Cosmic electromagnetic fields due to perturbations in the gravitational field

Mongwane, Bishop; Dunsby, Peter K. S.; Osano, Bob

doi:10.1103/physrevd.86.083533

Cited by 7 publications

(17 citation statements)

References 67 publications

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“…Examples include mechanisms based on gravitational wave interactions [2][3][4], and velocity perturbations in the cosmological plasma [4]. Although some of the mechanisms for amplifying the seed fields have been suggested to be too weak [5][6][7], the prospect of a mechanism based on the dynamics of a self-gravitating plasma and classical general relativity is still enticing, since it would not explicitly depend on any additional exotic physics. Therefore, it is still of great interest to study the interactions between a cosmological plasma and general relativistic effects.…”

Section: Introductionmentioning

confidence: 99%

“…The studies of self-gravitating plasmas in a cosmological scenario seem to have mainly used a perturbative approach with the FLRW spacetimes as zeroth order backgrounds [2][3][4][5][6][7][8]. However, due to the isotropy of the FLRW spacetimes, it is essentially impossible to have a non-zero magnetic field 3-vector on the background, since that field would otherwise define a preferred spatial direction.…”

Section: Introductionmentioning

confidence: 99%

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On the Interaction Between Electromagnetic, Gravitational, and Plasma Related Perturbations on LRS Class II Spacetimes

Semrén

2022

Preprint

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We investigate electromagnetic, gravitational, and plasma related perturbations to first order on homogeneous and hypersurface orthogonal locally rotationally symmetric (LRS) class II spacetimes. Due to the anisotropic nature of the studied backgrounds, we are able to include a non-zero magnetic field to zeroth order. As a result of this inclusion, we find interesting interactions between the electromagnetic and gravitational variables already to first order in the perturbations. The equations governing these perturbations are found by using the Ricci identities, the Bianchi identities, Einstein's field equations, Maxwell's equations, particle conservation, and a form of energy-momentum conservation for the plasma components. Using a 1 + 1 + 2 covariant split of spacetime, the studied quantities and equations are decomposed with respect to the preferred directions on the background spacetimes. After linearizing the decomposed equations around a LRS background, performing a harmonic decomposition, and imposing the cold magnetohydrodynamic (MHD) limit with a finite electrical resistivity, the system is then reduced to a set of ordinary differential equations in time and some constraints. On solving for some of the harmonic coefficients in terms of the others, the system is found to decouple into two closed and independent subsectors. Through numerical calculations, we then observe some mechanisms for generating magnetic field perturbations, showing some traits similar to previous works using FLRW backgrounds. Furthermore, beat-like patterns are observed in the short wave length limit due to interference between gravitational waves and plasmonic modes.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

On the Interaction Between Electromagnetic, Gravitational, and Plasma Related Perturbations on LRS Class II Spacetimes

Semrén

2022

Preprint

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“…In this paper we examine cosmological magnetic fields generated during inflation. It is noteworthy that gravitational waves are also generated during inflation [8] as a counterpart. The energy transfer between the two is of interest and has been studied in [9].…”

Section: Introductionmentioning

confidence: 99%

Post inflationary evolution of inflation-produced, large-scale magnetic fields using a generalised cosmological Ohm's law and both standard and modified Maxwell's equations

Oreta,

Osano

2019

Preprint

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In most of the literature on evolution of cosmological magnetic fields, it is found that large-scale magnetic fields evolve as B 2 ∝ a −4 (adiabatic magnetic decay) where a is the cosmological scale factor and B is the cosmological magnetic field. This rapid decay has been considered as the main obstacle against magnetic fields produced during the inflationary epoch from surviving until today and seeding the observed fields. However, recent reports of first ever detection of intergalactic fields, with strengths around 10 −6 G are a mystery [1][2][3][4]. One possible explanation is that largescale magnetic fields could have been superadiabatically amplified in their evolutionary history. Superadiabatic amplification may mean that there is an actual increase in the strength of the magnetic field or that magnetic decay-rates are slower than the standard adiabatic magnetic decay rate [5] . This can be demonstrated if we use the generalised cosmological Ohm's law and both standard and modified Maxwell field equations; this is the goal of this study.

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“…It is thought that original magnetic fields, or seed fields as they are commonly called, may have their origin in phase transition in the early universe [2,3], or in the cosmological structure formation [4], or in the first stars and black holes [5], or in the first supernova [6], or even as a result of fluctuations in the gravitational field [7]. The authors of [8] gave an argument that places severe constraints on magneto-genesis theories of the early universe.…”

Section: Introductionmentioning

confidence: 99%

Dynamo Theory, Nonlinear Magnetic Fields, and the Euler Potentials

Osano

2018

Advances in Astronomy

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The debate on the role of Euler potentials (EP), α∇β, in the dynamo theory is a long-standing one. It is known that the cross-product of gradients of two the potentials may represent magnetic fields lines. However, 2D and 3D dynamo hydromagnetic simulations suggest that their utility as analogues of magnetic field potential is restricted. This raises questions about their utility in the broader context of magneto-genesis and dynamo theories. We reexamine this and find that a reinterpretation of such potentials offers a new insight into the role EP may play in the general evolution of magnetic fields.

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Cosmic electromagnetic fields due to perturbations in the gravitational field

Cited by 7 publications

References 67 publications

On the Interaction Between Electromagnetic, Gravitational, and Plasma Related Perturbations on LRS Class II Spacetimes

On the Interaction Between Electromagnetic, Gravitational, and Plasma Related Perturbations on LRS Class II Spacetimes

Post inflationary evolution of inflation-produced, large-scale magnetic fields using a generalised cosmological Ohm's law and both standard and modified Maxwell's equations

Dynamo Theory, Nonlinear Magnetic Fields, and the Euler Potentials

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