Expansion of magnetic neutron stars in an energy (in)dependent spacetime

TL;DR

This paper explores how strong magnetic fields and energy-dependent spacetime, particularly gravity's rainbow, influence neutron star properties, revealing increased maximum mass and radius, and proposing a modified Buchdahl limit with stability considerations.

Contribution

It introduces a novel analysis of magnetic neutron stars within an energy-dependent spacetime framework, including a new upper mass limit and stability conditions using LOCV with AV18 potential.

Findings

Maximum mass and radius increase with magnetic field.

Average density and redshift decrease with magnetic field.

Gravity's rainbow causes neutron star expansion.

Abstract

Regarding the strong magnetic field of neutron stars and high energy regime scenario which is based on high curvature region near the compact objects, one is motivated to study magnetic neutron stars in an energy dependent spacetime. In this paper, we show that such strong magnetic field and energy dependency of spacetime have considerable effects on the properties of neutron stars. We examine the variations of maximum mass and related radius, Schwarzschild radius, average density, gravitational redshift, Kretschmann scalar and Buchdahl theorem due to magnetic field and also energy dependency of metric. First, it will be shown that the maximum mass and radius of neutron stars are increasing function of magnetic field while average density, redshift, the strength of gravity and Kretschmann scalar are decreasing functions of it. These results are due to a repulsive-like force behavior for the magnetic field. Next, the effects of the gravity's rainbow will be studied and it will be shown that by increasing the rainbow function, the neutron stars could enjoy an expansion in their structures. Then, we obtain a new relation for the upper mass limit of a static spherical neutron star with uniform density in gravity's rainbow (Buchdahl limit) in which such upper limit is modified as $M_{eff}<\frac{4c^{2}R}{9G}$. In addition, stability and energy conditions for the equation of state of neutron star matter are also investigated and a comparison with empirical results is done. It is notable that the numerical study in this paper is conducted by using the lowest order constrained variational (LOCV) approach in the presence of magnetic field employing AV18 potential.