Charged Strange Star Model with Stringy Quark Matter in Rainbow Gravity

Abstract

This study deals with the formation and evolution of a strange star in the Krori Barua Rainbow spacetime from collapsing charged stringy quark matter. The dynamical variables are explored from the field equations, taking into account the effects of particle's energy on the mass density, pressure, and string tension. The electric field is also computed using the MIT Bag model. The real time data of SAX J1808.4-3658 is used to analyzed the physical properties including gradients, energy conditions, anisotropy, stability, Tolman Oppenheimer Volkoff equation, mass function, compactness, and red-shift. The graphical analysis has been made according to both the theories of rainbow gravity and general relativity. The energy conditions and anisotropy are found to be satisfied, indicating the physical existence of suggested model. Tolman Oppenheimer Volkoff equation is satisfied indicating equilibrium of forces and stability of the compact object. Overall, our model is consistent with the observational information of SAX J1808.4-3658.