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  1. On Vacuum Fluctuations and Particle Masses.M. D. Pollock - 2012 - Foundations of Physics 42 (10):1300-1328.
    The idea that the mass m of an elementary particle is explained in the semi-classical approximation by quantum-mechanical zero-point vacuum fluctuations has been applied previously to spin-1/2 fermions to yield a real and positive constant value for m, expressed through the spinorial connection Γ i in the curved-space Dirac equation for the wave function ψ due to Fock. This conjecture is extended here to bosonic particles of spin 0 and spin 1, starting from the basic assumption that all fundamental fields (...)
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  • A Velocity Field and Operator for Spinning Particles in (Nonrelativistic) Quantum Mechanics.Giovanni Salesi & Erasmo Recami - 1998 - Foundations of Physics 28 (5):763-773.
    Starting from the formal expressions of the hydrodynamical (or “local”) quantities employed in the applications of Clifford algebras to quantum mechanics, we introduce—in terms of the ordinary tensorial language—a new definition for the field of a generic quantity. By translating from Clifford into tensor algebra, we also propose a new (nonrelativistic) velocity operator for a spin- ${\frac{1}{2}}$ particle. This operator appears as the sum of the ordinary part p/m describing the mean motion (the motion of the center-of-mass), and of a (...)
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  • Zitterbewegung in Quantum Mechanics.David Hestenes - 2009 - Foundations of Physics 40 (1):1-54.
    The possibility that zitterbewegung opens a window to particle substructure in quantum mechanics is explored by constructing a particle model with structural features inherent in the Dirac equation. This paper develops a self-contained dynamical model of the electron as a lightlike particle with helical zitterbewegung and electromagnetic interactions. The model admits periodic solutions with quantized energy, and the correct magnetic moment is generated by charge circulation. It attributes to the electron an electric dipole moment rotating with ultrahigh frequency, and the (...)
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  • Contribution to Inertial Mass by Reaction of the Vacuum to Accelerated Motion.Alfonso Rueda & Bernhard Haisch - 1998 - Foundations of Physics 28 (7):1057-1108.
    We present an approach to understanding the origin of inertia involving the electromagnetic component of the quantum vacuum and propose this as a step toward an alternative to Mach's principle. Preliminary analysis of the momentum flux of the classical electromagnetic zero-point radiation impinging on accelerated objects as viewed by an inertial observer suggests that the resistance to acceleration attributed to inertia may be at least in part a force of opposition originating in the vacuum. This analysis avoids the ad hoc (...)
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  • Concepts of Mass in Contemporary Physics and Philosophy.Max Jammer - 2009 - Princeton University Press.
    The concept of mass is one of the most fundamental notions in physics, comparable in importance only to those of space and time. But in contrast to the latter, which are the subject of innumerable physical and philosophical studies, the concept of mass has been but rarely investigated. Here Max Jammer, a leading philosopher and historian of physics, provides a concise but comprehensive, coherent, and self-contained study of the concept of mass as it is defined, interpreted, and applied in contemporary (...)
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  • Time as a Geometric Concept Involving Angular Relations in Classical Mechanics and Quantum Mechanics.Juan Eduardo Reluz Machicote - 2010 - Foundations of Physics 40 (11):1744-1778.
    The goal of this paper is to introduce the notion of a four-dimensional time in classical mechanics and in quantum mechanics as a natural concept related with the angular momentum. The four-dimensional time is a consequence of the geometrical relation in the particle in a given plane defined by the angular momentum. A quaternion is the mathematical entity that gives the correct direction to the four-dimensional time.Taking into account the four-dimensional time as a vectorial quaternionic idea, we develop a set (...)
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  • Classical Origin of Quantum spin.K. Muralidhar - 2011 - Apeiron: Studies in Infinite Nature 18 (2):146.
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  • Space-time structure of weak and electromagnetic interactions.David Hestenes - 1982 - Foundations of Physics 12 (2):153-168.
    The generator of electromagnetic gauge transformations in the Dirac equation has a unique geometric interpretation and a unique extension to the generators of the gauge group SU(2) × U(1) for the Weinberg-Salam theory of weak and electromagnetic interactions. It follows that internal symmetries of the weak interactions can be interpreted as space-time symmetries of spinor fields in the Dirac algebra. The possibilities for interpreting strong interaction symmetries in a similar way are highly restricted.
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  • A Classical Explanation of Quantization.Gerhard Grössing, Johannes Mesa Pascasio & Herbert Schwabl - 2011 - Foundations of Physics 41 (9):1437-1453.
    In the context of our recently developed emergent quantum mechanics, and, in particular, based on an assumed sub-quantum thermodynamics, the necessity of energy quantization as originally postulated by Max Planck is explained by means of purely classical physics. Moreover, under the same premises, also the energy spectrum of the quantum mechanical harmonic oscillator is derived. Essentially, Planck’s constant h is shown to be indicative of a particle’s “zitterbewegung” and thus of a fundamental angular momentum. The latter is identified with quantum (...)
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