Sort by
Wave-Packet Transport in Graphene Under Asymmetric Electrostatic Arrays: Geometry-Tunable Confinement
Khakimjan Butanov,
Maksudbek Baydjanov,
Hammid Yusupov,
Komiljon Bobojonov,
Maksudbek Yusupov,
Andrey Chaves,
Khamdam Rakhimov
Posted: 07 November 2025
Some Results on Cumulative Residual Inaccuracy Measure of k-Record Values
Ritu Goel,
Vikas Kumar,
Sarang Vehale,
Tony C. Scott
Posted: 07 November 2025
Thermodynamic Coherence and Virial Inversion in Black Hole Evolution
Jordan Barton
Posted: 07 November 2025
Animal Skin Attenuation in the Millimeter Wave Spectrum
Yarden Shay,
Alex Shteinman,
Moshe Einat,
Asher Yahalom,
Helena Tuchinsky,
Stella Danet
Posted: 07 November 2025
Temporal Convergence Framework: Distinguishing Structure from Coincidence in High-Precision, Low-Dimensionality Parameter Spaces
Andrew Michael Brilliant
Posted: 07 November 2025
Quantum Relativity (Electron Ripple)
Ahmed Mohamed Ismail,
Samira Ezzat Mohamed
Posted: 07 November 2025
Advantages of Non-Associative Sedenionic QED Without UV-Divergence and Renormalization: Predictions of Lepton Mass and Magnetic Moment Anomaly
Jau Tang
We propose a non-associative reformulation of quantum electrodynamics (QED) based on octonionic and sedenionic hypercomplex algebras, replacing the conventional associative Clifford algebra and Dirac gamma matrices. In this framework, the associator — a quantity that vanishes in standard QED — becomes physically active, inducing Yukawa-type screening and regulating self-energy divergences. This removes the need for renormalization and resolves the vacuum catastrophe. Lepton masses arise algebraically from associator norms without invoking the Higgs mechanism, yielding accurate predictions for the electron, muon, and tau masses. Likewise, anomalous magnetic moments (g-2)/2 for all three charged leptons emerge naturally from generation-dependent associator corrections, matching experimental values to high precision — including the muon anomaly — without perturbative loop corrections. The model introduces gauge fields valued in non-associative algebras and generalizes the field strength tensor to include commutators and associators. This results in a divergence-free, highly predictive quantum field theory with no adjustable parameters. Our results suggest that non-associativity provides a deeper algebraic foundation for quantum dynamics, encoding mass, anomaly, and vacuum structure in a unified formalism.
We propose a non-associative reformulation of quantum electrodynamics (QED) based on octonionic and sedenionic hypercomplex algebras, replacing the conventional associative Clifford algebra and Dirac gamma matrices. In this framework, the associator — a quantity that vanishes in standard QED — becomes physically active, inducing Yukawa-type screening and regulating self-energy divergences. This removes the need for renormalization and resolves the vacuum catastrophe. Lepton masses arise algebraically from associator norms without invoking the Higgs mechanism, yielding accurate predictions for the electron, muon, and tau masses. Likewise, anomalous magnetic moments (g-2)/2 for all three charged leptons emerge naturally from generation-dependent associator corrections, matching experimental values to high precision — including the muon anomaly — without perturbative loop corrections. The model introduces gauge fields valued in non-associative algebras and generalizes the field strength tensor to include commutators and associators. This results in a divergence-free, highly predictive quantum field theory with no adjustable parameters. Our results suggest that non-associativity provides a deeper algebraic foundation for quantum dynamics, encoding mass, anomaly, and vacuum structure in a unified formalism.
Posted: 07 November 2025
Quantum Reality from Micro-Causal Geometry: A Wavefunction-Free Resolution of Quantum Paradoxes
Jau Tang
Posted: 07 November 2025
Beyond Correlation: Redefining Causation Through Robustness and Resilience to Perturbation
Arturo Tozzi
Posted: 07 November 2025
Particle-in-Cell Simulations of Laser Crossbeam Energy Transfer via Magnetized Ion-AcousticWave
Yuan Shi,
John D. Moody
Posted: 07 November 2025
Quantum Gravity I—Emergent Hypercomplex Operator Gauge Theory for Microcausal Lattice Spacetime
Jau Tang
We propose a novel operator-based formulation of quantum gravity grounded in two foundational principles: a discrete causal lattice and algebraic microcausality. Departing from traditional continuum approaches and wavefunction-based quantum mechanics, this framework models spacetime and matter as emergent phenomena arising from the algebraic structure of displacement operators. In this first part of a two-part series, we construct the foundational framework and demonstrate how key features of quantum mechanics—such as the uncertainty principle, de Broglie relations, and entanglement—emerge naturally without invoking wavefunctions, path integrals, or metric-based geometry. Operator non-commutativity on the causal lattice gives rise to a self-consistent quantum structure with natural ultraviolet finiteness, intrinsic time directionality, and a microcausal interpretation of measurement. This foundational part lays the groundwork for gravitational dynamics, cosmology, and the grand unification principles of gravity and the Standard Model to be explored in the sequel to quantum gravity part II.
We propose a novel operator-based formulation of quantum gravity grounded in two foundational principles: a discrete causal lattice and algebraic microcausality. Departing from traditional continuum approaches and wavefunction-based quantum mechanics, this framework models spacetime and matter as emergent phenomena arising from the algebraic structure of displacement operators. In this first part of a two-part series, we construct the foundational framework and demonstrate how key features of quantum mechanics—such as the uncertainty principle, de Broglie relations, and entanglement—emerge naturally without invoking wavefunctions, path integrals, or metric-based geometry. Operator non-commutativity on the causal lattice gives rise to a self-consistent quantum structure with natural ultraviolet finiteness, intrinsic time directionality, and a microcausal interpretation of measurement. This foundational part lays the groundwork for gravitational dynamics, cosmology, and the grand unification principles of gravity and the Standard Model to be explored in the sequel to quantum gravity part II.
Posted: 06 November 2025
Fano Resonance Sensor with Ultra-High Spectral Resolution in a Metallic Waveguide
Er'el Granot
Posted: 06 November 2025
Photonic Vacuum Windows: A Casimir-Safe Operational Baseline
André J. H. Kamminga
Posted: 06 November 2025
The Problem of Coordination: Entropy as a Physical Quantity in Classical Thermodynamics
Evgenii Rudnyi
Posted: 06 November 2025
Resolution of the Hubble Tension by a Reversible Fractal Cosmology: The Ultimate Black Hole Framework
Juergen Schreiber
Posted: 06 November 2025
A Localized Axisymmetric Solution of the Hilbert-Einstein Equations for Spacetime Without Mass Sources
Elizabeth P. Tito,
Vadim I. Pavlov
Posted: 06 November 2025
Effect of Cholesterol and Ergosterol on the Electrical Response of Supported Lipid Bilayers: An Application of Kelvin Probe Force Microscopy
Arturo Galván-Hernández,
Omar Hernández-Villanueva,
Leonardo Ibor Ruiz-Ortega,
Iván Ortega-Blake
Posted: 06 November 2025
Generalized Maxwell Equations with Magnetic Monopole Sources in Differential-Form Representation
Bo Hua Sun
Posted: 06 November 2025
PSA-Responsive Aptamer-Based Switchable Aggregates of Ultrasmall Gold Nanoparticles
Giulia Matteoli,
Pasquale Mastella,
Elisa Ottalagana,
Riccardo Nifosì,
Luca Bellucci,
Fabio Beltram,
Giovanni Signore,
Stefano Luin
Posted: 05 November 2025
Field-Mediated Time: A Covariant Framework for Gauge-Invariant Temporal Modulation
James C Hateley
Posted: 05 November 2025
of 288