שמור ב:
| Main Authors: | , |
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| פורמט: | Recurso digital |
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Zenodo
2026
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| נושאים: | |
| גישה מקוונת: | https://doi.org/10.5281/zenodo.19570608 |
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הוספת תג
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תוכן הענינים:
- <p>We present a complete, relativistically consistent, testable theoretical framework in which the effective gravitational coupling of matter can be dynamically suppressed via coherent excitation of helical spacetime torsion.<br>The theory is constructed as an effective geometric extension of standard physics, fully reducing to the Standard Model and general relativity in the unexcited vacuum limit.</p> <p>Spacetime is endowed with an intrinsic helical decomposition into two dual torsion components:<br>tangential torsion $\tau_\perp$, associated with electromagnetic interactions,<br>and axial torsion $\tau_\parallel$, associated with gravitational and inertial response.<br>A universal normalization closure condition enforces a strict geometric duality:<br>\[<br>\tau_\perp \cdot \tau_\parallel = \kappa = 4\pi,<br>\]<br>where $\kappa$ is the topological invariant of 3D space.<br>Effective gravitational coupling is proportional to axial torsion,<br>so coherent enhancement of tangential torsion suppresses the effective gravitational response.</p> <p>A critical suppression threshold emerges naturally from fundamental constants:<br>\[<br>\frac{G_{\text{eff}}}{G_0} \approx \sqrt{\alpha^2 \kappa} \approx 0.04,<br>\]<br>corresponding to a stable, topologically protected quasi-excited state at approximately 4\% residual coupling.<br>This state exhibits strongly suppressed interaction cross sections,<br>near-perfect material transparency,<br>eliminated interatomic Coulomb barriers enabling room-temperature cold welding,<br>and weak electromagnetic coupling to ordinary matter.</p> <p>In the extreme excitation limit, the system approaches a near-null propagation regime<br>where the worldline becomes lightlike, proper time collapses,<br>and effective spatial separation vanishes in the proper frame.<br>This is a topological phase transition, not acceleration to light speed,<br>and is fully consistent with relativistic causality.</p> <p>We formulate five quantitative, falsifiable experimental predictions.<br>The framework provides a unified geometric description of mass, time, and spacetime,<br>with profound implications for fundamental physics and advanced materials engineering.</p>