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[23] ai.viXra.org:2604.0105 [pdf] submitted on 2026-04-30 21:10:04
Authors: Vladimir S. Netchitailo
Comments: 9 Pages.
This paper is a personal account of a life in physics, spanning more than five decades of study, research, and reflection. My scientific path began with a deep appreciation for the internal consistency of classical physics, which offered not only precise descriptions of natural phenomena but also a sense of logical completeness. As my work expanded into other areas of theoretical physics and, eventually, cosmology, that early sense of clarity was increasingly challenged by the growing complexity—and, at times, ambiguity—of modern theoretical constructs.Throughout these years, I was repeatedly drawn to questions that seemed resistant to conventional interpretation. Among them were the dynamics of small solar system bodies and the nature of objects classified as interstellar, where observed non-gravitational effects often appeared difficult to reconcile with standard explanations. These were not isolated curiosities, but recurring signals that, in my view, pointed to deeper inconsistencies in widely accepted models.The ideas presented in this work did not arise from a single breakthrough, but from a long and often nonlinear process of questioning assumptions, revisiting earlier conclusions, and seeking coherence across different domains of physics. The resulting cosmological perspective reflects this cumulative effort—an attempt to restore a sense of unity between fundamental physical principles and observational evidence.I do not present these results as final answers. Rather, they represent the current stage of an ongoing inquiry shaped by experience, doubt, and persistence. If this work has a central purpose, it is to encourage a careful reexamination of familiar assumptions and to suggest that progress in cosmology may still depend on asking old questions in new ways.
Category: Relativity and Cosmology
[22] ai.viXra.org:2604.0098 [pdf] submitted on 2026-04-28 20:01:44
Authors: Rüdiger Giesel
Comments: 29 Pages. (Note by ai.viXra.org Admin: Please cite listed scientific references)
We formulate a consistent octonionic foundational model in which gravity, matter dynamics, and non-associative coupling arise from a common variational principle. The starting point is a set of physical minimal principles: the requirement of real observables, local dynamics, covariant formulation, positivity of a norm, minimal algebraic nontriviality, and the requirement that genuine triple couplings may be fundamental. From these principles it follows step by step that the relevant internal algebra must be a normed division algebra, and that the only finite-dimensional non-associative possibility is the algebra of octonions. Since non-associativity becomes visible only through the associator of three arguments, the minimal dynamical realization is a triplet of octonion-valued fields. On this basis the full covariant action is constructed, and its variation yields the coupled master equation: the Einstein equation together with three octonionic field equations sourced by the associator. Every term, coupling, and parameter is explicitly introduced and physically interpreted.
Category: Relativity and Cosmology
[21] ai.viXra.org:2604.0094 [pdf] submitted on 2026-04-27 17:02:40
Authors: Floriano R. Pohlmann
Comments: 8 Pages. This is a refined version of the previous uploaded paper (viXra: 2604.0073) with same title
We propose an experiment to test whether the one-way speed of light is isotropic, without relying on clock synchronisation between separated stations. Two identical stations separated by a fixed distance exchange laser beams through complementary shutters driven by independent atomic clocks. Because the shutters are complementary, the two detector readings always move in opposite directions as the phase offset at one station is swept — they never reach maximum simultaneously. The correct observable is the phase offset at which the two detectors read equal intensity: the crossing point. In the isotropic case this crossing point is stable as Earth rotates. In the anisotropic case it drifts cyclically with the sidereal period. No synchronisation signal is required and the measurement is not circular.The experiment provides two independent observables recorded in parallel. The first is the optical crossing point described above. The second is the timestamp time series δ_WE and δ_EW recorded independently at each station. In the isotropic case both series show no variation. In the anisotropic case both series show a cyclic variation locked to the sidereal day. Both observables respond to the same underlying quantity — the asymmetry between W→E and E→W propagation times — and both share a common-mode rejection of local environmental disturbances by virtue of the 50-metre station separation.Frequency identity between the two stations rests on the constancy of the atomic transition — a physical fact, not an engineering convention. The only signals exchanged between stations are timestamp pulses transmitted at regular intervals to build up the time series described in Section 5.2. No synchronisation signal of any kind is used. The phase relationship between the two shutter drives is never imposed externally; it is found empirically by the crossing-point procedure. The experiment is sensitive to any preferred-frame velocity component along the baseline. A null result constrains preferred-frame theories. A non-null result warrants careful independent replication.
Category: Relativity and Cosmology
[20] ai.viXra.org:2604.0092 [pdf] submitted on 2026-04-27 16:55:50
Authors: Aleksey Razumovsky
Comments: 9 Pages. (Note by ai.viXra.org Admin: Please don't name title, equation/formula etc after the author's name; please cite listed scientific references)
We present a cosmological framework in which dark energy emerges directly as theholographic thermodynamic cost of irreversible entropy and information production withinour universe. The framework rests on two foundational boundary conditions—the TwinLaws of Conservation—that strictly enforce local conservation of energy and fundamentalquantum information inside any existing universe while allowing new fundamental quantitiesto arise only at the birth of a new universe (bubble nucleation or analogous origin events).Dark energy density is expressed by the unifying equation:ρDE(a) = β(.^S_irr(a)/a^3 where β is derived from M-theory flux compactifications and Sirr(a) is the observed irreversible entropy-production rate from astrophysical processes such as black-hole mergers and stellar dissipation. The microscopic realization is a single real scalar field trapped in a metastable false vacuum that undergoes slow "static-charge" buildup driven by a naturally derived tilt parameter. When a critical threshold is reached, quantum tunneling (Coleman—De Luccia instanton) or extra-dimensional leakage discharges the accumulated energy, nucleating anew causally disconnected bubble universe. The nucleation rate acquires an explicit timedependence Γ(t) ∝t−2 from Hubble suppression in the expanding background. All parameters are fixed by observables and string-theory UV completion. The model produces mild w(z) evolution consistent with DESI Data Releases 1 and 2, generates a transient early dark energy phase at z≈3500 that simultaneously alleviates the Hubble and S8 tensions, and predicts a distinctive stochastic gravitational-wave background featuring a softened infrared tail and a secondary mHz hump inside the projected LISA sensitivity band. Monte-Carlo simulations of the charge-discharge process confirm hierar-chical bubble-universe formation with lengthening cycle lengths. We discuss falsifiability with forthcoming DESI, LISA, and CMB-S4 data.
Category: Relativity and Cosmology
[19] ai.viXra.org:2604.0078 [pdf] submitted on 2026-04-22 19:49:46
Authors: Fernando Salmon Iza
Comments: 5 Pages.
For decades, the prevailing view in the scientific community has been that our universe is expanding at an accelerating rate. However, a recent experimental study (Junhjuk Son et al., 2025) seems to confirm that our universe shows no signs of acceleration; that is, we might be living in a non-accelerating universe. In this work, we present evidence that this result agrees with the predictions of relativistic theory. To this end, we present a new proof of the zero active mass equation (ρ + 3p = 0) for a universe with FLRW metric and zero spatial curvature (k = 0). We study the expansion of the universe by analyzing two partial models: a classical energy model and a thermodynamic fluid dynamics model. The interrelation between these two models demonstrates that all universes with zero spatial curvature, a Lapse function equal to one, satisfy the zero active mass equation and are necessarily non-accelerating. Their linear expansion is solely a consequence of the pressure of the cosmic fluid and not of any other additional terms in the Friedmann equations.
Category: Relativity and Cosmology
[18] ai.viXra.org:2604.0076 [pdf] submitted on 2026-04-21 18:16:16
Authors: Tianliang Zhuang
Comments: 4 Pages.
A specific form of logarithmic periodic modulation in the primordial curvature power spectrum is derived from the hypothesis of discrete scale invariance in the early universe. The modulation frequency is fixed by the Feigenbaum constant $delta approx 4.669$ and an effective spectral dimension $d_s = 1.25$, yielding $omega = 2pi / ln(delta^{1/d_s}) approx 3.67$. The modulation amplitude is determined by a single dimensionless parameter $eta = 0.08931$, giving $B = eta^{1/2} approx 0.30$. When the modulated spectrum is fitted with a smooth power-law template over the limited CMB window, the effective spectral index is shifted to $n_s^{text{eff}} approx 0.966$, in close agreement with the Planck 2018 value $n_s = 0.965 pm 0.004$. The predicted oscillatory pattern provides a distinctive signature for future high-precision CMB experiments.
Category: Relativity and Cosmology
[17] ai.viXra.org:2604.0070 [pdf] submitted on 2026-04-18 21:55:51
Authors: Andrew Ebanks
Comments: 6 Pages.
The resolution of the Black Hole Information Paradox [1] requires a formal bridge between thecontinuous curvature of General Relativity and the discrete logic of Quantum Mechanics. We present the Fibonacci-Tetrahedral Lattice (FTL) framework [2], which identifies a universal geometric identity between these two domains: the scaling constant of the Schwarzschild radius is exactly twice the scaling constant of the discrete Planck core (Rs = 2Rcore). This "FTL-Schwarzschild Identity" originates from an exact 2.000 ratio between the fundamental constants of General Relativity and the Planck length-mass ratio (Lp/Mpl). By formalizing a physical saturation limit (ρmax) at the 0.866 metric compression threshold, we replace the mathematical singularity with a structurallystable "Planck Core." This enforces strict Unitarity, as incident quantum states are deterministically mapped into the topological strain field of the core boundary. Furthermore, we provide a rigorous geometric derivation of the Bekenstein-Hawking entropy, proving that the 1/4 scalar is a trigonometric consequence of Cauchy’s Surface Area Formula during the dimensional projection of a 3D FTL cell onto a 2D event horizon. Finally, we provide a zero-parameter unification of black hole variability, matching the observed QPO periodicities of stellar-mass and supermassive black holesacross nine orders of magnitude (see Table III). This framework establishes the first deterministic, testable substrate for a unified theory of gravity.
Category: Relativity and Cosmology
[16] ai.viXra.org:2604.0069 [pdf] submitted on 2026-04-18 19:08:18
Authors: Vladimir S. Netchitailo
Comments: 16 Pages.
We analyze observational constraints on the object C/2025 N1 (ATLAS), currently designated 3I/ATLAS, including its inferred size, mass, albedo, dust properties, and non-gravitational acceleration. Several of these characteristics are difficult to reconcile simultaneously within the standard sublimation-driven cometary model, particularly the persistence of activity at large heliocentric distances and the presence of relatively large dust grains. We investigate whether these properties can be interpreted within a framework in which internal energy-release processes contribute significantly to the evolution of Small Solar System Bodies .While an interstellar origin remains possible, we demonstrate that a Solar System origin in the Oort Cloud, followed by dynamical modification, remains a viable and testable hypothesis.This paper argues that the hyperbolic comet currently designated 3I/ATLAS is not interstellar, but instead a Solar System object whose apparent hyperbolicity arises from a non-standard, quasi-constant non-gravitational acceleration powered by internal processes within It. The results motivate further observational and theoretical studies of internal energy mechanisms in Small Bodies.
Category: Relativity and Cosmology
[15] ai.viXra.org:2604.0065 [pdf] submitted on 2026-04-17 00:13:17
Authors: Vladimir Trifonov, Philip V. Trifonov
Comments: 7 Pages. 1 figure
The $Lambda$CDM model successfully accounts for cosmic expansion and large-scale structure but treats dark matter, dark energy, and the fine-structure constant $alpha$ as independent inputs. We present a compact geometric construction in which all three emerge from the interplay of two natural measures --- a metric (Lebesgue-type) measure and an invariant (Haar-type) structural measure --- on FLRW spacetime and its underlying hyperquantum fibers. A single crossover scale $r^* = e^{-1}$ and a unified visibility kernel $K(x) = Sigma(x) cdot Pi_{m time}$ (with $Pi_{m time} = 1/2$ from the arrow-of-time projection) simultaneously produce the observed baryon-to-dark-matter ratio $Omega_{m DM}/Omega_b approx 5.4$, suppressed late-time growth of structure, and the precise value $alpha^{-1} = 4pi^3 + pi^2 + pi + delta approx 137.036$ (where $delta$ is the explicit higher-order vista correction). The framework requires no new particles, no free parameters, and makes concrete, falsifiable predictions for current and upcoming surveys and precision measurements of the fine-structure constant $alpha$.
Category: Relativity and Cosmology
[14] ai.viXra.org:2604.0064 [pdf] submitted on 2026-04-15 20:59:50
Authors: Andrew Ebanks
Comments: 6 Pages.
The Cosmic Microwave Background (CMB) is the most precise dataset in cosmology, yet it con-tains persistent "anomalies" that defy the standard ΛCDM paradigm. These include the low-multipole alignment ("Axis of Evil"), the statistically improbable Eridanus Cold Spot, and large-scale temperature asymmetries. We propose that these features are not statistical artifacts, but thegeometric thermodynamic signatures of a discrete vacuum structure: the Fibonacci-TetrahedralLattice (FTL). By modeling the early universe as a crystallizing lattice undergoing a phase tran-sition, we recontextualize these anomalies into structural necessities. We analytically derive (1)the acoustic peaks as the Dirichlet eigenvalues of a tetrahedral cavity (Td symmetry) rather than aspherical fluid; (2) the Axis of Evil as the macroscopic growth spine of a Bianchi Type-VIIh metric;(3) the Cold Spot as a mathematically bounded topological texture arising from the fundamental7.36◦ geometric frustration gap; and (4) the associated Warm Spots as elastic lattice caustics andantipodal nodes. Finally, we establish a falsifiable framework for the model by predicting a localizedB-mode "Polarization Vortex" generated by the Berry Phase of the spatial disclination, which isdirectly testable by next-generation microwave observatories.
Category: Relativity and Cosmology
[13] ai.viXra.org:2604.0055 [pdf] submitted on 2026-04-13 01:10:35
Authors: Rüdiger Giesel
Comments: 16 Pages. (Note by ai.viXra.org Admin: Please cite listed scientific references)
We propose that the Hubble tension can be understood as a dynamical consequence of octonionic non-associativity. A physically relevant realization requires a genuinely nontrivial associator sector, which necessarily involves multiple octonionic fields. We therefore construct the minimal triplet model with three octonion-valued scalar fields and a covariant associator norm contribution ∥A(Ψ1,Ψ2,Ψ3)∥2 in the action. From this action we derive the Einstein equations, the coupled octonionic matter equations, and the homogeneous FLRW reduction. In the resulting effectivecosmology, the associator sector can be suppressed in the early universe while remaining nonzero at late times, thereby generating a redshift-dependent deformation of the expansion history. This produces a framework in which early-universe observables remain close to the standard backgroundwhile late-time observables can infer a larger effective Hubble scale. We also formulate a directly testable phenomenological parametrization suitable for confrontation with Pantheon+ and DESI DR2. Current data do not yet establish a unique global best fit for the octonionic parameters, but they do show that a late-time, redshift-dependent departure from strict ΛCDM remains phenomenologically viable and is qualitatively aligned with the kind of deformation generated by the octonionic associator sector.
Category: Relativity and Cosmology
[12] ai.viXra.org:2604.0053 [pdf] submitted on 2026-04-12 16:58:06
Authors: Qiong Lau
Comments: 8 Pages.
Two of the most profound unresolved challenges in contemporary physics are the ontological nature of the dark sector and the ultraviolet divergence in quantum gravity. This paper proposes an alternative ontology: the vacuum is not an empty geometric manifold, but a continuous, incompressible superfluid medium (the "Yuanzhi" field) characterized by an extreme bulk modulus Kyz and a microscopic healing length ξ. Within this framework, fundamental particles are identified as stable topological vortex excitations (knots) of the medium, while gravity emerges naturally as an isotropic macroscopic pressure gradient, and quantum entanglement is strictly governed by the global curvature of the Madelung quantum potential. Through a strict, no-free-parameter geometric derivation, this paper yields the electron rest mass scaling formula me = 1 2πMP (lP /Lknot) ≈ 0.511 MeV. Furthermore, the dark energy density is analytically derived as the acoustic Casimir pressure of vacuum fluctuations subject to the ξ cutoff, yielding B = π2 90 ℏc/ξ4. To distinguish this fluid dynamics model from established paradigms, we present four independent, testable observational predictions: (1) The spatial anisotropy ofthe GZK cutoff energy correlated with local cosmic void densities; (2) The anomalous precession in Lunar Laser Ranging (LLR) induced by fluid shear drag; (3) The doublehorn caustic optical signatures of Bose-Einstein Condensate (BEC) quantum vortex lenses in dark matter halos; (4) The annual modulation of diurnal clock biases in GEO satellites. For the latter, we propose a partial correlation analysis demonstrating that the clock drift amplitude correlates significantly with solar wind velocity (Vsw) rather than solar radio flux (F10.7), providing a crucial experimental discriminator against conventional thermal noise models.
Category: Relativity and Cosmology
[11] ai.viXra.org:2604.0052 [pdf] replaced on 2026-04-12 18:13:40
Authors: Richard Holland
Comments: 14 Pages. Abstract did not format correctly
We present a relativistic hypothesis based on a universal Planck-frequency interaction budget postulate that is fully compatible with general relativity. The observable cosmos, with �� ≈ 1090particles and cosmic age �� ≈ 4.35 × 10^17s, permits at most ∼10^151 interaction events at the Planck frequency ���� ≈ 1.85 × 10^43Hz. Full pairwise Newtonian gravity is combinatorially impossible if ���� imposes a limit, so gravitational influence aggregates into long, coherent wavefronts exhibiting cylindrical dilution ∼ 1/�� at large scales. Near localized masses these wavefronts undergo shear-induced breakup, recovering the Newtonian 1/��2 regime locally. In the weak-field, low-acceleration limit the model naturally recovers the deep-MOND relation �� ≈ √������0 without dark matter or auxiliary fields.
Category: Relativity and Cosmology
[10] ai.viXra.org:2604.0049 [pdf] submitted on 2026-04-11 06:07:26
Authors: Vladimir S. Netchitailo
Comments: 28 Pages.
The object formally designated C/2025 N1 (ATLAS) has been widely discussed as a candidate third interstellar object ("3I/ATLAS") due to its strongly hyperbolic trajectory. In standard celestial mechanics, an interstellar origin is inferred when the original barycentric eccentricity significantly exceeds unity prior to planetary perturbations. This interpretation, however, implicitly assumes that cometary dynamics are governed solely by gravitational forces and conventional outgassing.In this work, we propose an alternative hypothesis: C/2025 N1 (ATLAS) is not interstellar but a Solar System small body originating from the Oort Cloud, consistent with the framework of World—Universe Cosmology (WUC). We argue that its large excess velocity can be explained by a non-gravitational internal acceleration mechanism involving partial conversion of rotational energy of the nucleus into translational kinetic energy.Within WUC, the Universe is structured as a hierarchy of interaction regimes—Macro-world (gravity), Large-world (extremely-weak interaction), Small-world (super-weak interaction), and Micro-world (weak interaction). Previous studies associate Ball Lightning [1] with Solar System Small Body (SB1) and interpret the Tunguska superbolide [2] as an SB2 analogue. Extending this hierarchy, we identify C/2025 N1 (ATLAS) as an SB3 object. This model naturally accounts for its extreme hyperbolic excess velocity without invoking an interstellar origin and leads to specific, testable predictions regarding kinematics, activity, and radiation signatures.We compare these predictions with observations of ʻOumuamua, C/2019 Q4 (Borisov), and a growing population of low-albedo asteroids and "dark comets" exhibiting dust-poor outgassing.
Category: Relativity and Cosmology
[9] ai.viXra.org:2604.0045 [pdf] submitted on 2026-04-10 13:20:22
Authors: Russell S. Clark, Brian L. Swift
Comments: 16 Pages.
The Causal Topology Vacuum Model (CTVM) proposes that only bipartite (EPR-type) vacuum entanglement gravitates, while the irreducible multipartite (non-EPR) entanglement of the quantum vacuum is gravitationally inert. Previous formulations stated this sector-selection principle and its consequences as a system of six axioms (S1—S3, T1—T3). We show that all six axioms can be derived from standard ingredients of algebraic quantum field theory: the Wightman axioms, microcausality, the split property, the nuclearity condition, the Bisognano—Wichmann theorem, and the bit-thread (max-flow/min-cut) representation of holographic entanglement entropy. The derivation proceeds by constructing a canonical vacuum response matroid from the harvested correlation matrix of Unruh—DeWitt detectors coupled to the QFT vacuum. Microcausality forces a direct-sum decomposition of this matroid into gravitating and topological sectors. The split property identifies the gravitating sector with the image of a conditional expectation onto the intermediate type-I factor. The nuclearity condition guarantees area-scaling of the boundary rank and the existence of protected boundary generators. The Freedman—Headrick bit-thread theorem bridges matroid connectivity to Ryu—Takayanagi entanglement entropy, closing the final gap. No new physics beyond standard QFT is invoked. The CTVM is thereby established as a theorem of algebraic quantum field theory rather than a conjectural framework.
Category: Relativity and Cosmology
[8] ai.viXra.org:2604.0042 [pdf] submitted on 2026-04-10 13:17:26
Authors: Enno Matthiesen
Comments: 4 Pages. (Note by ai.viXra.org Admin: Please cite listed scientific references)
This paper presents a derivation of the Tully-Fisher relation based on a phase-dynamics-driven description of galactic rotation. Starting from a coupled amplitude-phase field structure, an effective dynamical relation between rotational velocity, density, and coupling properties is formulated. In a stationary regime, the dynamics can become dominated by phase evolution, leading to a characteristic scaling between velocity and enclosed mass. Under scale-invariant conditions, this framework yields a relation consistent with the observed proportionality v^4 ∝ M. The result suggests that the Tully-Fisher relation may emerge as a structural consequence of coherent dynamical organization, without requiring additional unseen components. The derivation is presented in a self-contained form and is compatible with a broader relational field framework.
Category: Relativity and Cosmology
[7] ai.viXra.org:2604.0039 [pdf] submitted on 2026-04-09 10:35:26
Authors: Alexander Unzicker
Comments: 13 Pages.
We apply a template-free cross-correlation method to publicly availablestrain data from the LIGO Hanford (H1) and Livingston (L1) detectors forseven strong gravitational wave (GW) events spanning observing runs O1 through~O4.The method, based on the Pearson cross-correlation coefficient between thetwo detector streams as a function of inter-detector time lag, requires noassumptions about waveform morphology.A time-slide background estimated from the same whitened, band-passed datasegment provides the statistical reference.Among all events studied, GW150914 stands out clearly with an empiricalsignificance of $sigma_mathrm{emp} = 9.1$ and $p = 0.001$($n_mathrm{bg} = 10{,}000$); it is furthermore the only event thatremains significant ($>5sigma$) across analysis windows of $pm 0.5$,$pm 1.0$, and $pm 2.0,mathrm{s}$.GW170814 is also detected ($sigma_mathrm{emp} = 4.2$, $p = 0.0005$)but its significance is window-dependent.The recovered inter-detector time lags are consistent with the officialLIGO values for all events.Events with long in-band chirp durations (GW170817: $approx!180,mathrm{s}$)are not detectable by this method, which explains the absence of significancein several high matched-filter SNR events.We discuss the implications for Virgo's role in GW170817 and argue thattemplate-free non-detections cannot contribute to sky localisation viatriangulation.
Category: Relativity and Cosmology
[6] ai.viXra.org:2604.0037 [pdf] submitted on 2026-04-09 20:06:39
Authors: Luiz Felipe Coutinho Martins Filho
Comments: 9 Pages. echnical companion ai.vixra:2604.0026.
Core Hypothesis. We propose that the invisibility of dark matter to all non-gravitational probes may result from structural incompatibility between gauge sectors, rather than weak coupling. We formalize a discrete transformation T — the force polarity inversion — acting on the gauge fiber bundle of an embedding group G, producing a derived sector (our Standard Model) whose gauge representations are orthogonal to the substrate’s. Gravity, being a property of the base manifold rather than the fiber bundle, is shown to be invariant under T.Scope and limitation. This paper is kinematic, not dynamical
Category: Relativity and Cosmology
[5] ai.viXra.org:2604.0014 [pdf] submitted on 2026-04-03 11:32:52
Authors: Andrew Ebanks
Comments: 3 Pages.
The fine structure constant α is a cornerstone of fundamental physics, yet persistent observational evidence from high-resolution quasar spectroscopy suggests it may vary across cosmological scales.We provide a zero-parameter, purely geometric derivation of this variance within the Fibonacci Tetrahedral Lattice (FTL) framework. By modeling the vacuum as a discrete, aperiodic tilingof regular tetrahedra derived from an E8 → R3 projection, we demonstrate that the observed≈ 10 ppm shift in α emerges as a necessary mechanical consequence of structural phase transitions between discrete "Fibonacci Gates." Furthermore, we show that the same structural frustration that generates α variance also drives the **Hubble Expansion Ratio** (κexp = 1.0905) between gate transitions, providing a unified resolution to both the α-dipole and the Hubble Tension (67.4 × 1.0905 ≈ 73.5 km/s/Mpc). This result transforms a series of observational "anomalies" into the primary experimental proofs for a discrete, frustrated vacuum.
Category: Relativity and Cosmology
[4] ai.viXra.org:2604.0006 [pdf] submitted on 2026-04-02 20:35:34
Authors: Geza Kovacs
Comments: 16 Pages.
We present Imprint-Fading (IF) theory, a one-field dissipative model for galactic dynamics in which spacetime accumulates a curvature-memory variable Σ from baryonic sources and loses it by fading at the Hubble rate. The dimensionless evolution equationṡ = Hu2080 [ y − s²/(1 − s) ],where s ≡ Σ/au2080 and y ≡ g_N/au2080, is simultaneously a gradient flow on the grand-canonical free energy of a lattice gas with hard-core exclusion and mean-field pair interactions, and the Onsager equation for entropy production in a driven dissipative system. In steady state it yields the MOND simple interpolation function ν(y) = [1 + √(1 + 4/y)] / 2 exactly and without free parameters.Global asymptotic stability is proved by a Lyapunov functional. The relaxation spectrum predicts timescales from 204 Gyr (ultra-faint dwarfs) to 0.09 Gyr (Newtonian regime), providing a dynamical clock absent from all prior MOND formulations. Non-equilibrium solutions predict hyperbolic halo decay after baryon stripping, with a sharp bifurcation at su2080 = ln 2: stripped massive galaxies lose half their effective halo in 6—7 Gyr, while stripped MOND-regime dwarfs retain theirs for 10²—10³ Gyr.The SPARC radial-acceleration relation is recovered exactly (by algebraic construction) once au2080 = cHu2080/(2π) is fixed from the local Hubble rate. Eight falsifiable dynamical predictions are stated; seven target galactic observations (JWST, Gaia DR4, WEAVE, Hector IFU), and one is a conditional cosmological conjecture contingent on the covariant sector.A proposed covariant extension (§10) derives c_gw = c exactly and no-ghost from the kinetic structure, with candidate results w ≥ −1 and γ_PPN = 1 + O(au2080/g_N) contingent on the proposed action; CMB invariance and phantom exclusion are stated as conjectures requiring full perturbation-theory derivation.
Category: Relativity and Cosmology
[3] ai.viXra.org:2604.0003 [pdf] replaced on 2026-04-04 18:45:45
Authors: Rüdiger Giesel
Comments: 7 Pages. (Note by ai.viXra.org Admin: Please cite listed scientific references)
We formulate an observationally testable phenomenological framework for a cosmological model motivated by octonionic pre-geometry. In this picture, the nonassociativity of the octonionic division algebra obstructs the existence of a fundamental global time and motivates a symmetry reduction to an effectively associative sector, identified with emergent four-dimensional spacetime. Residualnonassociative degrees of freedom are modeled as an effective dynamical dark-energy component. Weintroduce a minimal approach for the effective octonionic energy density and derive the associated Hubble function, luminosity distance, baryon-acoustic-oscillation distances, and effective equation of state. The resulting model admits a direct mapping onto the standard (w0,wa) dark-energy parametrization and reduces continuously to ΛCDM in the appropriate limit. We present a concrete benchmark parameterization and formulate a step-by-step likelihood strategy based on Type Ia supernovae, baryon acoustic oscillations, and direct H(z) measurements. The framework is designed as a falsifiable intermediate step between a speculative algebraic origin of spacetime and precisionlate-universe cosmology.
Category: Relativity and Cosmology
[2] ai.viXra.org:2604.0002 [pdf] submitted on 2026-04-01 01:57:04
Authors: Aleksey Razumovsky
Comments: 12 Pages. (Note by ai.viXra.org Admin: Please don't name title, equation/formula etc after the author's name; please cite listed scientific references)
Recent DESI DR1 and DR2 data indicate mild time evolution in the dark-energy equation of state, while persistent discrepancies between early- and late-universe probes continue to manifest as the Hubble tension (∆H0 ≈5−6 km/s/Mpc,∼4−5σ) and the S8 tension (∼2−3σ). We demonstrate that both tensions are naturally resolved within [a new]Framework by a single, minimal extension: a brief, entropy-driven early dark energy (EDE) phase triggered by Twin-Law charge buildup before recombination, followed by the late- time charge-discharge mechanism already derived in our prior work. The early EDE phase arises automatically when the Hubble friction term 3H|˙ϕ|drops below the fixed potential tilt ϵ, a crossover that occurs at the cosmologically natural temperature T ≈0.95 eV (z ≈ 3500) set entirely by the benchmark parameters of the scalar potential. A transient energy release fEDE ≈0.13−0.15 raises the CMB-inferredH0 from 67.4 to∼72.8 km/s/Mpc, while the subsequent late-time charge-discharge produces the mild phantom-like w(z) evolution pre-ferred by DESI. Full CLASS/CAMB Markov-chain Monte-Carlo fits to the combined Planck+ACT+DESI DR2+BAO+Pantheon++KiDS/HSC 1 dataset reduce the Hubble tension to < 2σ and the S8 tension to<1.5σ with only the original model parameters.The mechanism preserves all prior predictions, including a distinctive stochastic ravitational-wave background with a softened infrared tail and secondary mHz hump inside the LISA core band, as well as a specific w(z) wiggle observable in forthcoming DESI DR3/DR4 re-leases. The framework remains fully consistent with the Twin Laws of energy and information conservation and requires no fine-tuningbeyond the parameters already fixed in our earlier work. We discuss falsifiability and the string-theory UV completion via Bento—Monteroflux compactifications.
Category: Relativity and Cosmology
[1] ai.viXra.org:2604.0001 [pdf] submitted on 2026-04-01 01:59:56
Authors: Aleksey Razumovsky
Comments: 6 Pages. (Note by ai.viXra.org Admin: Please don't name title, equation/formula etc after the author's name; please cite listed scientific references)
The [proposed new] Framework unifies two foundational conservation principles—the Twin Laws—with the Information-Driven Expansion (IDE) model, a holographic framework in which dark energy emerges as the energetic consequence of the universe’s irreversible pro-duction and holographic storage of quantum information. The Twin Laws enforce strict boundary conditions on fundamental energy and quantum information within any existing universe, while IDE converts the allowed macroscopic entropy growth into a source of dark energy. Drawing from the holographic principle, black-hole thermodynamics, information theory, and string theory, the framework resolves the origin-of-initial-conditions problem and the coincidence problem without fine-tuning. It predicts an evolving equation of state consistent with recent DESI observations and offers a quantum-gravity-compatible mecha-nism for cosmic acceleration. We derive the key equations, discuss testable predictions, and outline challenges and future directions.
Category: Relativity and Cosmology