J.W. Vegt
Eindhoven University of Technology,
Netherlands
Keywords: photon absorption, electron mass, speed of light, electromagnetic interaction, gravitational electromagnetic confinements, light to matter transformation, Bose-Einstein condensate, gravitational-electromagnetic interactions, general relativity, quantum mechanics
Summary:
This presentation explores the transformation of light into matter, focusing on the interaction between photons and electrons that results in increased electron mass and energy levels. A fresh interpretation challenges the core assumption of an invariant speed of light by examining its variability during photon absorption by electrons, prompted by electromagnetic interactions that slow light down. This phenomenon is crucial for understanding the transformation process as electrons absorb photons, increasing their energy and mass, effectively illustrating the conversion of electromagnetic energy into matter. Our exploration begins by examining how electromagnetic radiation behaves within a Bose-Einstein condensate—a medium where light's speed is substantially reduced. This deceleration allows light to manifest properties that contribute significantly to the interaction between photons and electrons. Building on Lene Vestergaard Hau's pioneering experiments, which revealed the dramatic slowdown of light within such condensates, this research highlights the intricate balance between light and matter. Further, this study extends Einstein's concepts, moving beyond a geometric interpretation of gravity to propose a synthesis of gravitational and electromagnetic forces through the interaction of Stress-Energy and Gravitational Tensors. This integration reveals the transition of light into mass and energy as a key process facilitated by electromagnetic interactions. Proposed models suggest that Black Holes act as Gravitational Electromagnetic Confinements, further evidencing this transformation under extreme conditions. By introducing advanced theoretical models that incorporate quantum mechanics, this work aligns with recent advances in theoretical physics, resonating with solutions to Wheeler's relativistic quantum mechanical Dirac equation. Upcoming experiments with Galileo Satellites and ground-based MASER frequency measurements aim to empirically validate these theoretical insights, potentially uncovering deviations from General Relativity. The convergence of Quantum Physics and General Relativity within innovative frameworks such as String Theory is expected to redefine core gravitational concepts, enriching our understanding of the synergy between light and gravitational forces. This research illuminates the transformational potential of light into matter, proposing a paradigm shift with significant implications for advancements in physics. Keywords: Photon Absorption, Electron Mass, Speed of Light, Electromagnetic Interaction, Gravitational Electromagnetic Confinements, Light to Matter Transformation, Bose-Einstein Condensate, Gravitational-Electromagnetic Interactions, General Relativity, Quantum Mechanics. [1] Vegt Wim; The Origin of Gravity; Research & Reviews: Journal of Pure and Applied Physics; Manuscript No. JPAP-22-76022(A); Published: 26-Oct-2022; DOI: 10.4172/2320-24 59.10004 / https://www.rroij.com/open-access/the-origin-of-gravity.php?aid=91966 [2] Vegt Wim, Enhancing precision in electromagnetic force density modulation using LASER control, Journal of Laser Applications; Published December 05 2024; DOI: https://doi.org/10.2351/7.0001636