The Effect of f(R, T) Modified Gravity on the Mass and Radius of Pulsar HerX1

Nashed, G. G. L.

doi:10.3847/1538-4357/acd182

Cited by 12 publications

(7 citation statements)

References 139 publications

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“…In spite of the capability of the model to lower the speed of sound in comparison to the GR or quadratic gravity with positive ϵ cases, it is still above the conjectured conformal upper bound on the maximum sound speed c 2 s = c 2 /3. This result may favor matter-geometry nonminimal coupling scenario to provide better framework for treating that issue as suggested by [26,37,84].…”

Section: Jcap09(2023)038mentioning

confidence: 89%

Constraining quadratic f(R) gravity from astrophysical observations of the pulsar J0704+6620

Nashed,

El Hanafy

2023

J. Cosmol. Astropart. Phys.

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We apply quadratic f(R) = R + ϵR 2 field equations, where ϵ has a dimension [L2], to static spherical stellar model. We assume the interior configuration is determined by Krori-Barua ansatz and additionally the fluid is anisotropic. Using the astrophysical measurements of the pulsar PSR J0740+6620 as inferred by NICER and XMM observations, we determine ϵ ≈ ± 3 km2. We show that the model can provide a stable configuration of the pulsar PSR J0740+6620 in both geometrical and physical sectors. We show that the Krori-Barua ansatz within f(R) quadratic gravity provides semi-analytical relations between radial, pr , and tangential, pt , pressures and density ρ which can be expressed as pr ≈ vr 2 (ρ-ρ 1) and pr ≈ vt 2 (ρ-ρ 2), where vr (vt ) is the sound speed in radial (tangential) direction, ρ 1 = ρs (surface density) and ρ 2 are completely determined in terms of the model parameters. These relations are in agreement with the best-fit equations of state as obtained in the present study. We further put the upper limit on the compactness, C = 2GMRs -1 c -2, which satisfies the f(R) modified Buchdahl limit. Remarkably, the quadratic f(R) gravity with negative ϵ naturally restricts the maximum compactness to values lower than Buchdahl limit, unlike the GR or f(R) gravity with positive ϵ where the compactness can arbitrarily approach the black hole limit C → 1. The model predicts a core density a few times the saturation nuclear density ρ nuc = 2.7 × 1014 g/cm3, and a surface density ρs > ρnuc . We provide the mass-radius diagram corresponding to the obtained boundary density which has been shown to be in agreement with other observations.

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Section: Jcap09(2023)038mentioning

confidence: 89%

Constraining quadratic f(R) gravity from astrophysical observations of the pulsar J0704+6620

Nashed,

El Hanafy

2023

J. Cosmol. Astropart. Phys.

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“…Multiple minimal/non-minimal models have been proposed in this scenario, among them   x + 2 gained great attention in the literature due to its linear nature. Nashed [11] discussed various pulsars in this linear gravity model and solved the differential equations by making an explicit assumption regarding the anisotropy and radial component of the metric. They found that the estimated masses of these pulsars are in accordance with the observed ones.…”

Section: Introductionmentioning

confidence: 99%

Extending Finch-Skea isotropic model to anisotropic domain in modified f(, T ) gravity

Naseer,

Sharif

2024

Phys. Scr.

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This paper considers the Finch-Skea isotropic solution and extendsits domain to three different anisotropic interiors by using thegravitational decoupling strategy in the context of$f(\mathbb{R},\mathbb{T})$ gravitational theory. For this, weconsider that a static spherical spacetime is initially coupled withthe perfect matter distribution. We then introduce a Lagrangiancorresponding to a new gravitating source by keeping in mind thatthis new source produces the effect of pressure anisotropy in theparent fluid source. After calculating the field equations for thetotal matter setup, we apply a transformation on the radialcomponent, ultimately providing two different systems of equations.These two sets are solved independently through differentconstraints that lead to some new solutions. Further, we consider anexterior spacetime to calculate three constants engaged in the seedFinch-Skea solution at the spherical interface. The estimated radiusand mass of a star candidate LMC X-4 are utilized to perform thegraphical analysis of the developed models. It is concluded thatonly the first two resulting models are physically relevant in thismodified theory for all the considered parametric choices.

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“…On the other hand, Harko and collaborators [57] proposed another extension of standard GR, the f (R, T) modified gravity theories, where the gravitational Lagrangian is given by an arbitrary function of the Ricci scalar R and of the trace of the energy-momentum tensor T. The cosmological consequences [58][59][60][61][62][63][64][65][66][67][68][69] and applications to compact stars [70][71][72][73][74][75][76][77][78][79][80][81][82][83] of such a theory have been addressed by several authors in recent years. See further [84][85][86][87] for a novel scalar-tensor representation of f (R, T) gravity.…”

Section: Introductionmentioning

confidence: 99%

Moment of inertia and compactness of quark stars within the context of f(R, T, L _m) gravity

Pretel

2024

Phys. Scr.

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Within the metric formalism of f(R, T, L m ) gravity theories, we investigate the hydrostatic equilibrium structure of compact stars taking into account both isotropic and anisotropic pressure. For this purpose, we focus on the f(R, T, L m ) = R + α TL m model, where α is a free parameter. We derive the modified TOV equations and the relativistic moment of inertia in the slowly rotating approximation. Using an equation of state (EoS) for color-superconducting quark stars, we examine the effects of the α TL m term on the different macroscopic properties of these stars. Our results reveal that the decrease of the parameter α leads to a noticeable increase in the maximum-mass values. For negative α with sufficiently small ∣α∣, we obtain a qualitative behavior similar to the general relativistic (GR) context, namely, it is possible to obtain a critical stellar configuration such that the mass reaches its maximum. However, for sufficiently large values of ∣α∣ keeping negative α, the critical point cannot be found on the mass-radius diagram. We also find that the inclusion of anisotropic pressure can provide masses and radii quite consistent with the current observational measurements, which opens an outstanding window onto the physics of anisotropic quark stars. By comparing the I − C relations of isotropic quark stars in modified gravity, we show that such a correlation remains almost unchanged as the parameter α varies from GR counterpart. On the other hand, given a fixed α, the I − C relation is insensitive to variations of the anisotropy parameter β to O ( 4 % ) .

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The Effect of f(R, T) Modified Gravity on the Mass and Radius of Pulsar HerX1

Cited by 12 publications

References 139 publications

Constraining quadratic f(R) gravity from astrophysical observations of the pulsar J0704+6620

Constraining quadratic f(R) gravity from astrophysical observations of the pulsar J0704+6620

Extending Finch-Skea isotropic model to anisotropic domain in modified f(, T ) gravity

Moment of inertia and compactness of quark stars within the context of f(R, T, L _m) gravity

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The Effect of f(R, T) Modified Gravity on the Mass and Radius of Pulsar HerX1

Cited by 12 publications

References 139 publications

Constraining quadratic f(R) gravity from astrophysical observations of the pulsar J0704+6620

Constraining quadratic f(R) gravity from astrophysical observations of the pulsar J0704+6620

Extending Finch-Skea isotropic model to anisotropic domain in modified f(, T ) gravity

Moment of inertia and compactness of quark stars within the context of f(R, T, L m ) gravity

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Resources

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Moment of inertia and compactness of quark stars within the context of f(R, T, L _m) gravity