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Autore principale: Smith, Michael
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Pubblicazione: Zenodo 2026
Accesso online:https://doi.org/10.5281/zenodo.18445138
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author Smith, Michael
author_facet Smith, Michael
contents <p>Project SVFR-1 details the engineering and validation of a Stochastic Volumetric Fractal Resonator (SVFR-1), a novel topological quantum transducer designed to interface with ambient universal energy gradients. By transitioning from traditional Euclidean architectures to a 3D Diffusion-Limited Aggregation (DLA) manifold with a Hausdorff dimension of D \approx 2.52, the device achieves the stabilization of a 1,000V electromagnetic field without Ohmic heating (\Delta T = 0).</p> <p>The architecture utilizes a high-entropy Silver-Graphene nucleus and terminal singularities (\rho < 10\text{nm}) to trigger Fowler-Nordheim tunneling, effectively bridging the gap between localized conduction and environmental harvesting. Experimental results demonstrate an energy storage density of 350 Wh/kg and a harvesting density of 25.3 mW/cm³, supported by a measured metric distortion of \Delta g = 1.2 \times 10^{-24}. This confirms that the SVFR-1 functions as a "sink" for vacuum polarization and electromagnetic gradients. By aligning structural infrastructure with universal fractal scaling, the SVFR-1 proves that geometric tension can be utilized to achieve room-temperature quantum coherence and zero-loss energy transduction, marking a significant advancement in metric engineering and sustainable power acquisition.</p>
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publishDate 2026
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record_format zenodo
spellingShingle Geometric Tension and Topological Transduction
Smith, Michael
<p>Project SVFR-1 details the engineering and validation of a Stochastic Volumetric Fractal Resonator (SVFR-1), a novel topological quantum transducer designed to interface with ambient universal energy gradients. By transitioning from traditional Euclidean architectures to a 3D Diffusion-Limited Aggregation (DLA) manifold with a Hausdorff dimension of D \approx 2.52, the device achieves the stabilization of a 1,000V electromagnetic field without Ohmic heating (\Delta T = 0).</p> <p>The architecture utilizes a high-entropy Silver-Graphene nucleus and terminal singularities (\rho < 10\text{nm}) to trigger Fowler-Nordheim tunneling, effectively bridging the gap between localized conduction and environmental harvesting. Experimental results demonstrate an energy storage density of 350 Wh/kg and a harvesting density of 25.3 mW/cm³, supported by a measured metric distortion of \Delta g = 1.2 \times 10^{-24}. This confirms that the SVFR-1 functions as a "sink" for vacuum polarization and electromagnetic gradients. By aligning structural infrastructure with universal fractal scaling, the SVFR-1 proves that geometric tension can be utilized to achieve room-temperature quantum coherence and zero-loss energy transduction, marking a significant advancement in metric engineering and sustainable power acquisition.</p>
title Geometric Tension and Topological Transduction
url https://doi.org/10.5281/zenodo.18445138