Abstract
Considering the variable cosmological constant in the extended phase space has a significant background in the black hole physics. It has been shown that the thermodynamic behavior of charged anti--de Sitter black hole surrounded by the quintessence in the extended phase space is similar to the van der Waals fluid. In this paper, we indicate that such a black hole admits the same criticality and van der Waals--like behavior in the nonextended phase space. In other words, we keep the cosmological constant as a fixed parameter, and instead, we consider the normalization factor as a thermodynamic variable. We show that there is a first-order small/large black hole phase transition which is analogous to the liquid/gas phase transition in fluids. We introduce a new picture of the equation of state and then we calculate the corresponding critical quantities. Moreover, we obtain the critical exponents and show that they are the same values as of the van der Waals system. Finally, we study the photon sphere and the shadow observed by a distant observer and investigate how the shadow radius may be affected by the variation of black hole parameters. We also investigate the relations between shadow radius and phase transitions and calculate the critical shadow radius where the black hole undergoes a second-order phase transition.
Highlights
The black hole (BH) is one of the most fascinating and mysterious subjects in the world of physics as well as mathematics
It has been shown that the thermodynamic behavior of charged anti–de Sitter black hole surrounded by the quintessence in the extended phase space is similar to the van der Waals fluid
We studied the analogy of charged anti–de Sitter (AdS) black holes surrounded by quintessence with van der Waals fluid system with a new viewpoint, in which we kept the cosmological constant as a constant parameter and instead allowed the normalization factor to vary as a thermodynamic quantity
Summary
The black hole (BH) is one of the most fascinating and mysterious subjects in the world of physics as well as mathematics. Thermodynamics of charged black holes in the background of an asymptotically AdS spacetime is of particular interest, due to a complete analogy between them and the van der Waals liquid-gas system Such an analogy will be more precise by considering the cosmological constant as a dynamical pressure and its conjugate quantity as a thermodynamic volume in the extended phase space [9]. The number of colors is kept fixed, which requires the variation of Newton’s constant to compensate the variation of the volume of the boundary field theory This shows that one cannot employ such an approach (AdS=CFT correspondence) to investigate the extended thermodynamics of black holes.
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