Your search keyword '"Rahaman, Farook"' showing total 445 results

1. A new type of $f(\mathcal{T})$ gravity from Barrow entropy

Author

Ghorui, Tuhina, Rudra, Prabir, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

In this work, two originally separate adjustments for the Friedmann equations are concurrently considered. Firstly, the fractal structure of the black hole horizon region is imposed by the Barrow entropy. The second adjustment is the $f(\mathcal{T})$ gravity, which is based on a teleparallel framework generalization of the Einstein-Hilbert action, where $\mathcal{T}$ is the scalar torsion. This can be considered as a Barrow entropy modification of the $f(\mathcal{T})$ gravity thus yielding a new model. Gravity thermodynamics hypothesis principles are used to integrate these two models under a unified framework. We derive the modified Friedmann equation and note the corrections obtained. To understand the implications of such dual modifications, an application is analyzed and a particular $f(\mathcal{T})$ toy model is chosen for the purpose. The equation of the state parameter of the resulting model, the dimensionless density parameters of matter and dark energy, and the deceleration parameter are explored to check the viability of the new model. A discussion of the dynamic evolution of the universe follows from these results. It is seen that the results comply with the observations. The newly developed model is promising and demands further study., Comment: 15 pages, 5 figures. arXiv admin note: text overlap with arXiv:2211.04178 by other authors

Published

2024

2. Evolving wormhole geometry from dark matter energy density

Author

Rahaman, Farook and Choudhury, Bikramarka S

Subjects

General Relativity and Quantum Cosmology

Abstract

We analyze traversable wormholes defined by the dynamic line elements that asymptotically approaches Friedmann-Robertson-Walker (FRW) universe. This dynamical wormholes is supported by the galactic dark matter as well as perfect isotropic fluid. We will discuss several evolving Lorentzian wormholes comprising with different perfect isotropic fluids in addition to various scale factors. We will speculate the various significance, features and throat energy conditions for these evolving traversable Lorentzian wormholes., Comment: Paper is accepted for publication in 'The European Physical Journal C'

Published

2024

3. Finslerian extension of an anisotropic strange star in the domain of modified gravity

Author

Chowdhury, Sourav Roy, Deb, Debabrata, Rahaman, Farook, and Ray, Saibal

Subjects

General Relativity and Quantum Cosmology

Abstract

In this article, we apply the Finsler spacetime to develop the Einstein field equations in the extension of modified geometry. Following Finsler geometry, which is focused on the tangent bundle with a scalar function, a scalar equation should be the field equation that defines this structure. This spacetime maintains the required causality properties on the generalized Lorentzian metric manifold. The matter field is coupled with the Finsler geometry to produce the complete action. In this work, we use modified gravity to develop the Einstein field equations from the variational principle. Developed Einstein field equations are employed on the strange stellar system to improve the study. The interior of the system is made of a strange quark, maintained by the MIT Bag equation of state. In addition, the modified Tolman-Oppenheimer-Volkov (TOV) equation is formulated. In particular, the anisotropic stress attains the maximum at the surface. The mass-central density variation justifies the stability of the system., Comment: Accepted for publication in EPJC

Published

2024

4. Conservative wormholes in generalized $\kappa(\mathcal{R},\mathcal{T})$-function

Author

Singh, Ksh. Newton, Teruel, G. R. P., Maurya, S. K., Chowdhury, Tanmoy, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology, 83Dxx, 83-XX02

Abstract

We present an exhaustive study of wormhole configurations in $\kappa(\mathcal{R},\mathcal{T})$ gravity with linear and non-linear functions. The model assumed Morrison-Thorne spacetime where the redshift and shape functions linked with the matter contain and geometry of the spacetime through non-covariant conservation equation of the stress-energy tensor. The first solution was explored assuming a constant redshift function that leads to a wormhole (WH) which is asymptotically non-flat. The remaining solutions were explored in two cases. Firstly, assuming a linear equation of state $p(r)=\omega \rho(r)$ along with different forms of $\kappa(\mathcal{R},\mathcal{T})-$function. This proved enough to derive a shape function of the form $b(r)=r_{0}\left(\frac{r_{0}}{r}\right)^{1/\omega}$. Secondly, by assuming specific choices of the shape function consistent with the wormhole configuration requirements. All the solutions fulfill flare-out condition, asymptotically flat and supported by phantom energy. Further, the embedding surface and its revolution has been generated using numerical method to see how the length of the throat is affected of the coupling parameters through $\kappa(\mathcal{R},\mathcal{T})$ function. At the end, we have also calculated the average null energy condition, which is satisfied by all the WH models signifying minimum exotic matter is required to open the WH throats., Comment: 25 Pages, 17 figures, submitted to JHEP

Published

2024

5. Reconstruction of $f(T,\mathcal{T})$ Lagrangian for various cosmological scenarios

Author

Ghorui, Tuhina, Rudra, Prabir, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

In this paper, we explore a reconstruction scheme in the background of the $f(T,\mathcal{T})$ gravity theory for different cosmological scenarios, where $T$ is the scalar torsion and $\mathcal{T}$ is the trace of the energy-momentum tensor. Using the reconstruction technique $f(T, \mathcal{T})$ Lagrangian is constructed for different cosmological eras such as dust, $\Lambda CDM$, perfect fluid, etc. Both minimal and non-minimal matter-coupled models are considered for this purpose. Different cosmological scenarios such as power law expansion, de-Sitter expansion, etc. have been considered, and using them Lagrangian functionals are constructed. Mathematical viabilities of all the constructed functionals have been investigated. The physical implications of the obtained solutions are discussed in detail. To check the cosmological compatibility of the constructed $f(T,\mathcal{T})$ functionals we have generated plots of important parameters like the equation of state parameter and deceleration parameter. It is seen that the reconstructed models are perfectly compatible with the late-time accelerated expansion of the universe., Comment: 23 pages, 4 figures

Published

2023

6. Testing of K(R,T)-gravity through gravastar configurations

Author

Teruel, GRP, Singh, Ksh. Newton, Chowdhury, Tanmoy, Rahaman, Farook, and Mondal, Monimala

Subjects

General Relativity and Quantum Cosmology

Abstract

In this article, we are reporting for the first time the existence of gravastar configurations in the framework of K(R,T)-gravity, which can be treated as an alternative to a black hole (Mazur and Mottola). This strengthens how much this new gravity theory may be physically demanding to the gravity community in the near future. We first develop the gravastar field equations for a generic K(R,T) functional and then we study four different models within this theory. We find that the solutions for the interior region are regular everywhere regardless of the exact form of the K(R,T) functional. The solutions for the shell region indicate that two of the four models subjected to the study are physically feasible. In addition, the junction conditions are considered at each interface by using the Lanczos equations that yield the surface density and pressure at the thin shell. We investigate various characteristics of the gravastar structure such as the proper length, energy, and entropy of the spherical distribution.

Published

2023

7. Euclidean quantum wormholes

Author

Rahaman, Farook, Choudhury, Bikramarka S., and Islam, Anikul

Published

2024

8. Study of compact objects: a new analytical stellar model

Author

Das, Shyam, Chakraborty, Koushik, Rahaman, Farook, and Majumder, Shreya

Published

2024

9. Possible existence of stable compact stars in $\kappa(\mathcal{R},\mathcal{T})-$gravity

Author

Teruel, Ginés R. Pérez, Singh, Ksh. Newton, Rahaman, Farook, and Chowdhury, Tanmoy

Subjects

General Relativity and Quantum Cosmology

Abstract

We present the first interior solutions representing compact stars in $\kappa(\mathcal{R},\mathcal{T})$ gravity, by solving the modified field equations in isotropic coordinates. Further, we have assumed the metric potentials in Schwarzschild's form and a few parameters along with the isotropic condition of pressure. For solving, we use specific choice of the running gravitational constant as $\kappa(\mathcal{R},\mathcal{T})=8\pi-\lambda \mathcal{T} ~~(G=\tilde{c}=1)$. Once arrived at the reduced field equations, we investigate two solutions with $c=1$ and $c \neq 1$, where $c$ denotes here another constant that should not be confused with the speed of light. Then, we investigate each solution by determining the thermodynamics variable {\it viz} pressure, density, speed of sound, and adiabatic index. We found that these solutions satisfy the Bondi criterion, causality condition, and energy conditions. We also found that the $M-R$ curves generated from these solutions satisfy the stringent constraints provided by the gravitational wave observations due to the neutron star merger GW 170817., Comment: 15 pages, 9 figures

Published

2022

10. On some properties of M-projective curvature tensor in spacetime of general relativity

Author

Ali, Musavvir, Salman, Mohammad, Rahaman, Farook, and Pundeer, Naeem Ahmad

Subjects

General Relativity and Quantum Cosmology, 53C50, 53C25, 83C20, 83C50, 83C05

Abstract

In this paper, we investigate the connection between the M-projective curvature tensor and other tensors. Also, we obtain the divergence of M-projective curvature tensor. A symmetry of spacetime known as M-projective collineation has been presented, and it has been possible to determine the conditions under which the general relativity spacetimes can admit such collineations.

Published

2022

11. Wormholes in $\kappa(R,T)$ gravity

Author

Sarkar, Susmita, Sarkar, Nayan, Rahaman, Farook, and Aditya, Y

Subjects

General Relativity and Quantum Cosmology

Abstract

The wormhole solution could be found by solving the Einstein field equations with violating the null energy condition (NEC). We represent wormhole solutions in $\kappa(R,T)$ gravity in two different ways. At first, we find the shape function by considering a redshift function and linear equation of state (EoS). The solution represents a wormhole for the real feasible matter. In the second part, we consider four pairs of two redshift functions and two shape functions and analyze the obtained solutions. Some of the models suggest that for particular values of the parameters, the existence of wormholes are supported by an arbitrarily small quantity of exotic matter., Comment: 15 pages, 12 figures. Published in To Physics Journal Vol 2, page 7 (2019)

Published

2022

12. Quasi Normal Modes of Ayon-Beato Garcia Regular Black Holes For Scalar Field

Author

Murshid, Masum, Rahaman, Farook, and Kalam, Mehedi

Subjects

General Relativity and Quantum Cosmology

Abstract

In this paper, we compute quasi-normal modes of ABG black holes (which has a non-linear electrodynamical source) using the WKB methods and AIM. A comparison between the spectrum of QNMs calculated by both methods is made. We analyse how the spectrum of QNMs depends on the black hole parameters, multipole number and overtone number and establish that the ABG black hole is stable against the scalar field.

Published

2022

13. Physical Implications of Pure Lovelock Geometry on Stellar Structure

Author

Singh, Ksh. Newton, Govender, Megandhren, Hansraj, Sudan, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology, Astrophysics - High Energy Astrophysical Phenomena, 83Dxx, 83Exx, 83-10

Abstract

We construct an exact anisotropic star model with a linear barotropic equation of state and with Finch-Skea potential within the framework of pure Lovelock gravity. A comparison with the corresponding Einstein model in a suitable limit is easily deduced. Evidently higher curvature effects induced by the Lovelock contributions generate lower densities, pressures, surface tensions and anisotropy factors when compared to its Einstein counterpart. The maximum moment of inertia is attained for the Einstein case and hence it may be inferred that Lovelock effects soften the equation of state. The model satisfies various stability tests., Comment: 11 Pages, 16 Figures, 1 Table

Published

2022

14. Geometrical Origin of Growth of Matter Perturbations

Author

De, S S, Rahaman, Farook, and Mapdar, Antara

Subjects

General Relativity and Quantum Cosmology

Abstract

The density perturbation of the universe has been considered in the framework of a Finslerian cosmological model in which the background spacetime of the universe is taken as the spatially flat FLRW spacetime with a Finslerian perturbation. The inhomogeneity in the matter(energy) density arises naturally in this consideration of gravity in the $( \alpha, \beta)$ - Finsler space for the background spacetime of the universe. The resulting inhomogeneous matter density indicates matter perturbation departing from the uniform density, and it is caused by the Finslerian perturbation in the Riemannian spacetime, thus ascertaining the geometrical origin of the growth of matter perturbation., Comment: 5 pages. 1 figure

Published

2022

15. Anisotropic compact stellar objects with a slow rotation effect

Author

Baskey, Lipi, Das, Shyam, and Rahaman, Farook

Published

2024

16. A note on shock wave in the dark matter medium

Author

Azam, Mofazzal, Sami, M, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

Employing Newton's stellar balance equation and using the flat rotation velocity of satellite galaxies, we have found the velocity of sound in the dark matter medium. What is interesting is that the velocity of satellite galaxies is very much larger than the velocity of sound in the dark matter medium. This indicates that there will be shock wave in the dark matter medium due to the supersonic movement of satellite galaxies., Comment: 4 pages. Submitted in Phys.Lett.B on 25.11.21

Published

2022

17. Gravitational deflection of massive body around naked singularity

Author

Hossain, Md Khalid, Takizawa, Keita, Islam, Anikul, Das, Shyam, and Rahaman, Farook

Published

2024

18. Thin accretion disks around traversable wormholes

Author

Rahaman, Farook, Manna, Tuhina, Shaikh, Rajibul, Aktar, Somi, Mondal, Monimala, and Samanta, Bidisha

Subjects

General Relativity and Quantum Cosmology

Abstract

In this paper, we aim to investigate various physical properties and characteristics of radiation emerging from the surface of accretion disks, in a rotating traversable axially symmetric wormhole spacetime of the Teo class. We have studied the marginally stable orbits and accretion efficiency graphically, corresponding to different values of dimensionless spin parameter $J/M^2$ ranging from 0.2 to 1.5 and some values of the throat radius $r_0$, in comparison to the Kerr black hole with the same parameter values, and also tabulated the results. The energy flux radiated by the accretion disk $F(r)$, the temperature distribution $T(r)$ and the emission spectra $\nu L(\nu)$ is plotted, corresponding to varying values of the dimensionless spin parameter $J/M^2$ and throat radius $r_0$. Also, the critical frequency at which the luminosity attains its maximum value, for various values of the angular momentum of the wormhole $J/M^2$ and $r_0$ is tabulated. Lastly, we have employed ray-tracing technique, to produce the intensity map of the image of an accretion disk, as observed by an asymptotic observer, under two conditions: firstly when the disk is on the same side as the observer and we have also compared those with the images of an accretion disk in case of Kerr black hole with same parameters. Secondly, the images have been provided when the disk and observer are on opposite sides of the throat. This study may help to detect and distinguish wormhole geometries from other compact objects., Comment: 18 pages, 6 figures. Published in Nuclear Physics B

Published

2021

19. Quark stars in 4-dimensional Einstein-Gauss-Bonnet gravity

Author

Singh, Ksh. Newton, Maurya, S. K., Dutta, Abhisek, Rahaman, Farook, and Aktar, Somi

Subjects

General Relativity and Quantum Cosmology

Abstract

The article explores the first exact solution in a four-dimensional EGB-gravity with an anisotropic matter source. The solution has been found by two assumptions, a metric potential and the MIT-bag equation of state. Further, the solution has been tested with several physical constraints. Finally, using the boundary condition we have also estimated the range of bag constant $\mathcal{B}$ by varying the mass of the structure and the Gauss-Bonnet coupling constant $\alpha$. This allows us to check the physical viability of the solution by comparing it with the existing accepted range of bag constant $\mathcal{B}$., Comment: 10 pages, 12 Figures, 1 Table (Accepted in Eur. Phys. J. C)

Published

2021

20. Wormhole geometries in $f(Q)$ gravity and the energy conditions

Author

Banerjee, Ayan, Pradhan, Anirudh, Tangphati, Takol, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

Following the recent theory of $f(Q)$ gravity, we continue to investigate the possible existence of wormhole geometries, where $Q$ is the non-metricity scalar. Recently, the non-metricity scalar and the corresponding field equations have been studied for some spherically symmetric configurations in [ Phys. Lett. B 821, 136612 (2021) and Phys. Rev. D 103, 124001 (2021) ]. One can note that field equations are different in these two studies. Following [Phys. Rev. D 103, 124001 (2021)], we systematically study the field equations for wormhole solutions and found the violation of null energy conditions in the throat neighborhood. More specifically, considering specific choices for the $f(Q)$ form and for constant redshift with different shape functions, we present a class of solutions for static and spherically symmetric wormholes. Our survey indicates that wormhole solutions could not exist for specific form function $f(Q)= Q+ \alpha Q^2$. To summarize, exact wormhole models can be constructed with violation of the null energy condition throughout the spacetime while being $\rho \geq 0$ and vice versa., Comment: 7 pages, 3 figures, version accepted for publication in The European Physical Journal C

Published

2021

21. Shadows of Lorentzian traversable wormholes

Author

Rahaman, Farook, Singh, Ksh. Newton, Shaikh, Rajibul, Manna, Tuhina, and Aktar, Somi

Subjects

General Relativity and Quantum Cosmology

Abstract

The prospect of identifying wormholes by investigating the shadows of wormholes constitute a foremost source of insight into the evolution of compact objects and it is one of the essential problems in contemporary astrophysics. The nature of the compact objects (wormholes) plays a crucial role on shadow effect, which actually arises during the strong gravitational lensing. Current Event Horizon Telescope observations have inspired scientists to study and to construct the shadow images of the wormholes. In this work, we explore the shadow cast by a certain class of rotating wormhole. To search this, we first compose the null geodesics and study the effects of the parameters on the photon orbit. We have exposed the form and size of the wormhole shadow and have found that it is slanted as well as can be altered depending on the different parameters present in the wormhole spacetime. We also constrain the size and the spin of the wormhole using the results from M87* observation, by investigating the average diameter of the wormhole as well as deviation from circularity with respect to the wormhole throat size. In a future observation, this type of study may help to indicate the presence of a wormhole in a galactic region., Comment: 12 pages, 7 figures. published in Class.Quan.Grav

Published

2021

22. Relativistic model of anisotropic star with Bose–Einstein density depiction

Author

Sarkar, Susmita, Sarkar, Nayan, Rudra, Prabir, Rahaman, Farook, and Ghorui, Tuhina

Published

2023

23. Quark matter supported wormhole in third order Lovelock gravity

Author

Chakraborty, Koushik, Aziz, Abdul, Rahaman, Farook, and Ray, Saibal

Subjects

General Relativity and Quantum Cosmology

Abstract

It is generally believed that wormholes are supported by exotic matter violating Null Energy Condition (NEC). However, various studies of wormhole geometries under Lovelock theories of gravity have reported existence of wormhole supported by matter satisfying NEC. Being inspired by these results, we explore the possibility of the existence of wormhole supported by normal quark matter in third order Lovelock gravity theory. Well known MIT Bag Model Equation of state is chosen for describing the quark matter. Taking physically acceptable approximations, we solve the field equations for shape function which satisfies flare out condition. The residual of the approximate solution is studied for accuracy and found to be acceptable., Comment: 15 pages, 6 figures

Published

2021

24. Lyapunov exponent ISCO and Kolmogorov Senai entropy for Kerr Kiselev black hole

Author

Mondal, Monimala, Rahaman, Farook, and Singh, Ksh. Newton

Subjects

General Relativity and Quantum Cosmology

Abstract

Geodesic motion has significant characteristics of space-time. We calculate the principle Lyapunov exponent (LE), which is the inverse of the instability timescale associated with this geodesics and Kolmogorov-Senai (KS) entropy for our rotating Kerr-Kiselev (KK) black hole. We have investigate the existence of stable/unstable equatorial circular orbits via LE and KS entropy for time-like and null circular geodesics. We have shown that both LE and KS entropy can be written in terms of the radial equation of innermost stable circular orbit (ISCO) for time-like circular orbit. Also, we computed the equation marginally bound circular orbit, which gives the radius (smallest real root) of marginally bound circular orbit (MBCO). We found that the null circular geodesics has larger angular frequency than time-like circular geodesics ($Q_o > Q_{\sigma}$). Thus, null-circular geodesics provides the fastest way to circulate KK black holes. Further, it is also to be noted that null circular geodesics has shortest orbital period $(T_{photon}< T_{ISCO})$ among the all possible circular geodesics. Even null circular geodesics traverses fastest than any stable time-like circular geodesics other than the ISCO., Comment: 16 pages, 5 figures. Published in EPJC

Published

2021

25. An analytical anisotropic compact stellar model of embedding class I

Author

Baskey, Lipi, Das, Shyam, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

A class of solutions of Einstein field equations satisfying Karmarkar embedding condition is presented which could describe static, spherical fluid configurations, and could serve as models for compact stars. The fluid under consideration has unequal principal stresses i.e. fluid is locally anisotropic. A certain physically motivated geometry of metric potential has been chosen and codependency of the metric potentials outlines the formation of the model. The exterior spacetime is assumed as described by the exterior Schwarzschild solution. The smooth matching of the interior to the exterior Schwarzschild spacetime metric across the boundary and the condition that radial pressure is zero across the boundary lead us to determine the model parameters. Physical requirements and stability analysis of the model demanded for a physically realistic star are satisfied. The developed model has been investigated graphically by exploring data from some of the known compact objects. The mass-radius (M-R) relationship that shows the maximum mass admissible for observed pulsars for a given surface density has also been investigated. Moreover, the physical profile of the moment of inertia (I) thus obtained from the solutions is confirmed by the Bejger-Haensel concept., Comment: Accepted in Mod. Phys. Lett. A

Published

2020

26. A new model for dark matter fluid sphere

Author

Das, Shyam, Sarkar, Nayan, Mondal, Monimala, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

We develop a new model for a spherically symmetric dark matter fluid sphere containing two regions: {\bf (i)} Isotropic inner region with constant density and {\bf (ii)} Anisotropic outer region. We solve the system of field equation by assuming a particular density profile along with a linear equation of state. The obtained solutions are well-behaved and physically acceptable which represent equilibrium and stable matter configuration by satisfying the TOV equation and causality condition, condition on adiabatic index, Harrison-Zeldovich-Novikov criterion, respectively. We consider the compact star EXO 1785-248 (Mass $M=1.3~M_{\odot}$ and radius $R = 8.8 ~km.$) to analyze our solutions by graphical demonstrations., Comment: 11 pages, 11 figures, 2 tables. Accepted in Mod.Phys.Lett.A

Published

2020

27. Null Geodesics and QNMs in the field of Regular Black Holes

Author

Mondal, Monimala, Yadav, Anil Kumar, Pradhan, Parthapratim, Islam, Sayeedul, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

We analyze the null geodesics of regular black holes. A detailed analysis of geodesic structure both null geodesics and time-like geodesics have been investigated for the said black hole. As an application of null geodecics, we calculate the radius of photon sphere and gravitational bending of light. We also study the shadow of the black hole spacetime. Moreover, we determine the relation between radius of photon sphere~$(r_{ps})$ and the shadow observed by a distance observer. Furthermore, We discus the effect of various parameters on the radius of shadow $R_s$. Also we compute the angle of deflection for the photons as a physical application of null-circular geodesics. We find the relation between null geodesics and quasinormal modes frequency in the eikonal approximation by computing the Lyapunov exponent. It is also shown that~(in the eikonal limit) the quasinormal modes~(QNMs) of black holes are governed by the parameter of null-circular geodesics. The real part of QNMs frequency determines the angular frequency whereas the imaginary part determines the instability time scale of the circular orbit. Next we study the massless scalar perturbations and analyze the effective potential graphically. Massive scalar perturbations also discussed. As an application of time-like geodesics we compute the innermost stable circular orbit~(ISCO) and marginally bound circular orbit~(MBCO) of the regular BHs which are closely related to the black hole accretion disk theory. In the appendix, we calculate the relation between angular frequency and Lyapunov exponent for null-circular geodesics., Comment: 24 pages, 18 figure panels, Accepted in Int. J. Mod. Phys. D

Published

2020

28. Geodesic stability and Quasi normal modes via Lyapunov exponent for Hayward Black Hole

Author

Mondal, Monimala, Pradhan, Parthapratim, Rahaman, Farook, and Karar, Indrani

Subjects

General Relativity and Quantum Cosmology

Abstract

We derive proper-time Lyapunov exponent $(\lambda_{p})$ and coordinate-time Lyapunov exponent $(\lambda_{c})$ for a regular Hayward class of black hole. The proper-time corresponds to $\tau$ and the coordinate time corresponds to $t$. Where $t$ is measured by the asymptotic observers both for for Hayward black hole and for special case of Schwarzschild black hole. We compute their ratio as $\frac{\lambda_{p}}{\lambda_{c}} = \frac{(r_{\sigma}^{3} + 2 l^{2} m )}{\sqrt{(r_{\sigma}^{2} + 2 l^{2} m )^{3}- 3 m r_{\sigma}^{5}}}$ for time-like geodesics. In the limit of $l=0$ that means for Schwarzschild black hole this ratio reduces to $\frac{\lambda_{p}}{\lambda_{c}} = \sqrt{\frac{r_{\sigma}}{(r_{\sigma}-3 m)}}$. Using Lyponuov exponent, we investigate the stability and instability of equatorial circular geodesics. By evaluating the Lyapunov exponent, which is the inverse of the instability time-scale, we show that, in the eikonal limit, the real and imaginary parts of quasi-normal modes~(QNMs) is specified by the frequency and instability time scale of the null circular geodesics. Furthermore, we discuss the unstable photon sphere and radius of shadow for this class of black hole., Comment: To appear in Mod.Phys.Lett.A, 19 pages and 6 figures

Published

2020

29. Color-flavor locked quark stars in energy-momentum squared gravity

Author

Singh, Ksh. Newton, Banerjee, Ayan, Maurya, S. K., Rahaman, Farook, and Pradhan, Anirudh

Subjects

General Relativity and Quantum Cosmology

Abstract

Several attempts have been made in the past decades to search for the true ground state of the dense matter at sufficiently large densities and low temperatures via compact astrophysical objects. Focusing on strange stars, we derive the hydrostatic equilibrium assuming a maximally symmetric phase of homogeneous superconducting quark matter called the \textit{color-flavor-locked} (CFL) phase in the background of energy-momentum squared gravity (EMSG). Theoretical and experimental investigations show that strange quark matter (SQM) in a CFL state can be the true ground state of hadronic matter at least for asymptotic densities, and even if the unequal quark masses. Motivated by these theoretical models, we explore the structure of stellar objects in recently proposed EMSG, which allows a correction term $T_{\mu \nu}T^{\mu \nu}$ in the action functional of the theory. Interestingly, EMSG may be effective to resolve the problems at high energy densities, e.g., relevant to the early universe and dense compact astrophysical objects without invoking some new forms of fluid stress, such as bulk viscosity or scalar fields. Finally, we solve the complicated field equations numerically to obtain the mass-radius relations for strange stars in CFL equation of state., Comment: 7 pages, 7 figures; accepted for publication in Phys.Dark Univ

Published

2020

30. Tolman IV fluid sphere in bigravity

Author

Singh, Ksh. Newton, Sarkar, Susmita, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

We present Tolman IV spacetime representing compact fluid sphere in bigravity. Here we have explored the effect of scale parameter $k$ in the local matter distribution of compact stars. We have model for three well-known compact stars and it shows that for lower values of $k$ leads to stiffer EoS. This claim is also supported by the graphical analysis. It can be observed that the sound speed and the adiabatic index are more for lower values of $k$. It is also seen that all the solutions of Einstein's field equations are still satisfying the field equations in the presence of a background metric $\gamma_{\mu \nu}$. However, the density and pressure does modified by extra term from the constant curvature background, thus affecting the EoS. One can also think that the parameter $\alpha \equiv 1/k^2$ as coupling constant between the $g_{\mu \nu}$ and $\gamma_{\mu \nu}$ and consequently more the coupling stiffer is the EoS. As $k\rightarrow \infty$, the background de-Sitter spacetime reduces to Minkowski's spacetime and the coupling vanishes. The solution satisfy the causality condition, all the energy conditions and equilibrium under gravity and hydrostatic forces. The stability of the local stellar structure is enhanced by reducing the scalar curvature of the background spacetime., Comment: 9 Pages, 11 Figs., 2 Tables (Published as Eur. Phys. J. Plus 135, 484 (2020))

Published

2020

31. Compact stars with exotic matter

Author

Singh, Ksh. Newton, Ali, Amna, Rahaman, Farook, and Nasri, Salah

Subjects

General Relativity and Quantum Cosmology

Abstract

In this paper we employ Tolman VII solution with exotic matter that may be present in the extremely dense core of compact objects. The Tolman VII solution, an exact analytic solution to the spherically symmetric, static Einstein field equations with a perfect fluid source, has many characteristics that make it interesting for modeling high density stellar astronomical objects. For our purpose we use generalized non-linear equation of state which may incorporate exotic matter along with dust, radiation and dark energy. The equation of state (EoS) has a linear contribution comprising quark/radiation matters and a nonlinear contribution comprising dark energy/exotic matters. The amount of exotic matter contain can be modify by a parameter $n$ which can be linked to adiabatic index. As $n$ increases the exotic contribution increases which stiffens the EoS. The physical properties of the model such as pressure, density, mass function, surface redshift, gravitational redshift are examined and the stability of the stellar configuration is discussed in details. The model has promising features as it satisfies all energy conditions and is free from central singularities. The $M-R$ relation is constructed analytically and the maximum mass and its corresponding radius is determined using the exact solutions and is shown to satisfy various observational stellar compact stars., Comment: 9 Pages, 14 Figs. Accepted in Physics of Dark Universe

Published

2020

32. Singularity-free nonexotic compact star in $f(R,T)$ gravity

Author

Yadav, Anil Kumar, Mondal, Monimala, and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

In the present work, we have searched the existence of anisotropic and non-singular compact star in the $f(R,T)$ gravity by taking into account the non-exotic equation of state (EoS). In order to obtain the solutions of the matter content of compact object, we assume the well known barotropic form of EoS that yields the linear relation between pressures and energy density. We propose the existence of non-exotic compact star which shows the validation of energy conditions and stability with in the $f(R,T)$ extended theory of gravity perspective. The linear material correction in the extended theory the matter content of compact star remarkably able to satisfies energy condition. We discuss various physical features of compact star and show that proposed model of stellar object satisfies all regularity conditions and is stable as well as singularity-free., Comment: 12 pages, 2 tables, 8 figures. Accepted in Pramana, J. of Phys

Published

2020

33. Study of gravastars under $f(\mathbb{T})$ gravity

Author

Das, Amit, Ghosh, Shounak, Deb, Debabrata, Rahaman, Farook, and Ray, Saibal

Subjects

General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

In the present paper we propose a stellar model under the $f(\mathbb{T})$ gravity following the conjecture of Mazur-Mottola~[Report number: LA-UR-01-5067 (2001); Proc. Natl. Acad. Sci. USA 101 (2004) 9545] known in literature as {\it gravastar}, a viable alternative to the black hole. This gravastar has three different regions, viz., (A) Interior core region, (B) Intermediate thin shell, and (C) Exterior spherical region. It is assumed that in the interior region the fluid pressure is equal to a negative matter-energy density providing a constant repulsive force over the spherical thin shell. This shell at the intermediate region is assumed to be formed by a fluid of ultrarelativistic plasma and the pressure, which is directly proportional to the matter-energy density according to Zeldovich's conjecture of stiff fluid~[Zeldovich, Mon. Not. R. Astron. Soc. 160 (1972) 1], does nullify the repulsive force exerted by the interior core region for a stable configuration. On the other hand, the exterior spherical region can be described by the exterior Schwarzschild-de Sitter solution. With all these specifications we have found out a set of exact and singularity-free solutions of the gravastar which presents several physically interesting as well as valid features within the framework of alternative gravity., Comment: 26 pages, 4 figures, Accepted in Nuclear Physics B

Published

2020

34. Exploring physical properties of compact stars in $f(R,T)-$gravity: An embedding approach

Author

Singh, Ksh. Newton, Errehymy, Abdelghani, Rahaman, Farook, and Daoud, Mohammed

Subjects

General Relativity and Quantum Cosmology

Abstract

Solving field equations exactly in $f(R,T)$ gravity is one of the difficult task. To do so, many authors have adopted different methods such as assuming both the metric functions, an equation of state (EoS) and a metric function etc. However, such methods may not always lead to well-behaved solutions and thereby rejection of the solutions may happen after complete calculations. Indeed, very recent works on embedding class one methods suggested that the chances of arriving at the well behaved-solution is very high thereby inspired us to used it. In class one approach, we have to ansatz one of the metric potentials and the other can be obtain from the Karmarkar condition. In this paper, we are proposing new class one solution which is well-behaved in all physical points of view. We have analyzed the nature of the solution by tuning the $f(R,T)-$coupling parameter $\chi$ and found that the solution results into stiffer EoS for $\chi=-1$ than $\chi=1$. This is because for lesser values of $\chi$, velocity of sound is more, higher $M_{max}$ in $M-R$ curve and the EoS parameter $\omega$ is larger. The solution satisfy the causality condition, energy conditions, stable and static under radial perturbations (static stability criterion) and in equilibrium (modified TOV-equation). The resulting $M-R$ diagram from this solution is well fitted with observed values of few compact stars such as PSR J1614-2230, Vela X-1, Cen X-3 and SAX J1808.4-3658. Therefore, for different values of $\chi$, we have predicted the corresponding radii and their respective moment of inertia from the $M-I$ curve., Comment: 26 Pages, 14 figures

Published

2020

35. Subatomic particle as the quantum universe

Author

De, S S, Rahaman, Farook, and Mapdar, Antara

Subjects

Physics - General Physics

Abstract

Wheeler-Dewitt equation for the wave function of the universe appeared long ago in an approach to quantization of gravity. Presently, the universe considered as the microuniverse, very tiny universe compared to the outer universe to which it belongs. This tiny universe is, thus, supposed to be the subatomic particle (elementary particle) in the universe we live in. It is possible here to convert the wave function of this microuniverse satisfying Wheeler-Dewitt equation into the wave function of the quantum (subatomic) particle, which is shown to satisfy Schr\"{o}dinger equation. The inverse of the length scale indicating smallness of the particle appears in the Schr\"{o}dinger equation being the mass of the particle. Thus, the subatomic particles are shown here to be the quantum universes., Comment: 8 pages. Comments are welcome

Published

2020

36. Conformally symmetric traversable wormholes in modified teleparallel gravity

Author

Singh, Ksh. Newton, Banerjee, Ayan, Rahaman, Farook, and Jasim, M. K.

Subjects

General Relativity and Quantum Cosmology

Abstract

In this paper, we consider wormhole geometries in the context of teleparallel equivalent of general relativity (TEGR) as well as $f(T)$ gravity. The TEGR is an alternative geometrical formulation of Einstein's general relativity, where modified teleparallel gravity or $f(T)$ gravity has been invoked as an alternative approach for explaining an accelerated expansion of the universe. We present the analytical solutions under the assumption of spherical symmetry and the existence of a conformal Killing vectors to proceed a more systematic approach in searching for exact wormhole solutions. More preciously, the existence of a conformal symmetry places restrictions on the model. Considering the field equations with a diagonal tetrad and anisotropic distribution of the fluid, we study the properties of traversable wormholes in TEGR that violates the weak and the null energy conditions at the throat and its vicinity. In the second part, wormhole solutions are constructed in the framework of $f(T)$ gravity, where $T$ represents torsion scalar. As a consistency check, we also discuss the behavior of energy conditions with a viable power-law $f(T)$ model and the corresponding shape functions. In addition, a wide variety of solutions are deduced by considering a linear equation of state relating the density and pressure, for the isotropic and anisotropic pressure, independently of the shape functions, and various phantom wormhole geometries are explored., Comment: 15 pages, 25 figure; accepted for publication in Physical Review D

Published

2020

37. Neutron star under homotopy perturbation method

Author

Aziz, Abdul, Ray, Saibal, Rahaman, Farook, and Guha, B. K.

Subjects

General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

We obtain a mass function solving the Tolman-Oppenheimer-Volkoff (TOV) equation for isotropic and spherically symmetric system via homotopy perturbation method (HPM). Using the mass function we construct a stellar model which can be determined from the equation of state (EOS) parameter ($\omega$) and a model parameter ($n$). With the help of Einstein field equations we develop three solutions which can describe different properties and the core-crust structure of neutron star (NS). Solution I is valid for NS having the inner and outer radius near the surface of the star. The star is physical up to the inner radius whereas negative density occurs and the energy conditions are violated in the upper region from the inner to outer radius. Solution II represents NS with high gravitational redshift as well as compactification factor. All the features of NS can be given by solution III which involves only the EOS parameter. Our model predicts maximum mass for a NS with the central density $5.5\times10^{15}~g/cm^{3}$ and surface redshift 0.69 is to be $2.01~M_\odot$ for the EOS parameter $\omega=0.73$. The predicted range for the surface redshift is $0.57

Published

2019

38. Einstein's cluster mimicking compact star in the teleparallel equivalent of general relativity

Author

Singh, Ksh. Newton, Rahaman, Farook, and Banerjee, Ayan

Subjects

General Relativity and Quantum Cosmology

Abstract

We present a physically plausible solution representing Einstein's cluster mimicking the behaviors of compact star in the context of teleparallel equivalent of general relativity. The Teleparallel gravity (TEGR) is an alternative formulation of gravity which uses tetrads as the dynamical variables. We focus on two particularly interesting scenarios. First, we develop the Einstein clusters in TEGR field equations using effective energy-momentum tensor for diagonal as well as off-diagonal tetrad. We then study the clusters in modified $f(T)-$gravity for anisotropic fluid distribution. Based on these two theories, we further study the solution without net electric charge and then for charged solution. For charge parameter $k \rightarrow 0$, the charged solution reduces to neutral one. Our calculations show that when charge increases, the stiffness of the EoS also increases. This is due to increase in adiabatic index and sound speed approaching speed of light. When the charge increase beyond a certain limit ($0\le k \le 1.3 \times 10^{-5}$ and $0\le k \le 1 \times 10^{-6}$), the compactness parameter crosses the Buchdahl limit i.e. $2M/R>8/9$ and the solution start violating the causality condition. We test the Tolman-Oppenheimer-Volkoff (TOV) limit for such compact objects. We analyze the static stability criterion of the Einstein clusters for both charged and uncharged case, and the stability of such compact objects is enhanced by the presence some net electric charge. Finally, we compare our solution for pure general relativity. As a result, we concluded that the Einstein cluster solution do exist in pure GR, however, physically unfit to mimic compact stars. We have also extend our findings by assuming the diagonal or off-diagonal tetrad and specific case of $f(T)$. In such models, Einstein's cluster solutions do exist however can't mimic the properties of a compact star., Comment: 15 pages, 21 figures. Accepted in Phys.Rev.D

Published

2019

39. Conformally symmetric traversable wormholes in $f(R,T)$ gravity

Author

Banerjee, Ayan, Singh, Ksh. Newton, Jasim, M. K., and Rahaman, Farook

Subjects

General Relativity and Quantum Cosmology

Abstract

To find more deliberate $f(R, T)$ astrophysical solutions, we proceed by studying wormhole geometries under the assumption of spherical symmetry and the existence of a conformal Killing symmetry to attain the more acceptable astrophysical results. To do this, we consider a more plausible and simple model $f(R,T)=R+2\chi T$, where $R$ is the Ricci scalar and $T= -\rho+p_r+2p_t$ denotes the trace of the energy-momentum tensor of the matter content. We explore and analyze two cases separately. In the first part, wormhole solutions are constructed for the matter sources with isotropic pressure. However, the obtained solution does not satisfy the required wormhole conditions. In the second part, we introduce an EoS relating with pressure (radial and lateral) and density. We constrain the models with phantom energy EoS i.e. $\omega= p_r/ \rho < -1$, consequently violating the null energy condition. Next, we analyze the model via $p_t= n p_r $. Several physical properties and characteristics of these solutions are investigated which are consistent with previous references about wormholes. We mainly focus on energy conditions (NEC, WEC and SEC) and consequently for supporting the respective wormhole geometries in details. In both cases it is found that the energy density is positive as seen by any static observer. To support the theoretical results, we also plotted several figures for different parameter values of the model that helps us to confirm the predictions. Finally, the volume integral quantifier, which provides useful information about the total amount of exotic matter required to maintain a traversable wormhole is discussed briefly., Comment: 10 pages and 9 figures, version published in Annals of Physics: comments added and typos fixed

Published

2019

40. Noncommutative black hole in the Finslerian spacetime

Author

Chowdhury, Sourav Roy, Deb, Debabrata, Rahaman, Farook, Ray, Saibal, and Guha, B. K.

Subjects

Physics - General Physics

Abstract

We study the behavior of the noncommutative radiating Schwarzschild black hole in the Finslerian spacetime. The investigation shows that black hole possesses either (i) two horizons, or (ii) a single horizon, or (iii) no horizon corresponding to a minimal mass. We obtain that the minimal mass significantly changes with the Finslerian parameter, keeping minimal horizon remain unchanged. It turns out that under Finslerian spacetime, the maximum temperature before cooling down to absolute zero varies with Finslerian parameter. We then study the stability of the black hole by analyzing the specific heat and free energy. The energy conditions, their violation limit also scrutinized. Our findings suggest a stable black hole remnant, whose mass and size are uniquely determined in terms of the Finslerian parameter $\overline{Ric}$ and noncommutative parameter $\theta$. The physical relevance of these results are discussed in a brief., Comment: 8 pages, 9 figures

Published

2019

41. Constraining values of bag constant for strange star candidates

Author

Aziz, Abdul, Ray, Saibal, Rahaman, Farook, Khlopov, M., and Guha, B. K.

Subjects

General Relativity and Quantum Cosmology

Abstract

We provide a strange star model under the framework of general relativity by using a general linear equation of state (EOS). The solution set thus obtained is employed on altogether 20 compact star candidates to constraint values of MIT bag model. No specific value of the bag constant ($B$) a-priori is assumed rather possible range of values for bag constant is determined from observational data of the said set of compact stars. To do so the Tolman-Oppenheimer-Volkoff (TOV) equation is solved by homotopy perturbation method (HPM) and hence we get a mass function for the stellar system. The solution to the Einstein field equations represents a non-singular, causal and stable stellar structure which can be related to strange stars. Eventually we get an interesting result on the range of the bag constant as 41.58~MeV~fm$^{-3}< B <$319.31~MeV~fm$^{-3}$. We have found the maximum surface redshift $Z^{max}_{s}=0.63$ and shown that the central redshift ($Z_c$) can not have value larger than $2k$, where $k=2.010789 \pm 0.073203$. Also we provide a possible value of bag constant for neutron star (NS) with quark core using hadronic as well as quark EOS., Comment: 22 pages, 6 figures, 2 tables

Published

2019

42. Possible formation of wormholes from dark matter in an isothermal galactic halo and void

Author

Sarkar, Nayan, Sarkar, Susmita, Rahaman, Farook, Kuhfittig, P. K. F., and Khadekar, G S

Subjects

Physics - General Physics

Abstract

It is well known that traversable wormholes are valid solutions of the Einstein field equations, but these structures can only be maintained by violating the null energy condition. In this paper, we have obtained such wormhole solutions in an isothermal galactic halo, as well as in a void. We have shown that the null energy condition is violated, with the help of a suitable redshift function obtained from flat galactic rotation curves., Comment: 7 pages, 10 figures. Accepted in Mod.Phys.Lett.A

Published

2019

43. A generalized Finch-Skea class one static solution

Author

Singh, K. N., Maurya, S. K., Rahaman, Farook, and Tello-Ortiz, Francisco

Subjects

Physics - General Physics

Abstract

In the present article, we discuss relativistic anisotropic solutions of the Einstein field equation for the spherically symmetric line element under the class I condition. To do so we apply the embedding class one technique using Eisland condition. Within this approach, one arrives at a particular differential equation that links the two metric components $e^{\nu}$ and $e^{\lambda}$. In order to obtain the full space-time description inside the stellar configuration we ansatz the generalized form of metric component $g_{rr}$ corresponding to the Finch-Skea solution. Once the space-time geometry is specified we obtain the complete thermodynamic description i.e. the matter density $\rho$, the radial, and tangential pressures $p_r$ and $p_t$, respectively. Graphical analysis shows that the obtained model respects the physical and mathematical requirements that all ultra-high dense collapsed structures must obey. The $M-R$ diagram suggests that the solution yields stiffer EoS as parameter $n$ increases. The $M-I$ graph is in agreement with the concepts of Bejgar et al. \cite{bej} that the mass at $I_{max}$ is lesser by few percent (for this solution $\sim 3\%$) from $M_{max}$. This suggests that the EoSs is without any strong high-density softening due to hyperonization or phase transition to an exotic state., Comment: 14 figures, Accepted in European Physical Journal C

Published

2019

44. Anisotropic strange star in Finsler geometry

Author

Chowdhury, Sourav Roy, Deb, Debabrata, Rahaman, Farook, Ray, Saibal, and Guha, B. K.

Subjects

General Relativity and Quantum Cosmology

Abstract

In the present paper, we report on a study of the anisotropic strange stars under Finsler geometry. Keeping in mind that Finsler spacetime is not merely a generalization of Riemannian geometry rather the main idea is the projectivized tangent bundle of the manifold $\mathpzc{M}$, we have developed the respective field equations. Thereafter, we consider the strange quark distribution inside the stellar system followed by the MIT bag model equation of state (EOS). To find out the stability and also the physical acceptability of the stellar configuration, we perform in detail some basic physical tests of the proposed model. The results of the testing show that the system is consistent with the Tolman-Oppenheimer-Volkoff (TOV) equation, Herrera cracking concept, different energy conditions and adiabatic index. One important result that we observe is that the anisotropic stress reaches to the maximum at the surface of the stellar configuration. We calculate (i) the maximum mass as well as corresponding radius, (ii) the central density of the strange stars for finite values of bag constant $B_g$ and (iii) the fractional binding energy of the system. This study shows that Finsler geometry is especially suitable to explain massive stellar systems., Comment: 15 pages, 17 figures

Published

2019

45. Charged anisotropic strange stars in Finslerian geometry

Author

Chowdhury, Sourav Roy, Deb, Debabrata, Ray, Saibal, Rahaman, Farook, and Guha, B. K.

Subjects

General Relativity and Quantum Cosmology

Abstract

We investigate a simplified model for the strange stars in the framework of Finslerian spacetime geometry, composed of charged fluid. It is considered that the fluid consisting of three flavor quarks including a small amount of non-interacting electrons to maintain the chemical equilibrium and assumed that the fluid is compressible by nature. To obtain the simplified form of charged strange star we considered constant flag curvature. Based on geometry, we have developed the field equations within the localized charge distribution. We considered that the strange quarks distributed within the stellar system are compiled with the MIT bag model type of equation of state (EOS) and the charge distribution within the system follows a power law. We represent the exterior spacetime by the Finslerian Ressiner-Nordstr{\"o}m space-time. The maximum anisotropic stress is obtained at the surface of the system. Whether the system is in equilibrium or not, has been examined with respect to the Tolman-Oppenheimer-Volkoff (TOV) equation, Herrera cracking concept, different energy conditions and adiabatic index. We obtain that the total charge is of the order of 10$^{20}$ C and the corresponding electric field is of around 10$^{22}$ V/m. The central density and central pressure vary inversely with the charge. Varying the free parameter (charge constant) of the model, we find the generalized mass-radius variation of strange stars and determine the maximum limited mass with the corresponding radius. Furthermore, we also considered the variation of mass and radius against central density respectively., Comment: 21 pages, 13 figures, 4 tables

Published

2019

46. Generating functions of wormholes

Author

Rahaman, Farook, Sarkar, Susmita, Singh, Ksh. Newton, and Pant, Neeraj

Subjects

Physics - General Physics

Abstract

It is known that wormhole geometry could be found solving the Einstein field equations by tolerating the violation of null energy condition (NEC). Violation of NEC is not possible for the physical matter distributions, however, can be achieved by considering distributions of "exotic matter". The main purpose of this work is to find generating functions comprising the wormhole like geometry and discuss the nature of these generating functions. We have used the Herrera et al. \cite{1} approaches of obtaining generating functions in the background of wormhole spacetime. Here we have adopt two approaches of solving the field equations to find wormhole geometry. In the first method, we have assumed the redshift function $f(r)$ and the shape function $b(r)$ and solve for the generating functions. In an another attempt we assume generating functions and redshift functions and then try to find shape functions of the wormholes., Comment: 12 pages, 12 figures. To appear in Mod.Phys.Lett.A

Published

2019

47. Traversable wormholes supported by dark matter and monopoles with semiclassical effects

Author

Rahaman, Farook, Samanta, Bidisha, Sarkar, Nayan, Raychaudhuri, Biplab, and Sen, Banashree

Published

2023

48. The Finslerian quantum cosmology

Author

De, S S, Rahaman, Farook, and Paul, Nupur

Subjects

Physics - General Physics

Abstract

We present a Friedmann-Robertson-Walker (FRW) quantum cosmological model within the framework of Finslerian geometry. In this work, we consider a specific fluid. We obtain the corresponding Wheeler-DeWitt equation as the usual constraint equation as well as Schr\"odinger equation following Dirac, although the approaches yields the same equation of time independent equation for the wave function of the universe. We provide exact classical and quantum mechanical solutions. We use the eigenfunctions to study the time evolution of the expectation value of the scale factor. Finally we discuss the physical meaning of the results., Comment: To appear in Can.J.Phys

Published

2018

49. Black holes/naked singularities in four-dimensional non-static space-time and the energy-momentum distributions

Author

Ahmed, Faizuddin, Rahaman, Farook, and Sarkar, Susmita

Subjects

General Relativity and Quantum Cosmology

Abstract

In this article, we discuss four dimensional non-static space-times in the background of de-Sitter and anti-de Sitter spaces with the matter-energy sources a stiff fluid, anisotropic fluid, and an electromagnetic field. Under various parameter conditions the solutions may represent models of naked singularity and/or black holes. Finally, the energy-momentum distributions using the complexes of Landau-Lifshitz, Einstein, Papapetrou, and M{\o}ller prescriptions, were evaluated., Comment: 18 pages, 6 figures. Accepted in EPJA. arXiv admin note: text overlap with arXiv:gr-qc/0309002 by other authors

Published

2018

50. Evolving wormhole geometry from dark matter energy density

Author

Rahaman, Farook, primary and Choudhury, Bikramarka S., additional

Published

2024