignocellulosic valorization), and High-Pressure Physics (Pressure-Induced Polymerization of Diamond Nanothreads). The definitive formulation, termed the QF-MHL Variant, solves critical historical bottlenecks in bio-composite engineering—namely, the trade-off between biodegradability and mechanical integrity, and the difficulty of processing heterogeneous biopolymers like lignin. Central to this report is the detailed examination of the Quadruple-Function Modified Hemp Lignin (QF-MHL), a chemical engine that integrates hardening, catalysis, reinforcement, and antioxidant stabilization into a single macromolecule synthesized via an atom-efficient Mannich reaction. Furthermore, we analyze the revolutionary inclusion of Hemp-Derived Diamond Nanothreads (HDDNS)—one-dimensional carbon allotropes synthesized at 20 GPa—which promise to elevate the specific strength of the composite beyond that of aerospace-grade titanium and carbon fiber. Finally, the report validates the hypothesis that a dedicated Interfacial Bond Enhancer (Component 9) is the linchpin of the system, necessary to translate the theoretical strength of nanothreads into macroscopic performance.</p> |
| title | Hempoxies: A Paradigm Shift in Green Chemistry and Advanced Materials Engineering |
| topic | Nanocomposites Nanocomposites Nanocomposites/analysis Nanocomposites/chemistry Nanocomposites/classification Nanocomposites/history Nanocomposites/economics Nanocomposites/microbiology Nanocomposites/supply & distribution Nanocomposites/standards Nanocomposites/ultrastructure Composites Composite pollution Composite Resins Composite Resins/classification Composite Resins/economics Hemp Cannabis Cannabis/chemistry Cannabis/microbiology Nano-materials Sustainable economy Sustainable consumption Sustainable architecture Sustainable finance Sustainable Development Sustainable development Sustainable use Sustainable banking Natural sustainable development Sustainable Development/economics |
| url | https://doi.org/10.5281/zenodo.17834113 |