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This preprint introduces an original prediction within the CCEGA (Cosmic Curvature Emergence from Gravitational Adaptation) framework. It proposes that quantum fluctuations of curvature generate self-stabilizing gravitational structures in the centers of galaxies, altering the standard understanding of supermassive black holes (SMBHs). Instead of collapsing into singularities, these regions exhibit a dynamically emergent curvature field, which could explain certain observational anomalies such as larger-than-expected black hole shadows, unstable accretion disk structures, and deviations in gravitational lensing.
The study presents a modified Kerr-like metric incorporating oscillatory curvature effects and outlines observational signatures that can be tested with instruments like the Event Horizon Telescope (EHT), Chandra, XMM-Newton, and JWST. This prediction provides a testable alternative to singularity-based black hole models, offering new perspectives on high-energy astrophysics and quantum gravity.
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Title Quantum-Gravitational Structures in Galactic Centers: A Prediction from CCEGA Theory
This preprint introduces an original prediction within the CCEGA (Cosmic Curvature Emergence from Gravitational Adaptation) framework. It proposes that quantum fluctuations of curvature generate self-stabilizing gravitational structures in the centers of galaxies, altering the standard understanding of supermassive black holes (SMBHs). Instead of collapsing into singularities, these regions exhibit a dynamically emergent curvature field, which could explain certain observational anomalies such as larger-than-expected black hole shadows, unstable accretion disk structures, and deviations in gravitational lensing.
The study presents a modified Kerr-like metric incorporating oscillatory curvature effects and outlines observational signatures that can be tested with instruments like the Event Horizon Telescope (EHT), Chandra, XMM-Newton, and JWST. This prediction provides a testable alternative to singularity-based black hole models, offering new perspectives on high-energy astrophysics and quantum gravity.
🛡️ Intellectual Property Statement:
This work is an original scientific contribution by the authors. Any reproduction, distribution, or modification must acknowledge the authors and cite the original preprint. The content is registered under Safe Creative to ensure intellectual protection.
Work type Technical
Tags quantum gravity, theoretical cosmology, field equations, dark matter, alternative gravity model, adaptive gravity, deflection of light, emergent time, quantum cosmology, general relativity, cosmology, cosmological model, adaptive spacetime, cosmological simulations, quantum fields, emergent gravity, gravitational lensing, ccega, theoretical physicist, quantum fluctuations
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Entry date Mar 17, 2025, 2:28 PM UTC
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Author 100.00 %. Holder MARC LOPEZ SANCHEZ. Date Mar 17, 2025.
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