Abstract
In this work, with the help of the quantum hydrodynamic formalism, the gravitational equation associated with the classical Dirac field is derived. The hydrodynamic representation of the Dirac equation described by the evolution of four mass densities, subject to the theory-defined quantum potential, has been generalized to the curved space-time in the covariant form. Thence, the metric of space-time has been defined by imposing the minimum action principle. The derived gravity shows the spontaneous emergence of the “cosmological” gravity tensor (CGT), a generalization of the classical cosmological constant (CC), as a part of the energy-impulse tensor density (EITD). Even if the classical cosmological constant is set to zero, the CGT is non-zero, allowing a stable quantum vacuum (out of the collapsed branched polymer phase). The theory shows that in the classical macroscopic limit, the general relativity equation is recovered. In the perturbative approach, the CGT leads to a second-order correction to Newtonian gravity that takes contribution from the space where the mass is localized (and the space-time is curvilinear), while it tends to zero as the space-time approaches the flat vacuum, leading, as a means, to an overall cosmological constant that may possibly be compatible with the astronomical observations. The Dirac field gravity shows analogies with the modified Brans–Dicke gravity, where each spinor term brings an effective gravity constant G divided by its field squared. The work shows that in order to obtain the classical minimum action principle and the general relativity limit of the macroscopic classical scale, quantum decoherence is necessary.
Highlights
One of the physics problems nowadays is to describe how the quantum mechanical properties of space-time (ST) and the second quantization affect gravity.Even if general relativity (GR) has opened up some understanding about cosmological dynamics [1,2,3,4,5,6], the complete explanation of the generation of matter and its distribution in the universe need the integration of cosmological physics with quantum physics
The great difficulty of the quantum field theory (QFT) to give a correct value to the cosmological constant (CC) relies on the fact that the energy-impulse tensor density (EITD) in the Einstein equation [12] owns a point-dependence by mass density, but does not have any analytical connection to the fields of matter described by the Dirac or Klein-Gordon equation (KGE)
The gravity equation associated to the Dirac-Fock-Weyl equation (DFWE) field takes into account the gravitational effects of the energy of the nonlocal quantum potential
Summary
One of the physics problems nowadays is to describe how the quantum mechanical properties of space-time (ST) and the second quantization affect gravity. This procedure allows us to include the QP energy in the definition of space-time curvature. The Dirac field gravity and the cosmological constant in pure quantum gravity; Analogies with the Brans-Dicke model; Quantum mechanical gravity and the foundations of quantum mechanics; Possible experimental tests
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