Cosmic strings in $$f\left( R,L_m\right) $$ f R , L m gravity

Harkó, Tiberiu; Lake, Matthew J.

doi:10.1140/epjc/s10052-015-3287-y

Cited by 42 publications

(35 citation statements)

References 149 publications

(170 reference statements)

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“…Houndjo [53] reconstructed f (R, T ) gravity by taking f (R, T ) = f 1 (R) + f 2 (T ) and it was shown that f (R, T ) gravity allowed for a transition of matter from a dominated phase to an acceleration phase. Harko and Lake [54] investigated cylindrically symmetric interior string like solutions in f (R, L m ) theory of gravity. In a recent paper [55], we explored the exact solutions of a cylindrically symmetric spacetime in f (R, T ) gravity and recovered two solutions, which corresponded to an exterior metric of cosmic string and a non-null electromagnetic field.…”

Section: Introductionmentioning

confidence: 99%

Locally rotationally symmetric Bianchi type I cosmology in f(R, T) gravity

Shamir

2015

Eur. Phys. J. C

166

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This manuscript is devoted to the investigation of the Bianchi type I universe in the context of f (R, T ) gravity. For this purpose, we explore the exact solutions of locally rotationally symmetric Bianchi type I spacetime. The modified field equations are solved by assuming an expansion scalar θ proportional to the shear scalar σ , which gives A = B n , where A, B are the metric coefficients and n is an arbitrary constant. In particular, three solutions have been found and physical quantities are calculated in each case.

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Section: Introductionmentioning

confidence: 99%

Locally rotationally symmetric Bianchi type I cosmology in f(R, T) gravity

Shamir

2015

Eur. Phys. J. C

166

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“…It also becomes important when some types of the topological effects are needed suddenly by assigning an independent metric. In the context of modified theories of gravity, cosmic strings are investigated in f (R) gravity [58,60], teleparallel theories [61][62][63], brane worlds [64], Kaluza-Klein models [65], Lovelock Lagrangians [66], Gauss-Bonnet [67][68][69], Born-Infeld [70,71], bimetric theories [72], non-relativistic models of gravity [73], scalar-tensor theories [74][75][76][77][78][79], Brans-Dicke theory [80][81][82][83][84][85], dilation gravity [86,87], non-minimally coupled models of gravity [88], Mimetic gravity [89] and, recently, in the Bose-Einstein condensate strings [90]. However, the cosmic string is still unexplored in gravity's rainbow setting.…”

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confidence: 99%

Cosmic string in gravity’s rainbow

Momeni

Upadhyay

Myrzakulov

et al. 2017

Astrophys Space Sci

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In this paper, we study the various cylindrical solutions (cosmic strings) in gravity's rainbow scenario. In particular, we calculate the gravitational field equations corresponding to energy-dependent background. Further, we discuss the possible Kasner, quasi-Kasner and non-Kasner exact solutions of the field equations. In this framework, we find that quasiKasner solutions can not be realized in gravity's rainbow. Assuming only time-dependent metric functions, we also analyse the time-dependent vacuum cosmic strings in gravity's rainbow, which are completely different than the other GR solutions. I. OVERVIEW AND MOTIVATIONA strong notion of an observer independent minimum length scale has been found in all theories of quantum gravity, for instance, in string theory [1], noncommutative geometry [2], loop quantum gravity [3,4] and Lorentzian dynamical triangulations [5][6][7][8]. Here we point out that the nascent GW astronomy [9] could help in discriminating among general relativity or alternative theories [10]. There is no harm to assume this minimum measurable length scale as the Planck scale. The mathematical ground of general theory of relativity is based on a smooth manifold which breaks down when energies of probe reaches the order of Planck energy [11,12].Keeping this point in mind, one may expect a radically new picture of spacetime, which includes departure from the standard relativistic dispersion relation. A departure from the standard dispersion relation indicates that the system incorporates a breaking of Lorentz invariance. * Electronic address:

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“…Hence, in order to determine the asymptotic form of the metric, the solutions presented in this paper must be matched onto the exterior cylindrically symmetric vacuum metric. In the case of cylindrical symmetry, and by assuming that the exterior gravitational field is described by standard general relativity, this metric is the Kasner metric [49][50][51][52]61,62],…”

Section: Discussion and Final Remarksmentioning

confidence: 99%

Bose-Einstein condensate strings

Harkó

Lake

2015

Phys. Rev. D

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We consider the possible existence of gravitationally bound general relativistic strings consisting of Bose-Einstein condensate (BEC) matter which is described, in the Newtonian limit, by the zero temperature time-dependent nonlinear Schr\"odinger equation (the Gross-Pitaevskii equation), with repulsive interparticle interactions. In the Madelung representation of the wave function, the quantum dynamics of the condensate can be formulated in terms of the classical continuity equation and the hydrodynamic Euler equations. In the case of a condensate with quartic nonlinearity, the condensates can be described as a gas with two pressure terms, the interaction pressure, which is proportional to the square of the matter density, and the quantum pressure, which is without any classical analogue though, when the number of particles in the system is high enough, the latter may be neglected. Assuming cylindrical symmetry, we analyze the physical properties of the BEC strings in both the interaction pressure and quantum pressure dominated limits, by numerically integrating the gravitational field equations. In this way we obtain a large class of stable stringlike astrophysical objects, whose basic parameters (mass density and radius) depend sensitively on the mass and scattering length of the condensate particle, as well as on the quantum pressure of the Bose-Einstein gas.Comment: 22 pages, 24 figures. Published versio

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Cosmic strings in $$f\left( R,L_m\right) $$ f R , L m gravity

Cited by 42 publications

References 149 publications

Locally rotationally symmetric Bianchi type I cosmology in f(R, T) gravity

Locally rotationally symmetric Bianchi type I cosmology in f(R, T) gravity

Cosmic string in gravity’s rainbow

Bose-Einstein condensate strings

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