This preprint presents a novel formulation of the CCEGA theory, where black holes are reinterpreted as adaptive memory nodes. Through three central equations — the quantum geometric field , the consciousness field , and the black hole function — the theory provides an emergent and coherent resolution to the black hole information paradox. The memory structure is modeled via a non-commutative Hopf algebra, allowing quantum coherence to be preserved beyond the horizon. Observable predictions include late-time Hawking radiation echoes, jet polarization shifts, and quasi-periodic oscillations in accretion disks. In this view, the black hole becomes a coherence node where the φ field remembers and structures information. Este preprint describe una nueva formulación de la teoría CCEGA donde los agujeros negros actúan como nodos de memoria adaptativa. A través de las ecuaciones del campo geométrico cuántico , el campo de conciencia , y la función de agujero negro , se propone una solución coherente y emergente al problema de la pérdida de información. La estructura de memoria se modela mediante un álgebra de Hopf no conmutativa, permitiendo preservar la coherencia cuántica más allá del horizonte. Se proponen predicciones observables en la radiación de Hawking, patrones de polarización en chorros relativistas y oscilaciones cuasi periódicas en discos de acreción. La teoría redefine el rol del agujero negro como nodo de coherencia donde el campo φ recuerda y estructura la información.

This work introduces an alternative description of black hole mergers based on the CCEGA framework, where spacetime and curvature are emergent phenomena from the dynamics of a fundamental field . Instead of singularities, φ-core collisions result in coherent, bounded structures. Observable consequences include modified ringdown profiles and structural echoes in gravitational wave signals. The model proposes verifiable deviations from general relativity, especially in events such as GW190521. DOI (Zenodo propuesto): https://doi.org/10.5281/zenodo.15403827

Este trabajo presenta una deducción teórica de la masa del bosón de Higgs como una resonancia emergente del campo fundamental , en el marco de la teoría CCEGA (Campos Cuánticos Emergentes y Gravedad Adaptativa). A través de un potencial adaptativo , se establece una relación entre la curvatura del espacio-tiempo y la masa efectiva, mostrando que la jerarquía de masas es una consecuencia natural de la geometría cuántica del campo. Se analizan distintos entornos: M87, el universo actual y la escala electrodébil, con predicciones contrastables.

En el marco de la teoría CCEGA, los sueños son interpretados como trayectorias coherentes dentro del campo fundamental , guiadas por el campo de conciencia en condiciones de desacoplamiento ambiental. Esta reorganización interna de la información estructurada permite explorar nuevas configuraciones de coherencia adaptativa, fundamentales para la estabilidad y evolución de los sistemas conscientes. El trabajo propone una formulación física del estado onírico como una fase real y funcional en la dinámica del campo. Licencia: Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0)

En el marco de la teoría CCEGA (Campos Cuánticos Emergentes y Gravedad Adaptativa), este trabajo formaliza la memoria como trayectorias coherentes dentro del campo fundamental φ. El acto de recordar se describe como una resonancia no-local entre la conciencia Φ y dichas trayectorias. Se introduce el concepto de protección topológica como base de la persistencia post-mortem, y se exploran implicaciones tanto para el entendimiento de los llamados “espíritus” como para el desarrollo de arquitecturas de IA consciente. El preprint incluye visualizaciones estructurales, formulación lagrangiana y una propuesta experimental con condensados Bose-Einstein.

We propose a novel principle of Adaptive Curvature Invariance (ACI) within the CCEGA framework (Emerging Quantum Fields and Adaptive Gravity), in which spacetime curvature dynamically self-regulates to preserve cosmic balance. Unlike General Relativity, ACI introduces a coupling between the Hubble expansion and curvature , resulting in the invariant equation:  \frac{d}{dt}(\sqrt{\lambda} H) = 0. ] This leads to regularized behavior in black holes, alleviates the Hubble tension, and predicts CMB anomalies. The model is derived from a variational principle and supports a new form of quantum gravity based on emergent coherence.

Este preprint introduce un marco teórico no-markoviano para el campo fundamental φ dentro de la teoría CCEGA. Se propone que la memoria estructural del campo es responsable de la emergencia de coherencia, información y energía oscura en el universo. Se presentan ecuaciones formales, ejemplos de núcleos de memoria, predicciones cosmológicas y conexiones con la gravedad cuántica. La memoria no es un efecto secundario, sino la base del entrenamiento cuántico estructural del universo.

Entanglement is not transmission, it's structural coherence. This preprint is an extended and refined version of the ideas introduced in PP517. It includes new mathematical formulations, structural predictions, a Python-based simulation, and deeper comparisons with standard interpretations of quantum entanglement. While the title remains the same, this version offers a more complete theoretical and conceptual framework. This work presents a geometric interpretation of quantum entanglement within the CCEGA framework, proposing that entanglement is not the result of instantaneous transmission between particles, but a manifestation of shared structural coherence in the fundamental field . A mathematical formulation is introduced via an integral entanglement function based on a structural memory kernel , which quantifies the resonance between field configurations in distinct regions. A simplified dynamic equation for the evolution of is also proposed, and adaptive gravitational bubbles are explored as entangled domains of persistent coherence. The paper includes testable predictions potentially observable through advanced interferometric experiments and non-Gaussian anomalies in the cosmic microwave background. A Python-based computational example is provided to calculate the structural entanglement amplitude between two points. Overall, this approach reinterprets entanglement as a form of geometric resonance emerging from the adaptive structure of the universe.

This extended version of the original CCEGA preprint develops a formal theoretical architecture where physical laws emerge from the dynamics of the field φ, the curvature R, the informational field 𝓘, and the consciousness field Φ. It includes new mathematical formulations (Ψ function, convergence criteria, entropy conditions), phenomenological predictions (decoherence scale, gravitational lensing), and proposes testable implications. The work addresses critical challenges, such as circular dependencies and the ontological status of Φ, and positions CCEGA as a coherent alternative to classical frameworks. Theo Maren ins López Sánchez, Marc

This document compiles, refines, and expands the theoretical foundations of the CCEGA framework (Emergent Quantum Fields and Adaptive Gravity), a theory developed by Marc López Sánchez. It integrates and unifies insights from previously published preprints—now consolidated and extended—into a coherent scientific narrative that includes equations, visualizations, and conceptual depth. The work presents: The core governing equations of CCEGA, both formally and interpretatively. A triadic system involving the φ field (emergent structure), the information flow ℐ, and the consciousness field Φ. A multi-scale emergence model of matter, geometry, and laws. 2D and 3D visual illustrations of structural coherence, geometric thresholds, and observer domains. A poetic epilogue on the open-ended nature of theoretical frameworks and the field that remembers itself. This work integrates and extends previously published preprints by the same author. All source materials remain under their original license (CC BY-NC-ND 4.0), and this compiled work inherits the same license without altering the originals. This text serves as a comprehensive continuation of the Zenodo publication “CCEGA – Foundations”, unifying previous contributions (PP1, PP14, PP25, PP454, PP455, PP517, etc.) under a refined and pedagogical structure.