Boleslav Plhák

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Papers by Boleslav Plhák

Quantum Compression Theory A Unified Framework for Fundamental Interactions, Geometry, and Dark Phenomena

Quantum Compression Theory (Peer Review), 2025

Quantum Compression Theory (QCT) proposes that fundamental interactions and cosmological phenomen... more Quantum Compression Theory (QCT) proposes that fundamental interactions and cosmological phenomena emerge from a single scalar field of entanglement density, ρent, physically identified with the cosmic neutrino background. We introduce the Heavy Hadron Era (HHE), an epoch at T ≳ 1 GeV where temporarily stabilized ∆-baryons provided the initial conditions for structure formation. The cosmic energy budget of this era 4.76 × 10 69 J from ∆-decays) is shown to be the source of the baryon asymmetry. For this mechanism to be consistent with the observed baryon-to-dark matter ratio Ω b /Ω dm ≈ 0.19, the QCT framework **predicts** a new physics energy scale of Λ ≈ 145 TeV. Furthermore, we demonstrate that this framework naturally yields the scale of the weak interaction, with the Fermi constant GF emerging as a direct consequence of the theory's fundamental parameters and the predicted new physics scale Λ. Additionally, we demonstrate that QCT's topological framework naturally derives three fundamental constants: (i) the fine structure constant E M throughelectromagneticf ieldtopology(nT = 3), predictingitisdef inedinultra-lowdensityvacuumenvironmentswithent0.36eV ; (ii) the cosmological constant through dynamic vacuum suppression, resolving the vacuum catastrophe by naturally generating extremely 'quiet' fluctuations E f luct 10-16 GeV ; and (iii) the lepton mass hierarchy through exponential topological scaling, reducing the /e mass ratio to a single parameter topo2.67, consistentwithotherQCT topologicalprocesses.T hisprediction, derivedf romadimension-9operatorintheQCT Lagrangian, determinesthenecessaryamplif icationf actorAQCT ≈ 3.12 × 10 11 without fine-tuning. The theory provides a unified explanation for dark matter as topological domains of the slabofon field Ψνν , resolves the Hubble tension via local ρent variations, and explains the AMS-02 positron excess as a fossil record of primordial anti-baryon decays. Testable signatures include specific CMB anisotropies, β-decay variations, and a concrete energy target for future colliders.

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Quantum Compression Theory Applications: Y-C-H Superconductors and Triboelectric Materials

Grand Unification of Space, Matter and fundamental interactions for new unitarity predictions with interdisciplinary implications - (QCT), 2025

We present a comprehensive theoretical framework for applying Quantum Compression Theory (QCT) to... more We present a comprehensive theoretical framework for applying Quantum Compression Theory
(QCT) to condensed matter systems, with specific focus on high-temperature superconductivity in
Y-C-H compounds and triboelectric phenomena. Starting from the fundamental QCT Lagrangian,
we derive effective field theories for electrons in materials with significant quantum entanglement
density (ρent) gradients. We demonstrate that ρent modifies electron-phonon coupling through a
novel mechanism involving topological defects, leading to enhanced Cooper pair formation in spe-
cific Y-C-H stoichiometries. Our microscopic model, combining QCT with modified Eliashberg
theory, predicts critical temperatures up to Tc ≈ 290 ± 15 K for optimized Y0.95Cr0.05H9C0.2 com-
pounds at ambient pressure—a prediction amenable to experimental verification. For triboelectric
materials, we derive from first principles how ρent gradients generate additional charge transfer
mechanisms beyond conventional electrostatic effects, explaining anomalous triboelectric series vio-
lations observed in certain materials. We present detailed numerical simulations of both phenomena,
including ab initio calculations incorporating QCT effects, and propose specific experimental tests
involving neutron scattering, tunneling spectroscopy, and specialized triboelectric measurements.
Our results establish QCT as a powerful theoretical framework for understanding and engineering
novel quantum materials with unprecedented properties.

Quantum Compression Theory Applications: Y-C-H Superconductors and Triboelectric Materials

We present a comprehensive theoretical framework for applying Quantum Compression Theory (QCT) to... more We present a comprehensive theoretical framework for applying Quantum Compression Theory (QCT) to condensed matter systems, with specific focus on high-temperature superconductivity in Y-C-H compounds and triboelectric phenomena. Starting from the fundamental QCT Lagrangian, we derive effective field theories for electrons in materials with significant quantum entanglement density (ρent) gradients. We demonstrate that ρent modifies electron-phonon coupling through a novel mechanism involving topological defects, leading to enhanced Cooper pair formation in specific Y-C-H stoichiometries. Our microscopic model, combining QCT with modified Eliashberg theory, predicts critical temperatures up to Tc ≈ 290 ± 15 K for optimized Y0.95Cr0.05H9C0.2 compounds at ambient pressure-a prediction amenable to experimental verification. For triboelectric materials, we derive from first principles how ρent gradients generate additional charge transfer mechanisms beyond conventional electrostatic effects, explaining anomalous triboelectric series violations observed in certain materials. We present detailed numerical simulations of both phenomena, including ab initio calculations incorporating QCT effects, and propose specific experimental tests involving neutron scattering, tunneling spectroscopy, and specialized triboelectric measurements. Our results establish QCT as a powerful theoretical framework for understanding and engineering novel quantum materials with unprecedented properties.

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Quantum Compression Theory Applications: Y-C-H Superconductors and Triboelectric Materials

We present a comprehensive theoretical framework for applying Quantum Compression Theory (QCT) to... more We present a comprehensive theoretical framework for applying Quantum Compression Theory (QCT) to condensed matter systems, with specific focus on high-temperature superconductivity in Y-C-H compounds and triboelectric phenomena. Starting from the fundamental QCT Lagrangian, we derive effective field theories for electrons in materials with significant quantum entanglement density (ρent) gradients. We demonstrate that ρent modifies electron-phonon coupling through a novel mechanism involving topological defects, leading to enhanced Cooper pair formation in specific Y-C-H stoichiometries. Our microscopic model, combining QCT with modified Eliashberg theory, predicts critical temperatures up to Tc ≈ 290 ± 15 K for optimized Y0.95Cr0.05H9C0.2 compounds at ambient pressure-a prediction amenable to experimental verification. For triboelectric materials, we derive from first principles how ρent gradients generate additional charge transfer mechanisms beyond conventional electrostatic effects, explaining anomalous triboelectric series violations observed in certain materials. We present detailed numerical simulations of both phenomena, including ab initio calculations incorporating QCT effects, and propose specific experimental tests involving neutron scattering, tunneling spectroscopy, and specialized triboelectric measurements. Our results establish QCT as a powerful theoretical framework for understanding and engineering novel quantum materials with unprecedented properties.

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Quantum Compression Theory -Effective Field Formalism and Phenomenology

We present a consistent and testable formulation of Quantum Compression Theory (QCT) as an effect... more We present a consistent and testable formulation of Quantum Compression Theory (QCT) as an effective quantum field theory, in which the entanglement density ρ ent (x, t) is promoted to a dynamical scalar field. In this framework, gravity emerges as a collective response of the spacetime geometry to quantum entanglement, with ρ ent acting as a source of curvature and modulating the local gravitational coupling. We derive the QCT action, field equations, and modified Einstein equations with a position-dependent Newton constant G eff (x) = G 0 /(1 + κρ ent ). The dynamics of ρ ent include non-linear self-interactions, neutrino-lepton sources, and decoherence effects. A coupling between ρ ent and baryonic matter is introduced via a bilinear term ρ ent ρ had . Interpretation of mass. In the Quantum Compression framework, spacetime is an emergent structure composed of a network of entangled and decohered neutrinos. This substrate, while rich in quantum correlations, sits atop a more fundamental ontological background -a pre-quantum void, devoid of any information or structure. The inertial mass of particles does not arise from local fields such as the Higgs condensate, but from the resistance of the substrate to deformations that extend toward this informational void. The heavier the particle, the deeper it deforms the entangled neutrino fabric, and the more tightly the substrate must "hold" it against the pull of the underlying nothingness. Thus, mass is interpreted as a measure of how much the entangled vacuum must be compressed to prevent collapse into non-being. Using a topological quantisation scheme on compact Kähler manifolds, we show that particle masses arise from discrete compression modes n T and associated Berry phases. This leads to exponential mass hierarchies and predicts mass ratios consistent with the Standard Model. We demonstrate that QCT naturally accounts for several phenomena without invoking dark matter or a cosmological constant, including flat galactic rotation curves, cosmic acceleration, and CP violation. Quantisation is performed in the BRST formalism, and the theory exhibits ultraviolet finiteness due to a modified propagator structure. We compare QCT predictions with current cosmological and particle data (Planck, DESI, NOvA), and propose falsifiable experimental tests using DESI, LSST, Hyper-Kamiokande, IceCube, and LIGO/Virgo. Finally, we reinterpret Hawking radiation as a consequence of extremely slow decoherence of entangled neutrino-lepton states inside black holes. This mechanism eliminates the need for trans-Planckian modes or horizon pair creation, providing a physically consistent and information-preserving model of black hole evaporation within QCT. Using a topological quantisation scheme on compact Kähler manifolds, we show that particle masses arise from discrete compression modes n T and associated Berry phases. This leads to exponential mass hierarchies and predicts mass ratios consistent with the Standard Model. We demonstrate that QCT naturally accounts for several phenomena without invoking dark matter or a cosmological constant, including flat galactic rotation curves, cosmic acceleration, and CP violation. Quantisation is performed in the BRST formalism, and the theory exhibits ultraviolet finiteness due to a modified propagator structure. We compare QCT predictions with current cosmological and particle data (Planck, DESI, NOvA), and propose falsifiable experimental tests using DESI, LSST, Hyper-Kamiokande, IceCube, and LIGO/Virgo.

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Quantum Compression Theory -Effective Field Formalism and Phenomenology

We present a consistent and testable formulation of Quantum Compression Theory (QCT) as an effect... more We present a consistent and testable formulation of Quantum Compression Theory (QCT) as an effective quantum field theory, in which the entanglement density ρ ent (x, t) is promoted to a dynamical scalar field. In this framework, gravity emerges as a collective response of the spacetime geometry to quantum entanglement, with ρ ent acting as a source of curvature and modulating the local gravitational coupling. We derive the QCT action, field equations, and modified Einstein equations with a position-dependent Newton constant G eff (x) = G 0 /(1 + κρ ent ). The dynamics of ρ ent include non-linear self-interactions, neutrino-lepton sources, and decoherence effects. A coupling between ρ ent and baryonic matter is introduced via a bilinear term ρ ent ρ had . Interpretation of mass. In the Quantum Compression framework, spacetime is an emergent structure composed of a network of entangled and decohered neutrinos. This substrate, while rich in quantum correlations, sits atop a more fundamental ontological background -a pre-quantum void, devoid of any information or structure. The inertial mass of particles does not arise from local fields such as the Higgs condensate, but from the resistance of the substrate to deformations that extend toward this informational void. The heavier the particle, the deeper it deforms the entangled neutrino fabric, and the more tightly the substrate must "hold" it against the pull of the underlying nothingness. Thus, mass is interpreted as a measure of how much the entangled vacuum must be compressed to prevent collapse into non-being. Using a topological quantisation scheme on compact Kähler manifolds, we show that particle masses arise from discrete compression modes n T and associated Berry phases. This leads to exponential mass hierarchies and predicts mass ratios consistent with the Standard Model. We demonstrate that QCT naturally accounts for several phenomena without invoking dark matter or a cosmological constant, including flat galactic rotation curves, cosmic acceleration, and CP violation. Quantisation is performed in the BRST formalism, and the theory exhibits ultraviolet finiteness due to a modified propagator structure. We compare QCT predictions with current cosmological and particle data (Planck, DESI, NOvA), and propose falsifiable experimental tests using DESI, LSST, Hyper-Kamiokande, IceCube, and LIGO/Virgo. Finally, we reinterpret Hawking radiation as a consequence of extremely slow decoherence of entangled neutrino-lepton states inside black holes. This mechanism eliminates the need for trans-Planckian modes or horizon pair creation, providing a physically consistent and information-preserving model of black hole evaporation within QCT.z Using a topological quantisation scheme on compact Kähler manifolds, we show that particle masses arise from discrete compression modes n T and associated Berry phases. This leads to exponential mass hierarchies and predicts mass ratios consistent with the Standard Model. We demonstrate that QCT naturally accounts for several phenomena without invoking dark matter or a cosmological constant, including flat galactic rotation curves, cosmic acceleration, and CP violation. Quantisation is performed in the BRST formalism, and the theory exhibits ultraviolet finiteness due to a modified propagator structure. We compare QCT predictions with current cosmological and particle data (Planck, DESI, NOvA), and propose falsifiable experimental tests using DESI, LSST, Hyper-Kamiokande, IceCube, and LIGO/Virgo.

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QCT - Unifikační matematický rámec

QCT-Unifikační matematický rámec, 2025

Abstrakt Představuji Kvantovou Kompresní Teorii (QCT) jako kandidátní teorii kvantové gravitace z... more Abstrakt Představuji Kvantovou Kompresní Teorii (QCT) jako kandidátní teorii kvantové gravitace založenou na kvantových korelacích neutrinových polí. Teorie zavádí nový koncept entanglementové hustoty, která modifikuje gravitační interakce a přirozeně vede k UV konečnosti v kvantové gravitaci. V tomto článku systematicky buduji matematický aparát QCT, začínající geometrickou formulací na Kählerově varietě K3, přes důkazy UV konečnosti a unitarity, až po renormalizační grupovou analýzu, BRST kvantizaci a generalizaci na zakřivený pozadí. Ukazuji, že QCT poskytuje řešení několika fundamentálních problémů: počínaje nerenormalizovatelností kvantové gravitace přes nejasnosti kolem kosmologické konstanty až po gravitační singularity. Teorie předpovídá měřitelné efekty v částicové fyzice, včetně specifických korekcí poměru hmotností W/Z bosonů a vysvětlení neutrinových anomálií. V kosmologickém kontextu QCT nabízí dynamické vysvětlení temné energie s parametry ΩΛ = 7 13 α-3 ≈ 0.685 a Ωc = 5 13 α-2 ≈ 0.265, které jsou v pozoruhodné shodě s měřeními. Představuju také testovatelné předpovědi pro budoucí experimenty v částicové fyzice, gravitačně-vlnové astronomii a kosmologii.

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Teorie OCT

We present an expanded framework for Quantum Compression Theory (QCT) that integrates rigorous ge... more We present an expanded framework for Quantum Compression Theory (QCT) that integrates rigorous geometric quantization on Kähler manifolds with a novel quantum compression term to derive emergent gravitational dynamics from collective neutrino states. Methods: Our approach decomposes the spacetime metric into a standard Hermitian component and an additional compression term, characterized by the fine structure constant and a quantization number. Detailed analytical derivations and extensive numerical simulations support our framework. Results: The analysis confirms an exceptionally precise prediction for the W/Z boson mass ratio and forecasts the existence of new vector and tensor bosons at energy scales of approximately 792 GeV and 9.27 TeV. Radiative corrections, gravitational damping, and topological effects are rigorously incorporated. Conclusions: Overall, our comprehensive analysis establishes QCT as a promising unifying framework bridging quantum mechanics and gravity, with significant implications for cosmology, dark energy, dark matter, and the Standard Model mass hierarchy.

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Books by Boleslav Plhák

Quantum Compression Theory: A Unified Framework for Fundamental Interactions, Geometry, and Dark Phenomena

Quantum Compression Theory (QCT): A Unified Framework for Fundamental Interactions, Geometry, and Dark Phenomena , 2025

This work introduces Quantum Compression Theory (QCT), a novel theoretical framework proposing... more This work introduces Quantum Compression Theory (QCT), a novel theoretical framework proposing that all fundamental interactions, spacetime geometry, and cosmological phenomena emerge from the dynamics of a single scalar field of quantum entanglement density, (\rho_{\text{ent}}). QCT offers a unified physical mechanism for several unresolved anomalies in modern physics without postulating new fundamental particles.
Key findings and predictions include:

A Novel Origin for Dark Matter: The theory posits that the gravitational effects attributed to dark matter in the early universe were caused by a "Heavy Hadron Era," a phase of temporarily stabilized, known heavy baryons.

An Explanation for the Positron Anomaly: The observed excess of high-energy positrons in cosmic rays (AMS-02 anomaly) is interpreted as a direct observational echo from the decay of the Heavy Hadron Era.

A Mechanism for Particle Stability: The stability of matter is explained via the "Atomic Antenna" mechanism, a dynamic energy exchange with the vacuum that accounts for the measured isotope shift and links particle stability directly to the expansion of the cosmos.

A Finite Proton Lifetime: As a direct consequence of its stability model, QCT predicts a finite, calculable lifetime for the proton, dictated by the continued expansion of the universe.
The framework provides a physical resolution to the Hubble tension, derives particle properties like spin and mass from topological defects, and presents a suite of falsifiable, experimentally testable predictions, including specific signatures in the Cosmic Microwave Background (CMB) and variations in beta-decay rates.

This paper presents the complete mathematical formalism and cosmological implications of QCT as a candidate for a new paradigm in fundamental physics.

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