Stability analysis of anisotropic Bianchi type-I cosmological model in teleparallel gravity

Koussour, M.; Bennai, M.

doi:10.1088/1361-6382/ac61ad

Cited by 26 publications

(12 citation statements)

References 61 publications

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“…In the literature, there are many alternatives to GR that attempt to explain this problem [5][6][7]. The most popular alternative currently proposed are modified gravity theories such as f (R) gravity, where f (R) is an arbitrary function of the Ricci scalar R. Several models have been studied in framework of f (R) gravity in var-ious cosmological contexts [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Bulk viscous fluid in extended symmetric teleparallel gravity

Koussour

Shekh²,

Беннаи³

et al. 2024

Chinese Journal of Physics

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Section: Introductionmentioning

confidence: 99%

Bulk viscous fluid in extended symmetric teleparallel gravity

Koussour

Shekh²,

Беннаи³

et al. 2024

Chinese Journal of Physics

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“…In GR, the Levi‐Civita connection is associated with curvature, but zero torsion, while in teleparallelism, the Weitzenbock connection is associated with torsion, but zero curvature. [ 21 ] In the same way, the

f(T)

gravity is the simplest modification of TEGR. Recently, a new theory of gravity has been proposed called the symmetric teleparallel equivalent of GR (STEGR), in which the gravitational interactions are described by the concept of non‐metricity Q with zero torsion and curvature.…”

Section: Introductionmentioning

confidence: 99%

“…The fundamental concept in GR is the curvature imported from Riemannian geometry which is described by the Ricci scalar R. The modified f (R) gravity is a simple modification of GR, replacing the Ricci scalar R with some general function of R. [20] Furthermore, there are other alternatives to GR such as the teleparallel equivalent of GR (TEGR), in which the gravitational interactions are described by the concept of torsion T. In GR, the Levi-Civita connection is associated with curvature, but zero torsion, while in teleparallelism, the Weitzenbock connection is associated with torsion, but zero curvature. [21] In the same way, the f (T) gravity is the simplest modification of TEGR. Recently, a new theory of gravity has been proposed called the symmetric teleparallel equivalent of GR (STEGR), in which the gravitational interactions are described by the concept of non-metricity Q with zero torsion and curvature.…”

mentioning

confidence: 98%

A New Parametrization of Hubble Parameter in f(Q)$f(Q)$ Gravity

Koussour

Pacif

Bennai

et al. 2023

Fortschritte der Physik

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In this paper, we examine the accelerated expansion of the Universe at late‐time in the framework of ffalse(Qfalse)$f(Q)$ gravity theory in which the non‐metricity scalar Q describes the gravitational interaction. To this, we propose a new parametrization of the Hubble parameter using a model‐independent way and apply it to the Friedmann equations in the FLRW Universe. Then we estimate the best fit values of the model parameters by using the combined datasets of updated Hfalse(zfalse)$H(z)$ consisting of 57 points, the Pantheon consisting of 1048 points, and BAO datasets consisting of six points with the Markov Chain Monte Carlo (MCMC) method. The evolution of deceleration parameter indicates a transition from the deceleration to the acceleration phase of the Universe. In addition, we investigate the behavior of statefinder analysis and Om diagnostic parameter, Further, to discuss other cosmological parameters, we consider a ffalse(Qfalse)$f(Q)$ model, specifically, f(Q)=Q+mQn$f(Q) =Q+mQ^{n}$, where m and n are free parameters. Finally, we find that the model supports the present accelerating Universe, and the EoS parameter behaves like the quintessence model.

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“…In general, MGT appears to be quite appealing since it provides subjective solutions to a number of key problems concerning DE. An alternative theory to GR is teleparallel gravity by which gravitational interaction is described by the torsion scalar T [8][9][10] in a space-time with zero curvature. This theory is named teleparallel equivalent to general relativity (TEGR) and formulated by tetrad fields on the tangent space in the Weitzenbock connection which is different from the Levi-Civita connection in GR.…”

Section: Introductionmentioning

confidence: 99%

Late-time acceleration in $f\left( Q\right) $ gravity: Analysis and constraints in an anisotropic background

Koussour¹,

Bourakadi²,

Shekh³

et al. 2022

Preprint

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This paper is devoted to investigate the anisotropic locally rotationally symmetric (LRS) Bianchi type-I space-time in the context of the recently proposed f (Q) gravity in which Q is the nonmetricity scalar. For this purpose, we consider a linear form of f (Q) gravity model, specifically, f (Q) = αQ + β, where α and β are free parameters and we analyzed the exact solutions of LRS Bianchi type-I space-time. The modified Friedmann equations are solved by presuming an expansion scalar θ (t) is proportional to the shear scalar σ (t) which leads to the relation between the metric potentials as A = B n where n is an arbitrary constant. Then we constrain our model parameters with the observational Hubble datasets of 57 data points. Moreover, we discuss the physical behavior of cosmological parameters such as energy density, pressure, EoS parameter, and deceleration parameter. The behavior of the deceleration parameter predicts a transition from deceleration to accelerated phases in an expanding Universe. Finally, the EoS parameter indicates that the anisotropic fluid behaves like the standard ΛCDM model.

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Stability analysis of anisotropic Bianchi type-I cosmological model in teleparallel gravity

Cited by 26 publications

References 61 publications

Bulk viscous fluid in extended symmetric teleparallel gravity

Bulk viscous fluid in extended symmetric teleparallel gravity

A New Parametrization of Hubble Parameter in f(Q)$f(Q)$ Gravity

Late-time acceleration in $f\left( Q\right) $ gravity: Analysis and constraints in an anisotropic background

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