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Self-Consistent Quantum-Gravitational Quadrupole Fluctuations

Binder, Bernd (2003) Self-Consistent Quantum-Gravitational Quadrupole Fluctuations. [Preprint]

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    Abstract

    To establish a self-consistent system of mutually interacting gravitational quadrupoles, a characteristic number N of quantum masses µ are related to a characteristic velocity scaling. For this purpose a critical reference is defined by the flux and flux number of mass quanta constituting a confining unit field generating mass m_{G}=Nµ. In the field of m_{G} any small test mass orbits at unit distance r_{u} with unit velocity u (human artificial units). The velocity limit c with angular momentum quantum h is assigned to the Schwarzschild black hole photon sphere with radius given by the Compton wavelength. For this quantum mass we find the constitutional scaling relation N \approx 3m_{G}/µ \propto (c/u)^5 which indicates a quadrupole exchange. The corresponding coupling strength can be exactly related to previous results confirming the quantum mass µ hidden in the action quantum related at the Planck scale to the gravitational coupling constant G by µ^4 G=1. The coupling deficits can be assigned to a duality of coupling and non-coupling fluxes with 4th power flux scaling. This fits very well to existing models assuming a non-gravitating vacuum energy to give a satisfactory answer to the cosmological constant problem.


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    Item Type: Preprint
    Keywords: Schwarzschild, Scaling, general relativity, non-gravitating, vacuum energy, cosmological, quantum, Gravity, Quadrupole, Fluctuations, Compton, Dirac, topological, fundamental, particle, spin, proton, electron, neutron, bosonization, modes, nonlinear, field equations, phase, berry, Gordon, sine-Gordon, Aharonov, Bohm, fine structure, iteration, iterative, exact
    Subjects: Specific Sciences > Physics > Cosmology
    Specific Sciences > Physics
    Specific Sciences > Physics > Relativity Theory
    Depositing User: Bernd Binder
    Date Deposited: 16 Mar 2003
    Last Modified: 07 Oct 2010 11:11
    Item ID: 1043
    URI: http://philsci-archive.pitt.edu/id/eprint/1043

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