Saved in:
Bibliographic Details
Main Authors: Murshid, Masum, Kalam, Mehedi
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2306.13758
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912026136150016
author Murshid, Masum
Kalam, Mehedi
author_facet Murshid, Masum
Kalam, Mehedi
contents In this paper, we study the slowly rotating neutron stars in $f(R, T)$ gravity based on Hartle-Thorne formalism. We first consider the simplest matter-geometry coupled modified gravity, namely $f(R, T)=R+2χT$. We compute the mass, radius, moment of inertia, change in radius, and binding energy due to rotation, eccentricity, quadrupole moment, and the tidal love number. The quantities, which are of the second order in angular velocity, like change in radius and binding energy due to rotation, eccentricity, and quadrupole moment, deviate more from their corresponding general relativistic counterparts in lighter neutron stars than heavier ones. Whereas the moment of inertia, which is of the first order in angular velocity, in $f(R, T)=R+2χT$ modified gravity, barely diverges from the general relativistic one. The Equation of state-independent I-Love-Q relation retains in this $f(R, T) $ modified gravity, and it coincides with the general relativistic ones within less than one percent even for the maximum allowed coupling parameters. We also study the slowly rotating neutron star in $f(R, T)=R+αR^{2}+2χT$ up to first order their angular velocity. We calculate the mass, radius, and moment of inertia of neutron stars in this modified gravity. The results show that the impact of the matter-geometric coupling parameter is greater on lighter neutron stars in both of these modified gravity models.
format Preprint
id arxiv_https___arxiv_org_abs_2306_13758
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Neutron Stars In $f(R,T)$ Theory: Slow Rotation Approximation
Murshid, Masum
Kalam, Mehedi
General Relativity and Quantum Cosmology
In this paper, we study the slowly rotating neutron stars in $f(R, T)$ gravity based on Hartle-Thorne formalism. We first consider the simplest matter-geometry coupled modified gravity, namely $f(R, T)=R+2χT$. We compute the mass, radius, moment of inertia, change in radius, and binding energy due to rotation, eccentricity, quadrupole moment, and the tidal love number. The quantities, which are of the second order in angular velocity, like change in radius and binding energy due to rotation, eccentricity, and quadrupole moment, deviate more from their corresponding general relativistic counterparts in lighter neutron stars than heavier ones. Whereas the moment of inertia, which is of the first order in angular velocity, in $f(R, T)=R+2χT$ modified gravity, barely diverges from the general relativistic one. The Equation of state-independent I-Love-Q relation retains in this $f(R, T) $ modified gravity, and it coincides with the general relativistic ones within less than one percent even for the maximum allowed coupling parameters. We also study the slowly rotating neutron star in $f(R, T)=R+αR^{2}+2χT$ up to first order their angular velocity. We calculate the mass, radius, and moment of inertia of neutron stars in this modified gravity. The results show that the impact of the matter-geometric coupling parameter is greater on lighter neutron stars in both of these modified gravity models.
title Neutron Stars In $f(R,T)$ Theory: Slow Rotation Approximation
topic General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2306.13758