Xu, M.; Lu, J.; Yang, S.; Jiang, H. Properties of Spherically Symmetric Black Holes in the Generalized Brans–Dicke Modified Gravitational Theory. Entropy2023, 25, 814.
Xu, M.; Lu, J.; Yang, S.; Jiang, H. Properties of Spherically Symmetric Black Holes in the Generalized Brans–Dicke Modified Gravitational Theory. Entropy 2023, 25, 814.
Xu, M.; Lu, J.; Yang, S.; Jiang, H. Properties of Spherically Symmetric Black Holes in the Generalized Brans–Dicke Modified Gravitational Theory. Entropy2023, 25, 814.
Xu, M.; Lu, J.; Yang, S.; Jiang, H. Properties of Spherically Symmetric Black Holes in the Generalized Brans–Dicke Modified Gravitational Theory. Entropy 2023, 25, 814.
Abstract
The many problems faced by the theory of general relativity (GR) have always motivated us to explore the modified theory of GR. Considering the importance of studying the black hole (BH) entropy and its correction in gravity physics, we study the correction of thermodynamic entropy for a kind of spherically symmetric black holes under the generalized Brans-Dicke (GBD) theory of modified gravity. We derive and calculate the entropy and heat capacity. It is found that when the value of event horizon radius~$r_+$~is small, the effect of the entropy correction term on the entropy is very obvious, while for larger values~$r_+$~, the contribution of the correction term on entropy can be almost ignored. In addition, we can observe that as the radius of the event horizon increases, the heat capacity of BH in GBD theory will change from a negative value to a positive value, indicating that there is a phase transition in black holes. Given that studying the structure of geodesic lines is important for exploring the physical characteristics of a strong gravitational field, we also investigate the stability of the geodesic motion of particles in static spherically symmetric BHs within the framework of GBD theory. Concretely, we analyzes the dependence of the innermost stable circular orbit on model parameters. Also, the geodesic deviation equation is also applied to investigate the stable circular orbit of particles in GBD theory. The conditions for the stability of BH solution and the limited range of radial coordinates required to achieve stable circular orbit motion are given. Finally, we show the locations of stable circular orbits, and obtain the angular velocity, the specific energy and angular momentum of the particles which move in circular orbits.
Keywords
generalized Brans-Dicke theory; corrected entropy of black hole; geodesics stability; modified gravity theory
Subject
Physical Sciences, Theoretical Physics
Copyright:
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