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[24] ai.viXra.org:2511.0097 [pdf] submitted on 2025-11-30 22:14:23
Authors: Paulo Mendes Pereira
Comments: 8 Pages. paulopereira.nextv@gmail.com (Note by ai.viXra.org Admin: Please cite and list scientific references in a proper manner)
We present a complete quantum theory of gravity where spacetime is a discrete superfluid at the Planck scale. Fundamental particles emerge as topological vortex configurations, with masses quantized by topological invariants. We rigorously derive: electron mass (511 keV) from fundamental SUSY breaking; dark matter (35.2 MeV) as a Hopf link; proton mass (938 MeV) as Borromean rings. The theory predicts SUSY partners at 511 keV,solves the cosmological constant problem, and provides testable dark matter detectioncross-sections. All parameters are derived from first principles with no fine-tuning.Keywords: quantum gravity; discrete spacetime; topological field theory; dark matter;mass generation.
Category: Relativity and Cosmology
[23] ai.viXra.org:2511.0089 [pdf] submitted on 2025-11-27 17:54:51
Authors: Ivars Fabriciuss
Comments: 23 Pages.
This work presents a unified statistical origin of the full cosmic energy budget—dark energy, dark matter, and ordinary baryonic matter—derived from a single Planck-scale white-hole lattice existing in a dual spatial structure R³ ⊕ I³. The model introduces an imaginary spatial vacuum sector I³, populated by a negative-energy white-hole lattice, dynamically coupled to the observable sector R³ through a finite-capacity interface.At the Planck epoch, the primordial white-hole ensemble forms a two-level thermal system at the Planck temperature. Standard Boltzmann statistics uniquely yield the primordial partition of the vacuum into a stable E = 0 sector with fractional abundance 0.269 and a negative-energy inflation-driving sector with fractional abundance 0.731. The E = 0 white holes become permanent, non-radiating gravitational composites that constitute the dark-matter sector.The negative-energy lattice drives an inflationary phase without an inflaton field. Vacancies created by the first statistical emission appear in R³ as primordial Planck black holes, which later evaporate and geometrically reheat the universe but do not determine the baryonic abundance.Ordinary matter is generated only in a second two-level emission process of the surviving negative-energy lattice, governed by the energy levels −mc² and +mc² at the same Planck temperature. This secondary Boltzmann system predicts the probability of white-hole/black-hole pair emission. Each pair evaporates into a particle—antiparticle pair. One half of the products remains in R³ as ordinary matter, while the other half is absorbed into I³ and builds species-specific Dirac seas. This process quantitatively predicts the baryonic matter fraction Ω_b ≃ 0.0436 without invoking baryon-number violation.At late times, the finite information capacity of the R³—I³ interface drives a vacuum compaction process. This produces a universal dynamical saturation of the homogeneous dark-energy fraction toward Ω_Λ → ln(2) ≃ 0.693, distinct from the primordial inflationary value 0.731. The final late-time cosmic energy budget therefore emerges as:Dark matter (E = 0 white holes): 0.269Dark energy (vacuum compaction): 0.693Baryonic matter (secondary emission): 0.0436The framework predicts a late-time vacuum equation of state very close to w = −1, the complete absence of primordial antimatter due to irreversible transfer into I³, and a cold, collisionless dark-matter sector of geometric origin. Dark matter, dark energy, inflation, baryogenesis, and antimatter suppression arise as successive dynamical phases of a single Planck-scale white-hole lattice.
Category: Relativity and Cosmology
[22] ai.viXra.org:2511.0087 [pdf] replaced on 2025-12-13 23:47:46
Authors: Zhong Wang
Comments: 9 Pages.
The cosmological constant (Λ) is the cornerstone of the standard ΛCDM model, but the Dark Energy Spectroscopic Instrument (DESI) has found evidence for dynamical dark energy that challenges this paradigm. Here, we propose a radical resolution based on the first principle of "Physical Information," which underpins a new cosmological paradigm wherein the universe's contents arise through recursive phase transitions. We show that dark energy is the untransitioned remnant of the primordial positive energy field—a fossil from cosmic genesis. This ontology, with its fixed total energy and intrinsic decay (ρ_{DE} ∝ a^{-n}), naturally yields dynamical behavior in which the equation of state w(z) evolves and crosses the phantom divide (w = -1), providing a first-principled account for the quintom-like behavior reported by DESI. Moreover, it resolves the cosmological constant problem through a causal isolation mechanism rooted in the multi-sector geometry of the universe. This work transforms dark energy from a mathematical puzzle into a physical reality, charting a new path from phenomenological fitting to first-principled ontological derivation.
Category: Relativity and Cosmology
[21] ai.viXra.org:2511.0086 [pdf] submitted on 2025-11-26 11:18:42
Authors: Nick Markov
Comments: 39 Pages.
The Discrete Cosmology Model (DCM) reformulates gravitation and cosmic dynamics by introducing a causal description of mass. Every mass is treated as a finite-sized domain whose internal interactions propagate at finite speed. Because the forces that maintain a body’s shape and volume are not instantaneous, relativistic delays occur within the mass itself. In this framework, matter co-expands with space, and the local expansion speed is intrinsically relativistic rather than restricted to the low-velocity Hubble rate. The internal time lags distort the equilibrium geometry: regions experiencing shorter interaction delays expand into more-delayed regions, generating a net expansion-delay gradient that manifests macroscopically as gravity. The same principle applies across scales—from quantized particles to galaxies—providing a unified explanation for gravitational attraction, galactic rotation, and cosmological redshift offering an alternative to dark-matter—dependent descriptions by attributing the same effects to finite-speed, delay-driven mechanics. At the particle level, expansion and rotation (spin) cannot occur simultaneously at the relativistic limit; their discrete alternation produces quantized delay steps that define the energy states of matter. On larger scales, the cumulative gradients of these finite-speed interactions govern the curvature and apparent acceleration of the Universe. A core DCM prediction, equating electromagnetic and gravitational dilations, is empirically supported by seismic wave velocities on Earth, Mars, and the Moon, which align with escape velocities. By linking mass geometry, finite propagation speed, and delay-driven scaling, the DCM offers a testable causal framework for gravitation and cosmology.
Category: Relativity and Cosmology
[20] ai.viXra.org:2511.0080 [pdf] submitted on 2025-11-23 07:15:35
Authors: A. G. Schubert
Comments: 12 Pages.
In four-dimensional Lorentzian spacetime, the kinematics of photon rays can be described in a spinor language in which each future-directed null covector kμ and timelike observer uμ determines a normalized spinor zA ∈ S3 and an associated internal orthonormal triad of directions {𝓃(1)(z), 𝓃(2)(z), 𝓃(3)(z)} via the Hopf fibration. (PenroseRindler1984; PenroseRindler1986; SchubertHopfNullGeometry) This Hopf structure packages propagation direction, phase and polarization into a single spinor bundle over null congruences, entirely within the standard Einstein-Maxwell framework. In many physical situations, however, one is interested not in individual null rays but in ensembles of photons or null geodesics, for which a statistical description of internal directions is more appropriate than a strictly deterministic one.
In this paper we develop a minimal Gaussian framework for such ensembles. We introduce random normalized Hopf spinors ZA on the spinor sphere and the induced random internal triads {𝒩(1), 𝒩(2), 𝒩(3)} in ℝ3. Treating the internal directions as ℝ3-valued random variables constrained to lie on the unit sphere, we model their statistics by multivariate normal distributions in regimes where the ensembles are narrowly concentrated around a preferred frame. Gaussian models are singled out by their well-known maximum-entropy property under fixed mean and covariance and thus provide a natural, least-biased reference class once only low-order moments are specified. (Jaynes1957; CoverThomas2006)
The second-order statistics of the internal triad are organised into a correlation tensor Cabij, where a,b label the legs of the triad and i,j are spatial indices. We decompose the spatial part of this tensor into a scalar and a symmetric traceless tensor channel under SO(3), providing a systematic classification of isotropic ensembles and weakly anisotropic deformations. In parallel, we consider ensemble averages of spinor bilinears MAȦ = 𝔼[ZA Z̅Ȧ], which transform naturally under the spinor representation and may be regarded as 2×2 density matrices of unit trace. The mixed bilinear MAȦ is related to the mean internal direction and can be mapped to an effective four-vector by the Infeld-van der Waerden symbols.
The constructions presented here are purely kinematical and statistical: they do not introduce any new field equations beyond those of the underlying spacetime geometry and null kinematics. Instead, they establish a Gaussian ensemble description of Hopf spinors and internal directions, together with a channel decomposition of their second-order statistics. This provides a technical backbone for subsequent work in which specific correlation patterns in such ensembles will be related to effective scalar, vector and tensor quantities on spacetime.
Category: Relativity and Cosmology
[19] ai.viXra.org:2511.0061 [pdf] submitted on 2025-11-19 22:12:07
Authors: A. G. Schubert
Comments: 19 Pages.
We revisit curvature and Killing vectors in general relativity from a two-spinor and twistor viewpoint in which local on-shell time directions are taken as primary. Null directions are represented by spinor dyads kAA' = λA λ̃A', and photon kinematics as well as local energy measurements are expressed through scalar overlaps uAA' λA λ̃A'. On the timelike side, a unit vector field ημ defines a local on-shell time direction that governs proper-time flow for massive degrees of freedom or an effective inertial background. In static spacetimes ημ can be aligned with a timelike Killing vector, recovering the conserved energy E∞ = −pμ ξμ in spinor form. In non-stationary geometries ημ remains well defined but fails to satisfy the Killing equation; expansion and shear then quantify the obstruction to a global time symmetry.Curvature enters through the spin connection as holonomy acting on null spinor dyads and on ηAA', a viewpoint we summarize as twistor misalignment. Radial null propagation and gravitational redshift in Schwarzschild spacetime illustrate how this reorganized spinor description reproduces standard results without modifying classical general relativity. The overall framework emphasizes null and timelike spinor sectors as the carriers of geometric information and reformulates the logical role of Killing symmetry in a twistor-based language.
Category: Relativity and Cosmology
[18] ai.viXra.org:2511.0059 [pdf] submitted on 2025-11-20 07:56:24
Authors: A. G. Schubert
Comments: 15 Pages.
We make explicit the role of the Hopf fibration in the two-spinor description of null directions and photon kinematics in four-dimensional spacetime. Working in the standard two-spinor formalism, any future-directed null vector k is represented by a bispinor k = λ ⊗ λ̃, and a timelike observer field u singles out an observer-dependent unit spatial propagation direction n ∈ S² via k = ω (u + n) with ω = -u·k > 0. We show that this direction n can be written as the image of a normalized spinor z on the unit spinor sphere S³ under the Hopf map S³ → S², so that z acts as a spinorial "square root" of the photon direction in the observer frame.Using the SU(2) action on spinors, we associate with z a rotated set of Pauli matrices and thereby define an orthonormal internal triad {n^(1), n^(2), n^(3) = n} attached to each null ray. The Hopf fibration thus provides a natural fiber structure over the space of spatial directions, in which propagation direction, phase and polarization of light are encoded geometrically in a single spinor bundle. We illustrate the construction for plane waves in Minkowski spacetime and for radial null rays in the Schwarzschild geometry. The framework remains purely kinematical and within classical Einstein—Maxwell theory: we do not introduce new dynamical fields, but reorganize familiar two-spinor geometry so that the internal directions of light are explicit. This kinematical Hopf picture is intended as a geometric starting point for subsequent work on statistical ensembles of spinors, correlation-based effective channels and multi-twistor configurations.
Category: Relativity and Cosmology
[17] ai.viXra.org:2511.0057 [pdf] submitted on 2025-11-19 11:48:48
Authors: A. G. Schubert
Comments: 10 Pages.
We formulate the propagation of massless spin-1 fields on a fixed curved spacetime entirely in spinor and twistor language and identify the minimal kinematical structure required to describe photon energy, redshift, and lensing. Any null direction is represented as a bispinor kȦA = λA · λ̃̇A, so that a photon of definite helicity appears as a correlated pair of spin-1/2 spinors with field strength φAB ∝ λAλB. Standard geometric-optics results — null geodesic motion, the eikonal equation, and the observer-dependent energy E = −ħ uμkμ — arise directly from the parallel transport of these spinors via the spin connection, with curvature encoded in their evolution along null congruences.
Within this strictly conventional framework we propose interpreting photon energy as a persistent phase gradient between twistor sectors. Relative phases between neighboring null rays and between the photon’s spinor dyad (λA, λ̃̇A) and an observer’s four-velocity uȦA encode measurable frequencies and interference effects, while curvature reshapes these correlations through spinor transport. No modification of general relativity or electrodynamics is introduced; instead, the construction reorganizes familiar kinematics in a way that highlights the role of spinor/twistor correlations and phase in the geometry of light.
Category: Relativity and Cosmology
[16] ai.viXra.org:2511.0054 [pdf] submitted on 2025-11-17 01:27:23
Authors: Artemiusz Palla
Comments: 6 Pages. (Note by ai.viXra.org Admin: Please cite all listed scientific references)
We propose a novel interpretation of special relativity in which all relativistic effects—time dilation, length contraction, and relativistic momentum—are purely optical illusions arising from the finite and constant speed of light c. No physical changes in matter, clocks, or spacetime are required. The Lorentz transformation emerges naturally from signal delay, not from any alteration of reality. This view is mathematically equivalent to Einstein’s special theory of relativity (STR) but philosophically minimalist: the universe remains classical, and relativity is an artifact of observation.
Category: Relativity and Cosmology
[15] ai.viXra.org:2511.0051 [pdf] submitted on 2025-11-15 23:18:14
Authors: A. G. Schubert
Comments: 7 Pages.
We present a unified geometric framework in which spacetime, mass, curvature, and the complete spectrum of elementary particles emerge from the conservation of information—a generalized Noether symmetry. Building on the existence-invariance principle, we show that information conservation under sub-Planck transformations necessarily generates spin-2 gravitational dynamics. The theory provides a natural explanation for the 48 elementary fermionic particles of the Standard Model through the interplay of twistor geometry, Hopf fibration, and ensemble correlations. Key advances include: (1) a fundamental Noether symmetry of existence leading to information conservation, (2) a dynamical action principle derived from twistor correlations and Fisher information, (3) emergent Lorentz signature from ensemble statistics, (4) a group-theoretic origin of the $SU(3)_C times SU(2)_L times U(1)_Y$ structure, (5) a quantitative mass-generation mechanism, and (6) a first-principles derivation of gravitational dynamics as a spin-2 field from information conservation.The framework naturally reproduces the Koide mass relation, the existence of three generations, and the observed matter dominance, while making concrete, testable predictions for cosmology and particle physics.
Category: Relativity and Cosmology
[14] ai.viXra.org:2511.0046 [pdf] submitted on 2025-11-14 09:52:41
Authors: E.P.J. de Haas
Comments: 25 Pages.
We develop the explicit first--order calculus of the gravitational rotor $Q_gin{m Spin}(1,3)$ and show how general--relativistic metrics, gravitational flows, and MOND--type galactic dynamics arise directly from its adjoint action in the Dirac--biquaternion (BQ) algebra. Starting from rapidity fields in the rotor exponent, we derive the Schwarzschild, de Sitter, and Kerr forms in Painlev'e--Gullstrand coordinates, demonstrating that tetrads, the spin connection, and the metric follow from $Q_g$ without invoking Christoffel symbols or second--order curvature equations. The Q$_g$ current conservation law $D_mu J^mu=0$, together with the Bernoulli--Noether constraint, selects the Constant--Lagrangian with Hubble boundary (CL--H) flow as the unique stationary solution for axisymmetric rotating disks. This flow yields an azimuthal velocity profile $v_phi^2(r)=tfrac32,w^2(R)-w^2(r)$, where $w(r)$ is the mixed Schwarzschild--Hubble river velocity, and produces a covariant acceleration law containing the Newtonian, MOND, and cosmological de~Sitter regimes as limiting cases. The formalism therefore links the algebraic structure of the Dirac equation to relativistic metric construction and to observed galactic rotation curves within a single first--order gravitational framework.
Category: Relativity and Cosmology
[13] ai.viXra.org:2511.0035 [pdf] submitted on 2025-11-12 02:03:09
Authors: David Ginsberg
Comments: 33 Pages. CC BY License
Eight fundamental mysteries spanning 100+ years of physics are resolved through a single ansatz: time emerges as phase accumulation in a universal standing wave oscillating at the Planck frequency ωp = 1.86 × 10⁴³ rad/s. This framework unifies solutions to (1) time emergence from Wheeler-DeWitt equation, (2) speed of light from vacuum structure, (3) universal visibility window W = 1/6 from 6-fold symmetry, (4) antimatter asymmetry through temporal phase separation, (5) dark energy suppression (73 orders of magnitude) via time-averaging, (6) spacetime curvature from phase-coherent gravitation, (7) large-scale structure without dark matter, and (8) quantum-gravity bridge through entropy-Einstein coupling. All predictions are validated against observation: baryon asymmetry η = 6×10⁻¹⁰ (observed 6.1 × 10⁻¹⁰), dark energy ΩΛ = 0.662 (observed 0.685 ± 0.02, 3.3% error). The universal window appears robustly in eight independent cosmological domains, defending against curve-fitting criticism. Framework uses only established physics (Wheeler-DeWitt, WKB, Einstein equations); no new particles or exotic symmetries required.
Category: Relativity and Cosmology
[12] ai.viXra.org:2511.0034 [pdf] replaced on 2025-12-24 20:51:22
Authors: Fedor Kapitanov
Comments: 21 Pages.
We present a unified cosmological framework synthesizing three theoretical developments: Ontological Resolution Theory (ORT), discrete geometrodynamics, and topological field regularization. Observable reality is modeled as a finite "bubble" of information embedded in an infinite Absolute (Dirac sea). The bubble’s boundary—a membrane of N ∼ 10122 Planck-scale hexagonal cells—constitutes the holographic screen of the universe. A central result is the geometric defect theorem: optimal hexagonal packing necessarily produces a dodecagonal boundary with area coefficient exactly 3, yielding an irreducible defect (π − 3) ≈ 0.14159 per cell. This defect quantifies the "cost of discreteness"—the unavoidable mismatch between continuous geometry and discrete realization.From hydrodynamic equilibrium between the bubble interior and the Absolute, we derive: (1) Newton’s gravity as the stationary information flow condition; (2) the cosmological constant Λ ∼ N −1ℓ−2 P without fine-tuning; (3) alaboratory-accessible length scale ℓΛ = ℓP · N 1/4 ≈ 85 μm; (4) particle mass as the finite self-energy of topological lattice defects; (5) a geometric parametrization α−1 = π4 + 4π2 + (π − 3) ≈ 137.029 for the fine-structure constant.Black holes function as pressure-relief valves, maintaining equilibrium by processing excess information—partially returning it to the Absolute, partially re-emitting it via Hawking radiation.
Category: Relativity and Cosmology
[11] ai.viXra.org:2511.0029 [pdf] submitted on 2025-11-10 09:23:00
Authors: E.P.J. de Haas
Comments: 7 Pages.
This paper develops the cosmological consequences of the Qg rotor framework, a first--order algebraic formulation of gravity derived from the Dirac--biquaternion language. Building on previous work that established the gravitational rotor, mixed tensor, and current as linear bilinears of the spinor field, we derive the corresponding continuity and constitutive relations from the first--order Lagrangian and apply them to a homogeneous and isotropic universe. The resulting dynamics describes cosmic expansion as a precession of the gravitational rotor and leads to a linear version of the Friedmann law in which the expansion rate depends directly on the local spinor density and on an asymptotic rotor precession constant. This first--order structure reproduces the empirical expansion history of the universe without invoking a separate dark--energy component and restores the direct, local coupling between matter density and cosmic flow that is averaged out in the classical quadratic formulation. The framework provides a natural, quantitative explanation for the Hubble tension: variations in the locally measured Hubble rate arise from genuine differences in matter density rather than from systematic errors or new physics. The Qg cosmology thus offers a linear, covariant, and testable extension of Einstein--Cartan gravity that unifies local and cosmic dynamics within a single algebraic formalism.
Category: Relativity and Cosmology
[10] ai.viXra.org:2511.0028 [pdf] submitted on 2025-11-10 18:59:37
Authors: Tyren Leeks
Comments: 19 Pages. (Note by ai.viXra.org Admin: Please cite and list scientific references)
This Definitive Analysis proposes the **Unified Field Theory of Resonance (ΦRF T )**, which reinterprets the current state of the cosmos not as the product of an initial explosion, but as the **Reverberation of Initial Potential Collapse(RIPC)**—the persistent, residual harmonic energy left by the decay of a maximally dense, pre-universal field state. This decay established two fundamental and nearly-equal cosmologicalfrequencies: the background field’s natural resonance (ω0) and the emergent matter’s stable frequency (ωM). This work precisely models how the subtle, non-zero **sub-harmonic discrepancy** δω = |ω0 − ωM| creates a persistent, dynamic pressure in the electromagnetic vacuum. This pressure, equivalent to the cosmological acceleration traditionally ascribed to Dark Energy, drives theobserved expansion of the universe and governs the formation of large-scale structure via plasma-induced Birkeland currents ([1], [4]). ΦRF T demonstrates that this single, subtle frequency difference is sufficient to unify the gravitational and electromagnetic interactions, accurately account for the Cosmic Microwave Background (CMB) acoustic signature ([3]), and resolve majorparadoxes related to inertia and the flatness of space, providing the definitive, purely energetic foundation for the observed physical reality.
Category: Relativity and Cosmology
[9] ai.viXra.org:2511.0027 [pdf] replaced on 2025-11-12 07:36:34
Authors: E.P.J. de Haas
Comments: 20 Pages.
This paper presents the Qg rotor framework as an algorithmic bridge between Dirac algebra and gravitation. The gravitational field is expressed within the biquaternionic (Dirac) algebra, where the adjoint action of the rotor Qg on the Dirac basis generates the metric and connection directly, without introducing curvature as an external postulate. The mixed tensor M = EΦ and the Dirac current J = uM describe the coupling between matter flow and gravitational geometry, forming a complete linear set of algebraic field operators. From this structure an explicit translation algorithm is derived that reproduces the general-relativistic metric while remaining entirely within the covariant Dirac—BQ domain. Applying the constant-Lagrangian with Hubble boundary (CL-H) condition yields galactic rotation laws and MOND-type accelerations as covariant consequences of the same invariant. The result shows that gravitational and galactic dynamics can be formulated as a single, self-consistent algebraic flow within the Qg field, linking the Dirac formalism, general relativity, and MOND phenomenology.
Category: Relativity and Cosmology
[8] ai.viXra.org:2511.0022 [pdf] submitted on 2025-11-08 18:01:38
Authors: Maziyar Khademi-Astaneh
Comments: 15 Pages. 4 figures, 3 tables, submitted to Physical Review D (gr-qc, cross-listed to astro-ph.CO).
We present Chronoton Field Theory (CFT), a unified scalar-field framework in which gravitation and cosmological dynamics emerge from distortions in the local rate of time. The theory reproduces General Relativity in its screened limit while naturally explaining dark matter, dark energy, and inflation without invoking exotic components. The dilaton field defines an environment-dependent effective mass analogous to plasma or neutrino medium effects, leading to observable screening across astrophysical contexts. CFT provides explicit weak-field, cosmological, and cluster-scale solutions consistent with existing data and yields falsifiable predictions within current experimental precision: a 0.4 ns chromatic Shapiro delay during solar conjunctions and nanohertz-frequency pulsar-timing dispersion proportional to mA^2 / omega^2. The framework is stable, free of ghosts or tachyons, and recovers Einstein gravity in dense regions while predicting testable deviations in low-density environments. CFT links time flow, cosmology, and precision timing within a single falsifiable formalism.
Category: Relativity and Cosmology
[7] ai.viXra.org:2511.0016 [pdf] submitted on 2025-11-07 00:31:28
Authors: Martin Hristov
Comments: 5 Pages. (Note by ai.viXra.org Admin: Please cite listed scientific references)
This paper presents a unified geometrodynamic model derived from the principle of Spacetime-Matter Unity. We posit that matter is a stable topological configuration of spacetime, whose presence displaces the surrounding medium, creating a region of variable density—a gradient. We identify gravity as the kinematic result of motion along this gradient. From this single principle, we derive inertia as the work required to displace an object's own gravitational field through this gradient, and momentum as the persistent state of that field when in motion. This framework naturally contains the Newtonian limit, provides a physical interpretation for the de Broglie wavelength, and predicts the galactic rotation curve as a measurement of large-scale spacetime density gradients, resolving the dark matter problem. All three concepts—gravity, inertia, and momentum—are shown to be manifestations of a single geometric entity: the dynamics of self-gravitating spacetime structures.
Category: Relativity and Cosmology
[6] ai.viXra.org:2511.0014 [pdf] submitted on 2025-11-06 04:16:48
Authors: A. G. Schubert
Comments: 16 Pages.
This study proposes that spacetime, causality, and classical dynamics emerge from the invariance of existence—a generalized Noether symmetry where information is the conserved quantity and geometry its structured manifestation. Below the quantum threshold (δS < ħ), physical transitions are operationally indistinguishable, forming a smooth informational substrate. Local symmetry breaking (via measurement or interaction) yields stable identities manifesting as spacetime curvature. Using the Fisher information metric and its quantum extension, we propose the closure Gμν = κeff ℎμν, linking curvature to information flow. Thermodynamic analogies reveal expansion, entropy, and geometry as co-emergent, obeying an informational first law. This framework unifies entropic gravity, information geometry, and relational quantum mechanics, with extensions to Higgs stability and symbolic verification in toy models.
Category: Relativity and Cosmology
[5] ai.viXra.org:2511.0011 [pdf] submitted on 2025-11-06 04:01:03
Authors: Paulo Mendes Pereira
Comments: 11 Pages.
We propose that our universe is the sole survivor of a pre—T0 selection among microscopic quantum foams. Survival requires three local structural features: (P) Pauli exclusion for identical excitations, (E) long-range, phase-coherent entanglement "bands," and (Z) a quasi-local zero-energy ledger on all patches larger than a coherence length ξ. After survival, no post-T0 parameter tuning is possible: all observed constants and sectors must be intrinsic to the foam or uniquely derivable from P+E+Z. From these ingredients we sketch: emergent quantum mechanics (Hilbert space, unitarity, Born rule), a continuum gravity limit from a discrete entanglement graph with a zero-ledger constraint, a dark-matter sector of vortex-born sterile fermions with mass scale tied to the same ξ that fixes Newton’s constant, a slowly drifting dark-energy component from stochastic band relaxation, and an internal symmetry frame compatible with U(1)×SU(2)×SU(3). We present concrete work packages and falsifiers against 2025 datasets. Core claim (Popperian): almost all candidate law-sets fail before time; the survivor fixes the observed constants via its microstructure.
Category: Relativity and Cosmology
[4] ai.viXra.org:2511.0008 [pdf] replaced on 2025-11-26 07:02:13
Authors: Zhong WANG
Comments: 15 Pages.
The standard cosmological model is challenged by persistent large-scale anomalies, including the Cosmic Microwave Background (CMB) cold spot, baryon asymmetry, and the efficient early galaxy formation observed by the James Webb Space Telescope (JWST). This paper proposes a testable "Four-Sector Universe Model" based on a novel first principle of "physical information." The model posits that our universe is one of four constituent material universes (U1-U4) stabilized in a tetrahedral configuration within a higher-dimensional spacetime. It directly predicts that the CMB sky of our universe should exhibit two cold spots, caused by repulsion from negative-energy neighbouring universes, and one hot spot, caused by gravitational attraction from a positive-energy neighbouring universe, with angular separation relations reflecting the characteristic geometry of the tetrahedron. A preliminary analysis of Planck satellite data shows a qualitative agreement between the distribution of anomalous regions and this prediction. This model provides a unified origin framework for the aforementioned puzzles and suggests that the large-scale structure of the universe may originate from its macroscopic geometric architecture.
Category: Relativity and Cosmology
[3] ai.viXra.org:2511.0007 [pdf] replaced on 2026-01-08 21:46:03
Authors: Anđelko Đermek
Comments: 75 Pages.
This work develops a horizon-based reconstruction framework exploring whether gravitational collapse and black-hole horizon physics admit a consistent reinterpretation as the kinematic origin of an emergent cosmological spacetime. The approach is grounded in gravitational time dilation, black-hole thermodynamics, and holographic entropy bounds, and is presented as a conceptual and kinematic construction rather than a complete dynamical theory. In Schwarzschild geometry, infalling matter approaches the event horizon only asymptotically in the external time governing causal communication. This motivates an operational description in which infalling quanta are incorporated through discrete Planck-scale updates on a stretched horizon, treated as a null synchronized, information-bearing surface with finite causal throughput. Lateral lightlike adjacency enforces coherence across the horizon, while the ordered growth of the horizon provides a natural causal ordering that can be used to define an internal notion of time. A kinematic mapping is constructed from this two-dimensional, null-ordered surface to an effective three-dimensional bulk description. Tangential adjacency supplies transverse spatial structure, generational layering defines an effective radial coordinate, and global retessellation establishes temporal ordering. Under these assumptions, the reconstructed interior admits a homogeneous and isotropic Friedmann—Lemaître—Robertson—Walker envelope with coasting expansion H(t) ∼ 1/t and an internal age of order ∼ 13.4 Gyr. When the parent black hole carries angular momentum, Kerr-induced azimuthal phase gradients across the horizon encoding provide a possible geometric origin for large-scale parity-violating correlations and preferred axes. Quantum randomness is interpreted as arising from coarse-grained access to underlying boundary dynamics rather than from intrinsic indeterminism. In this framework, the event horizon is reinterpreted not as a passive geometric boundary but as an actively evolving causal encoding surface whose null-ordered structure supports an emergent interior spacetime description.
Category: Relativity and Cosmology
[2] ai.viXra.org:2511.0005 [pdf] submitted on 2025-11-02 21:25:37
Authors: Martin Hristov
Comments: 5 Pages.
This paper provides a field-theoretic derivation of the equivalence between inertial and gravitational mass, formalizing a recent heuristic model. We demonstrate that by modeling a mass as a static gravitational potential and calculating the work required to accelerate this field configuration against its own gradient, the resulting inertial force is necessarily proportional to the gravitational mass. This transforms the equivalence principle from a postulate into a derivable consequence of gravitational self-interaction. This formal argument serves as a core prediction of a broader research program aimed at a purely geometric unification of matter and spacetime. The author is seeking collaboration with researchers possessing expertise in differential geometry and general relativity to further formalize this framework.Contact: M.V.Hristov@proton.me
Category: Relativity and Cosmology
[1] ai.viXra.org:2511.0001 [pdf] submitted on 2025-11-01 00:29:57
Authors: E.P.J. de Haas
Comments: 264 Pages.
The Constant--Lagrangian inflow model is tested against the SPARC database of galactic rotation curves, using a two--parameter formulation defined by the bulge radius (R) and enclosed mass (M), with the cosmological expansion rate fixed at (H_z = 2.2times10^{-18},mathrm{s^{-1}}). The model assumes that the galactic metric behaves as a Bernoulli medium satisfying a stationary constant--Lagrangian condition, (tfrac{1}{2}(v_r^2+v_phi^2)+Phi_{mathrm{eff}}=mathrm{const}), yielding a radial inflow component (v_{r,mathrm{eff}}=sqrt{2GM/r}-H_zr). This prescription produces accurate fits for both the rising inner regions and the flattened outer disks of galaxies without invoking dark matter. Across the sample, typical reduced chi--squared values fall in the range (chi_u^2=0.05{-}0.4) with relative residuals below 10%, outperforming MOND and cored--halo dark--matter models while using fewer and physically interpretable parameters. The fitted parameters correlate directly with observed morphological scales, linking photometric features such as disk breaks and bar radii to dynamical transitions in the inflow field. The results indicate that galactic rotation curves can be explained as manifestations of a self--organising spacetime flow governed by the Bernoulli--Noether closure (v^mu D_mu Q_g=0), where (Q_g) is the gravitational rotor field defining the local lapse and shift of the Dirac algebra. This establishes a direct empirical foundation for the (Q_g) formalism and supports the interpretation of galactic dynamics as first--order gravitational kinetics rather than as evidence for unseen matter or modified inertia.
Category: Relativity and Cosmology