Super-Materials

This manuscript investigates the theoretical properties of one-dimensional mag-carbon polymers, specifically mag-carbyne, as a lighter-weight alternative to the previously studied mag-carbon nanotubes (mag-CNTs). While mag-CNTs exhibit unparalleled absolute strength, their substantial linear mass density ($\approx 12.8 \text{ kg/m}$) presents a challenge for mass-critical applications. This work explores if a 1D polymer analogue can offer a superior strength-to-weight ratio. By applying a rigorously derived, carbon-specific scaling methodology to carbyne, theoretically the strongest 1D material, we calculate the properties of its magmatter counterpart. ...

This manuscript theoretically investigates the properties of mag-carbon nanotubes, building upon the recently refined understanding of magnetic monopole matter (magmatter) as a material forming stable crystal lattices. By deriving a new carbon-specific strength scaling factor of $5.60 \times 10^{38}$, we predict that mag-carbon nanotubes will exhibit a linear mass density of approximately $12.8 \text{ kg/m}$ and a theoretical tensile strength of $5.60 \times 10^{49} \text{ Pa}$. These calculations yield an unprecedented specific strength of $2.87 \times 10^{14} \text{ N} \cdot \text{m/kg}$ and a breaking length exceeding $2.93 \times 10^{13} \text{ m}$. Such properties suggest mag-carbon nanotubes could serve as a foundational material for revolutionary engineering feats, including single-stage space elevators and the construction of colossal megastructures. This study underscores magmatter’s potential to redefine material science, acknowledging the need for further research into its behavior under extreme gravitational potentials and the implications for large-scale structural design. ...

This manuscript presents a comprehensive analysis of the bulk density of magnetic monopole matter (magmatter), a material of critical importance to advanced galactic civilizations. We developed three theoretical models for mag-carbon density: a First-Principles (Packed Nucleus) model, a Bohr Radius (Isolated Atom) model, and a Diamond-like Lattice model incorporating packing efficiency. Our initial hypothesis, informed by the profound asymmetry of forces within magmatter, posited that its bulk density would align with the extreme condensation predicted by the Packed Nucleus model. Methodological validation against normal terrestrial diamond confirmed the distinct physical regimes governing normal and extreme matter. However, subsequent crystallographic analysis of a synthesized mag-diamond sample yielded an unexpected empirical result: its measured density ($\approx 2.0 \times 10^{35} \text{ kg/m}^3$) aligned closely with the Diamond-like Lattice model. This finding necessitates a significant revision of our understanding, suggesting that magmatter, despite its immense internal forces, forms stable, ordered crystal structures scaled by its unique atomic properties, rather than condensing to a fully degenerate state. This revised understanding, which also considers the potential influence of self-gravitation in larger constructs, opens new avenues for magchemistry and material engineering, bridging theoretical predictions with observed reality. ...

This theoretical framework introduces “magmatter,” a novel form of matter predicated on the existence of lighter, TeV-scale magnetic monopoles, serving as a fundamental dual to ordinary electrically charged matter. The manuscript systematically details its core constituents, specifically the fermionic magtron and magnucleus, and elucidates the powerful Higgs-boson mediated interactions responsible for binding them into extraordinarily compact magatoms, characterized by binding energies of approximately 300 GeV. The text comprehensively describes magmatter’s extreme macroscopic properties, including an astronomical density on the order of $\approx10^{33} \text{ kg/m}^3$, an expected melting temperature on the order of $\approx10^{14}$ Kelvin, and unique optical characteristics such as transparency to visible light and the perfect mirror-like reflectivity of its conductive “mag-metal” forms. Furthermore, it highlights magmatter’s capacity for largely unimpeded passage through ordinary matter unless specifically engineered for interaction. Quantitatively, the framework demonstrates magmatter’s unfathomable mechanical strength, calculated to be approximately $2.94 \times 10^{35}$ times greater than that of ordinary matter. This foundational work establishes magmatter not merely as a theoretical construct, but as an observed and extensively utilized material within advanced galactic civilizations, particularly for applications in the energy sector, the construction of megastructures, and the manipulation of exotic high-energy physical processes, with further practical applications reserved for subsequent detailed studies. ...