Abstract
Abstract The existence of strange matter in compact stars may give rise to striking outcomes of the various physical phenomena. As an alternative to neutron stars, a new class of compact stars called strange stars should exist if the strange matter hypothesis is true. In this paper, we investigate the possible construction of strange stars in quark matter phases based on the MIT bag model. We consider scenarios in which strange stars have no crusts. Then we apply two types of equations of state to quantify the mass–radius diagram for static strange star models, performing the numerical calculation of the modified Tolman–Oppenheimer–Volkoff equations in the context of 4D Einstein–Gauss–Bonnet (EGB) gravity. It is worth noting that the GB term gives rise to a nontrivial contribution to the gravitational dynamics in the limit D → 4. However, the claim that the resulting theory is one of pure gravity has been cast in doubt on several grounds. Thus, we begin our discussion by showing the regularized 4D EGB theory has an equivalent action as the novel 4D EGB in a spherically symmetric spacetime. We also study the effects of coupling constant α on the physical properties of the constructed strange stars including the compactness and criterion of adiabatic stability. Finally, we compare our results to those obtained from standard general relativity.
Highlights
In modern gravity theories, higher derivative gravity (HDG) theories have attracted considerable attention, as an alternative theories beyond GR
We begin our discussion with showing the regularized 4D EGB theory has an equivalent action as the novel 4D EGB in a spherically symmetric spacetime
The EGB theory is a natural extension of GR to higher dimensions, which emerges as a low energy effective action of heterotic string theory (Zwiebach 1985) ( see the extended discussion in Refs. (Wiltshire 1985; Boulware & Deser 1985; Wheeler 1986) for more information)
Summary
Higher derivative gravity (HDG) theories have attracted considerable attention, as an alternative theories beyond GR. In astrophysics, quark matter is an interplay between general relativistic effects and the equation of state of nuclear particle physics. These objects are present in the form of the stellar equilibrium including neutron stars with a quark core, super massive stars, white dwarfs and even strange quark stars. The authors of Ref.(Banerjee & Singh 2020) studied a class of static and spherically symmetric compact objects made of strange matter in the color flavor locked (CFL) phase in 4D EGB gravity. In Sec. we discuss a class of static and spherically symmetric compact objects invoking the equation of state parameters in quark matter phases invoking massless quark and cold star approximations.
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