Codex Alpha -Unified Theory Iconoclast edition v3.0

A coarse-grained description for the formation and evaporation of a black hole is given within the framework of a unitary theory of quantum gravity preserving locality, without dropping the information that manifests as macroscopic properties of the state at late times. The resulting picture depends strongly on the reference frame one chooses to describe the process. In one description based on a reference frame in which the reference point stays outside the black hole horizon for sufficiently long time, a late black hole state becomes a superposition of black holes in different locations and with different spins, even if the back hole is formed from collapsing matter that had a well-defined classical configuration with no angular momentum. The information about the initial state is partly encoded in relative coefficients---especially phases---of the terms representing macroscopically different geometries. In another description in which the reference point enters into the black hole horizon at late times, an S-matrix description in the asymptotically Minkowski spacetime is not applicable, but it sill allows for an "S-matrix" description in the full quantum gravitational Hilbert space including singularity states. Relations between different descriptions are given by unitary transformations acting on the full Hilbert space, and they in general involve superpositions of "distant" and "infalling" descriptions. Despite the intrinsically quantum mechanical nature of the black hole state, measurements performed by a classical physical observer are consistent with those implied by general relativity. In particular, the recently-considered firewall phenomenon can occur only for an exponentially fine-tuned (and intrinsically quantum mechanical) initial state, analogous to an entropy decreasing process in a system with large degrees of freedom.

Journal of the Korean Physical Society, 2013

It is suggested that the Einstein equation can be derived from Landauer's principle applied to an information erasing process at a local Rindler horizon and Jacobson's idea linking the Einstein equation with thermodynamics. When matter crosses the horizon, the information of the matter disappears and the horizon entanglement entropy increases to compensate the entropy reduction. The Einstein equation describes an information-energy relation during this process, which implies that entropic gravity is related to the quantum entanglement of the vacuum and has a quantum information theoretic origin.

Turkish Journal of Computer and Mathematics Education (TURCOMAT), 2021

The article endeavors to show how thinking about black holes as some form of hyper-efficient, serial computers could help us in thinking about the more fundamental aspects of space-time itself. Black holes as the most exotic and yet simplest forms of gravitational systems also embody quantum fluctuations that could be manipulated to archive hypercomputation, and even if this approach might not be realistic, yet it is important since it has deep connections with various aspects of quantum gravity, the highly desired unification of quantum mechanics and general relativity. The article describes how thinking about black holes as the most efficient kind of computers in the physical universe also paves the way for developing new ideas about such issues as black hole information paradox, the possibility of emulating the properties of curved space-time with the collective quantum behaviors of certain kind of condensate fluids, ideas of holographic spacetime, gravitational thermodynamics an...

2007

An increasing number of papers have appeared in recent years on decoherence in quantum gravity at the Planck energy. We discuss the meaning of decoherence in quantum gravity starting from the common notion that quantum gravity is a theory for the microscopic structures of spacetime, and invoking some generic features of quantum decoherence from the open systems viewpoint. We dwell on a range of issues bearing on this process including the relation between statistical and quantum, noise from effective field theory, the meaning of stochasticity, the origin of non-unitarity and the nature of nonlocality in this and related contexts. To expound these issues we critique on two representative theories: One [1, 2] claims that decoherence in quantum gravity scale leads to the violation of CPT symmetry at sub-Planckian energy which is used to explain today's particle phenomenology. The other uses this process in place with the Brownian motion model to prove that spacetime foam behaves like a thermal bath. A companion paper [5] will deal with intrinsic and fundamental decoherence which also bear on issues in classical and quantum gravity. * Email address: anastop@physics.upatras.gr † Email address: blhu@umd.edu 1 It also contains a short bibliography of some latest papers in related approaches to QG. Amongst the different approaches to quantum gravity the issues expounded by Sorkin [13], the ideas proposed by Wen [14] based on quantum order, the analog to condensed matter systems as expounded by Volovik [15], and the programs pursued by Ambjorn and Loll on Lorenzian dynamics of triangulated spacetime , that of Dreyer, Friedel, Levine, Markopoulo, Oriti, Rovelli and Smolin [18, on the structure and evolution of spin network are of particular interest, because one can use these explicit constructions to examine the issues raised here, e.g., seeing the hydrodynamic limit, or even the dynamically preferred dimension-four spacetimes.

Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics, 2013

Numerous approaches to a quantum theory of gravity posit fundamental ontologies that exclude spacetime, either partially or wholly. This situation raises deep questions about how such theories could relate to the empirical realm, since arguably only entities localized in spacetime can ever be observed. Are such entities even possible in a theory without fundamental spacetime? How might they be derived, formally speaking? Moreover, since by assumption the fundamental entities can't be smaller than the derived (since relative size is a spatiotemporal notion) and so can't 'compose' them in any ordinary sense, would a formal derivation actually show the physical reality of localized entities? We address these questions via a survey of a range of theories of quantum gravity, and generally sketch how they may be answered positively.

In this paper I give a major update of quantum gravity framework project. The heuristic conceptual framework proposed in previous versions is expanded to include structure formation and consciousness in the universe. A Path Integral version of decoherence in curved space-time is introduced as major update. Then we discuss the philosophical insights into structure formation in the universe and consciousness. We introduce various mathematical concepts to describe structure formation in the universe and consciousness.

The ‘Infinite Spiral Staircase theory’ or ISST (Hardy, 2015) hypothesizes at the origin of the universe (before Planck time, i.e. 10-43 second) a dynamical topology infused with a self-organized cosmic consciousness. The ISST aims at integrating the reality of consciousness in the universe within a cosmological framework. It posits that our universe originated as a field of information, itself issued from previous or parent universe-bubbles (UB). However, this field of information is very precisely and mathematically structured, and it is embedded in the dynamical topological form of a spiral. The metadimension Syg (S, consciousness) is entwined with two other metadimensions—Center (C, hyperspace) and Rhythm (R, hypertime)—to form the Infinite Spiral Staircase (ISS), that sets the dynamical thrust of a rapidly enlarging spiral, out of the ‘X-point’ of origin and toward Planck length. The three ‘metadims’ form a triune CSR hyperdimension. Any spiral created by the logarithm of phi, the golden ratio, is made out of quarters of circles (called ‘bows’), whose radii are incremented following the Fibonacci sequence; each bow being a precise and unique frequency. The ISS at the origin, on its quasi infinite number of bows, carries a gigantic set of frequencies. The bows will launch sygon waves—tachyonic virtual particles that will both create the hyperdimensional bulk and the spacetime region. The set of bow-frequencies on the cosmic ISS codes for innumerable systems and beings, acting as an active memory-bank issued from a collar of previous universe-bubbles and interacting with the unfolding universe.

Coherence Field Theory (CFT) posits that all physical phenomena - quantum, gravitational, and cosmological - emerge from phase alignment of quantum wavefunctions, quantified by a dimensionless scalar coherence field, C(x, t). Governed by a zero-parameter, relational equation. CFT unifies lasers, Bose-Einstein Condensates (BECs), superconductors, quantum entanglement, redshift anomalies, gravity, quasars, and the cosmic microwave background (CMB). Supported by redshift anomaly fits (e.g., NGC 4319), JWST’s early galaxies, and Planck’s CMB alignments, CFT eliminates dark matter, dark energy, singularities, and expansion, decisively rejecting the 39 flaws of ΛCDM, General Relativity (GR), and Friedmann-Lemaıtre-Robertson-Walker (FLRW) models, including undetected dark matter, speculative dark energy, and unphysical singularities. Testable predictions (e.g., SKA B-field maps, BEC gravity distortion) and gravity manipulation via C-field modulation redefine the universe as a manipulable domain. CFT offers a paradigm shift, replacing flawed mainstream models with a unified framework.

Quantum Resonance in Spacetime: How Gravitational Waves Modulate Quantum Coherence, 2025

This paper explores how gravitational waves influence quantum coherence, proposing that instead of merely causing decoherence, they may also restore entanglement. It introduces the Quantum Sensor Network (QSN) for detecting non-local perturbations and links this concept to the Cosmic Broth Theory (CBT), which describes spacetime as an emergent quantum substrate. The study suggests that time oscillates due to variations in the Cosmic Broth’s density, leading to measurable effects on pulsar timing, quantum entanglement, and gravitational interferometers. Proposed experiments using LISA, SKA, and atomic clocks aim to verify these predictions. If confirmed, the findings could redefine gravity as an emergent effect and provide a novel link between quantum mechanics and general relativity, with implications for quantum networking and space-based metrology.

International Journal of Quantum Information, 2012

In semiclassical gravity, the final state of black-hole evaporation cannot be described by a pure state. Nevertheless, we point out that the system can be described by a generalized pure state, which is not defined on a three-dimensional hypersurface but on the four-dimensional spacetime describing the whole Universe at all times. Unlike the conventional quantum state, such a generalized state treats time on an equal footing with space, which makes it well suited for systems that are both quantum and relativistic. In particular, such a generalized state contains a novel type of information encoded in the correlations between future and past, which avoids the black-hole information paradox.