Abstract

This paper discusses the gravitational collapse of dynamical self-gravitating fluid distribution in f ( R , T , Q ) gravity, where Q = R φ ϑ T φ ϑ . In this regard, we assume a charged anisotropic spherical geometry involving dissipation flux and adopt standard model of the form R + Φ T + Ψ Q , where Φ and Ψ symbolize real-valued coupling parameters. The Misner–Sharp as well as Müler–Israel Stewart mechanisms are employed to formulate the corresponding dynamical and transport equations. We then interlink these evolution equations which help to study the impact of state variables, heat dissipation, modified corrections and charge on the collapse rate. The Weyl scalar is further expressed in terms of the modified field equations. The necessary and sufficient condition of conformal flatness of the considered configuration and homogeneous energy density is obtained by applying some constraints on the model along with disappearing charge and anisotropy. Finally, we discuss different cases to investigate how the spherical matter source is affected by the charge and modified corrections. • We discuss the gravitational collapse of dynamical self-gravitating fluid distribution. • We assume a charged anisotropic spherical geometry involving dissipation flux. • The necessary and sufficient condition of conformal flatness and homogeneous energy density is obtained. • We discuss different cases how the spherical matter source is affected by the charge and modified corrections.

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