Dark Matter as a Result of Field Oscillations in the Modified Theory of Induced Gravity

Zaripov, Farkhat

doi:10.3390/sym12010041

Cited by 2 publications

(2 citation statements)

References 45 publications

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“…This result provides insight into the behavior of the gravitational potential in a system where the radial component of the vorticity is assumed to vary inversely with the distance from the center of the system. A similar result was obtained in the work of Farkhat Zaripov [25] in the context of dark matter models, where the gravitational potential's characteristics were explored within the framework of modified gravity theories. Zaripov's research, akin to this study, underscores the intricate relationship between field oscillations and gravitational effects, highlighting the adaptability and comprehensiveness of these theoretical frameworks within astrophysical settings.…”

Section: Intergalactic Gravitational Potentialsupporting

confidence: 78%

Extended Field Interactions in Poisson’s Equation Revision

Pinheiro

2024

Applied Sciences

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This investigation introduces a new variational approach to refining Poisson’s equation, enabling the inclusion of a broader spectrum of physical phenomena, particularly in the emerging fields of spintronics and the analysis of resonant structures. The innovative formulation extends the traditional capabilities of Poisson’s equation, offering a nonlocal extension to classical theories of gravitation and opening new directions for energy conversion and enhanced communication technologies. By introducing a novel geometric structure, ω˜, into the equation, a deeper understanding of electrostatic potentials is achieved, and the intricate dynamics of the gravitational potential in systems characterized by radial vorticity fluctuations are illuminated. Furthermore, the research elucidates the generation of longitudinal electromagnetic waves and resonant phenomena within dusty plasma media, thereby contributing to the methodological advances in the study of nonequilibrium systems. These theoretical advances have the potential to transform the understanding of complex physical systems and open up opportunities for significant technological achievements across a range of scientific sectors.

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Section: Intergalactic Gravitational Potentialsupporting

confidence: 78%

Extended Field Interactions in Poisson’s Equation Revision

Pinheiro

2024

Applied Sciences

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“…Concerning in particular the problems of the cosmological constant and the large-scale structure of the universe, a proper comparison among them can only be based on observations, i.e., the application of such theories to the description of observational data. The issue is important primarily for resolving existing questions in cosmology and astronomy, like for example the problems of dark matter and dark energy, for which conclusions and particular solutions applying to the DeSitter space-time might provide a relevant framework [12,13].…”

Section: Introductionmentioning

confidence: 99%

Quantum-Gravity Screening Effect of the Cosmological Constant in the DeSitter Space–Time

Cremaschini

Tessarotto

2020

Symmetry

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Small-amplitude quantum-gravity periodic perturbations of the metric tensor, occurring in sequences of phase-shifted oscillations, are investigated for vacuum conditions and in the context of the manifestly-covariant theory of quantum gravity. The theoretical background is provided by the Hamiltonian representation of the quantum hydrodynamic equations yielding, in turn, quantum modifications of the Einstein field equations. It is shown that in the case of the DeSitter space–time sequences of small-size periodic perturbations with prescribed frequency are actually permitted, each one with its characteristic initial phase. The same perturbations give rise to non-linear modifications of the Einstein field equations in terms of a suitable stochastic-averaged and divergence-free quantum stress-energy tensor. As a result, a quantum-driven screening effect arises which is shown to affect the magnitude of the cosmological constant. Observable features on the DeSitter space–time solution and on the graviton mass estimate are pointed out.

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Dark Matter as a Result of Field Oscillations in the Modified Theory of Induced Gravity

Cited by 2 publications

References 45 publications

Extended Field Interactions in Poisson’s Equation Revision

Extended Field Interactions in Poisson’s Equation Revision

Quantum-Gravity Screening Effect of the Cosmological Constant in the DeSitter Space–Time

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