Engineered Graviton Condensates in a Room-Temperature Superconductor for a Unified Quantum Fibonacci Field Theory
- URL: http://arxiv.org/abs/2404.01262v1
- Date: Mon, 1 Apr 2024 17:34:22 GMT
- Title: Engineered Graviton Condensates in a Room-Temperature Superconductor for a Unified Quantum Fibonacci Field Theory
- Authors: Yoong S. Phang, Artem V. Talanov,
- Abstract summary: We introduce a novel ambient superconductor fabricated through the bombardment of a dilute Bose-Einstein condensate with high-energy gamma photons.
We demonstrate the successful induction of a graviton condensate within our engineered superconductor.
This graviton condensate represents a critical step towards a unified field theory, bridging the gap between quantum mechanics and general relativity.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: In the quest to unify quantum mechanics with general relativity, the concept of gravitons as quantum carriers of gravitational force stands as a pivotal yet unproven hypothesis. This work pioneers a bold approach to graviton condensation via an innovative ambient superconductor, synthesized through a groundbreaking yet theoretically plausible physics process. Building on recent superconductivity breakthroughs, we introduce a novel ambient superconductor fabricated through the bombardment of a dilute Bose-Einstein condensate with high-energy gamma photons, under precisely controlled magnetic fields oscillating in Fibonacci sequence patterns. This process, designed to exploit quantum coherence at macroscopic scales, fosters conditions ripe for graviton condensation. Here we demonstrate the successful induction of a graviton condensate within our engineered superconductor, marking a significant stride towards integrating gravitational and electromagnetic forces at a quantum level. This discovery not only defies traditional views separating the four fundamental interactions but also lays down a tangible groundwork for quantum gravity. Our results challenge existing paradigms by indicating that graviton condensation, mediated through tailored superconducting states, can unlock new aspects of fundamental physics. This graviton condensate represents a critical step towards a unified field theory, bridging the gap between quantum mechanics and general relativity. This investigation not only extends the boundaries of theoretical physics but also hints at potential future technologies harnessing the quantum interplay of gravitational and electromagnetic forces. Through imaginative yet rigorous scientific inquiry, this study underscores the limitless potential of physics to explore and unify the natural world's most fundamental forces.
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