Thermodynamics and logarithmic corrections of symmergent black holes
Riasat Ali, Rimsha Babar, Zunaira Akhtar, Ali \"Ovg\"un

TL;DR
This paper investigates quantum gravity effects on symmergent black holes derived from quadratic-curvature gravity, analyzing thermodynamics, stability, and the impact of thermal fluctuations with logarithmic entropy corrections.
Contribution
It introduces a detailed analysis of quantum gravity effects on symmergent black holes, including thermodynamic properties and stability under thermal fluctuations with logarithmic corrections.
Findings
Logarithmic corrections improve black hole stability.
Quantum gravity influences thermodynamic behavior.
Thermal fluctuations affect entropy and stability.
Abstract
In this paper, we study quantum gravity effect on the symmergent black hole which is derived from quadratic-curvature gravity. To do so, we use the Klein-Gordon equation which is modified by generalized uncertainty principle (GUP). After solving the field equations, we examine the symmergent black hole's tunneling and Hawking temperature. We explore the graphs of the temperature through the outer horizon to check the GUP influenced conditions of symmergent black hole stability. We also explain how symmergent black holes behave physically when influenced by quantum gravity. The impacts of thermal fluctuations on the thermodynamics of a symmergent black holes spacetime are examined. We first evaluate the model under consideration's thermodynamic properties, such as its Hawking temperature, angular velocity, entropy, and electric potential. We evaluate the logarithmic correction terms for…
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Thermodynamics and logarithmic corrections of symmergent black holes
Riasat Ali
Department of Mathematics, GC University Faisalabad Layyah Campus, Layyah-31200, Pakistan
Rimsha Babar
Division of Science and Technology, University of Education, Township, Lahore 54590, Pakistan
Zunaira Akhtar
Division of Science and Technology, University of Education, Township, Lahore 54590, Pakistan
Ali Övgün
[email protected] https://www.aovgun.com Physics Department, Eastern Mediterranean University, Famagusta, 99628 North Cyprus via Mersin 10, Turkey
Abstract
In this paper, we study quantum gravity effect on the symmergent black hole which is derived from quadratic-curvature gravity. To do so, we use the Klein-Gordon equation which is modified by generalized uncertainty principle (GUP). After solving the field equations, we examine the symmergent black hole’s tunneling and Hawking temperature. We explore the graphs of the temperature through the outer horizon to check the GUP influenced conditions of symmergent black hole stability. We also explain how symmergent black holes behave physically when influenced by quantum gravity. The impacts of thermal fluctuations on the thermodynamics of a symmergent black holes spacetime are examined. We first evaluate the model under consideration’s thermodynamic properties, such as its Hawking temperature, angular velocity, entropy, and electric potential. We evaluate the logarithmic correction terms for entropy around the equilibrium state in order to examine the impacts of thermal fluctuations. In the presence of these correction terms, we also examine the viability of the first law of thermodynamics. Finally, we evaluate the system’s stability using the Hessian matrix and heat capacity. It is determined that a stable model is generated by logarithmic corrections arising from thermal fluctuations.
Black hole; Symmergent gravity; Modified Lagrangian Equation; Hawking Radiation; Quantum Tunneling; WKB method. First order correction of thermodynamics
pacs:
95.30.Sf, 04.70.-s, 97.60.Lf, 04.50.Kd
I Introduction
Hawking radiation describes hypothetical particles created near a black hole’s (BHs) event horizon. By combined models of general relativity and quantum mechanics, Hawking showed that BHs are not actually black, because of the emission of a nearly thermal radiation. This radiation implies BHs have temperatures that are inversely proportional to their mass. One can say that smaller BH is hotter. It is supposed that this radiation causes them to lose energy, shrink and eventually disappear which causes the unsolved information lost problem. There are some proposals to solve this information problem. One of them is proposed by Hawking, Perry and Strominger by defining new term in physics ‘soft particles’ S. W. Hawking, M. J. Perry and A. Strominger (2016). There are many ways to derive Hawking radiation and calculate its temperature. The most popular one is the the semi-classical quantum tunneling strategy introduced in M. Angheben, M. Nadalini, L. Vanzo and S. Zerbini (2005). In the tunneling phenomenon, there are two famous techniques to derive the tunneling rates. One is Parikh-Wilczek technique that consider the null geodesic equation of the radiated vector particles P. Kraus and F. Wilczek (1995). The other way is Hamilton-Jacobi approach proposed in literature W. Javed, R. Ali, R. Babar and A. Övgün (2019); A. Övgün, W. Javed and R. Ali (2018); W. Javed, G. Abbas and R. Ali (2017); W. Javed, R. Ali and G. Abbas (2019); W. Javed, R. Ali, R. Babar and A. Övgün (2020); W. Javed and R. Babar (2019); W. Javed, R. Babar and A. Övgün (2019); R. Babar, W. Javed and A. Övgün (2020); Kerner and Mann (2008a, 2006, b, 2007); Kuang et al. (2018, 2017); Akhmedov et al. (2006); Akhmedova et al. (2008); Akhmedov et al. (2007); Singleton et al. (2010); Kruglov (2014); Ali (2007, 2008); Singh et al. (2019); Ibungochouba Singh et al. (2016a, b); Singh et al. (2017); Meitei et al. (2020). The tunneling probability can be derived S. Shahraeini and Saghaf. (2022) from the following formula
[TABLE]
The Hawking temperature for all types of particles can be calculated by using the above tunneling formula. In various types of theories of quantum gravity (e.g., non-commutative geometry, loop quantum gravity and string theory), the main feature is the presence of a minimal noticeable length A. Kempf (1997); B. Carr, J. Mureika and P. Nicolini (2015). In order to study this minimal length, the generalized Uncertainty Principle (GUP) is the most appropriate way A. Kempf, G. Mangano and R. B. Mann (1995). The modified commutation relationship is defined as
[TABLE]
whereas and stands for generalized momentum and position operators. Furthermore, a relation with GUP can be given in the form
[TABLE]
here the correction parameter can be expressed in terms of dimensionless parameter as and denotes the Planck’s mass. The GUP association is very helpful to understand the BH physics and the quantum effects have a great influence near the horizon of a BH. Gecim and Sucu G. Gecim and Y. Sucu (2018a, 2017, b) have studied the gravity effects incorporating GUP for -dimensional Warped-, Martinez-Zanelli and New-Type of BHs. Övgün et al. A. Övgün and K. Jusufi (2016, 2017); K. Jusufi and A. Övgün (2017) have investigated the gravity impacts via GUP in the background of tunneling method for the noncommutative Reissner-Nordström, warped DGP gravity and 5D Myers-Perry BHs and derived the temperature for corresponding BHs. Moreover, the BH thermodynamics plays a very significant role in order to study the BH physics. The four laws of thermodynamics of BH and their relation with gravity have been investigated by Bardeen and his fellows J. M. Bardeen, B. Carter and S. W. Hawking (1973). In order to study the thermodynamics of BH, one associates entropy with Bekenstein’s area whereas the temperature can be calculated through first law of thermodynamics S. W. Hawking, D. N. Page (1983); J. D. Bekenstein (1973). Many important features of BH e.g., stable and unstable form, holographic duality, criticality and many numerous critical perspective can be studied through corrected thermodynamics of BH. In order to study the physics of BHs, the quantum corrected fluctuations in BH thermodynamics have acquired a noteworthy place. Pourhassan et al B. Pourhassan and M. Faizal (2015); B.Pourhassan, S.Upadhyay, H.Saadat and H.Farahani (2018); B.Pourhassan and M. Faizal (2016) have computed the logarithmic correction impacts of thermal fluctuations for a charged anti-de Sitter BH, Horava-Lifshitz BH and Kerr-AdS BH. Faizal and Khalil M. Faizal and M. M. Khalil (2015) have investigated the GUP corrected entropy corrections for Reissner-Nordström, Kerr, charged AdS BHs as well as rotating BHs. They have also analyzed their remnant. The logarithmic corrected entropy has been investigated for Godel BH as well as by using Cardy formula R. K. Kaul, P. Majumdar (2000); S. Carlip (2000). Considering 1st-order corrections to temperature and entropy of Kerr-Newman-anti-de Sitter BHs and Reissner-Nordstrom-anti-de Sitter BH impacts from the corrected temperature and entropy on thermodynamical quantities like enthalpy, internal energy, Gibbs free energy and Helmholtz energy have been examined Zhang (2018). Thermal fluctuations’ effects on modified Hayward BHs thermodynamics have been investigated. It has been determined B. Pourhassan, M. Faizal and U. Debnath (2016) how these correction terms for the first law of thermodynamics will affect thermodynamic properties such as inner energy, entropy, pressure, and specific heat Bargueño et al. (2021).
The motivations of our study is to analyze the Hawking temperature under the impacts of quantum gravity as well as logarithmic corrections via thermodynamics of symmergent BH. Symmergent black hole is derived from a quadratic-curvature gravity which is a subclass of gravity theories Demir (2021, 2019, 2016); Çimdiker et al. (2021); Rayimbaev et al. (2022). To compute rate of probability and the corresponding Hawking temperature, we utilize the Hamilton-Jacobi strategy associated with generalized Proca equation for boson radiated particles. After computing the corrected temperature, we graphically discuss the stable states of symmergent BH. Moreover, by utilizing the thermal fluctuations, we study the logarithmic corrections and their graphical interpretation.
The remaining part of this paper is organized as follows. In Section II, we briefly review the symmergent BHs. In Section III, we compute the corrected temperature of symmergent BH by utilizing the tunneling approach. Section IV, explains the physical significance and stable states of symmergent BH in the background of graphical representation of corrected temperature with horizon. In Section V, we investigates the logarithmic corrections under thermal fluctuations with the help of graphs. We conclude our findings in Section VI.
II Symmergent Black hole
In general, the symmergent gravity is a gravity theory that relates with theory and it is associated with gravity theories as a special case. The complete details about symmergent gravity theory can be studied in Demir (2021, 2019, 2016). The solution of symmergent black hole was found by Çimdiker, Övgün and Demir in Çimdiker et al. (2021) . Afterwards, the implications of this theory has been investigated in Rayimbaev et al. (2022); Pantig et al. (2022) for black features e.g., weak lensing, shadow radius, quasi-periodic and oscillations. The spacetime metric for the symmergent black hole is given by Çimdiker et al. (2021)
[TABLE]
with the lapse function
[TABLE]
where is an integration constant and the symmergent parameter (loop coefficient) is defined as
[TABLE]
in which / are for the total number of bosons/fermions in the underlying QFT. The above metric function reaches to the Schwarzschild BH space-time when or . The radius of event horizon for the symmergent BH is calculated by using . In that case we get three horizons but the largest root of event horizon can be calculated as Çimdiker et al. (2021)
[TABLE]
with
[TABLE]
where , and the BH mass can be represented in terms of the horizon, despite its complicated functional form. In order to get more details about the horizon properties check Rayimbaev et al. (2022).
The Hawking temperature of a symmergent BH is calculated as follows
[TABLE]
The Bekenstein-Hawking entropy Bekenstein (1973); Brevik et al. (2004); Çimdiker et al. (2021) is given by
[TABLE]
which is independent of . The next section analyzes the particle tunneling from the symmergent BH solution using the WKB approximation method.
III Particle tunnel from the symmergent black hole
We calculate the tunneling rate of the boson particles to investigate the Hawking temperature of a symmergent BH. By using a semi-classical technique, we describe the Hawking temperature. Ali et al. R. Ali and M. Asgher (2022); R. Ali, R. Babar, M. Asgher and S. A. A. Shah (2022, 2021); R. Ali, K. Bamba, S. A. A. Shah and M. J. Saleem (2022); R. Ali, K. Bamba, M. Asgher and S. A. A. Shah (2021); R. Ali, R. Babar, M. Asgher and X. T. Cheng (2022) have investigated the gravity impacts via GUP in the background of tunneling method for the BHs, cosmic strings and 5D black rings and derived the temperature for corresponding BHs. We examine how quantum gravity affects the Hawking temperature in the influence of GUP. According to R. Ali, R. Babar and P. K. Sahoo (2022), the gravity parameter and the BH stability feature are generally connected. The GUP component of the Lagrangian equation’s physical importance is taken into consideration. The field equation without a singularity extended in the form of Lagrangian field equation is the GUP parameter. In order to study the boson radiation phenomena, we utilize the Lagrangian equation of action via vector field .
[TABLE]
here , and represents the coefficient matrix determinant, vector particle mass and anti-symmetric tensor, respectively. Defining the anti-symmetric tensor is
[TABLE]
where and are the Plank’s constant and GUP parameter, respectively. The components of and can be calculated as
[TABLE]
The WKB strategy is given by R. Ali, R. Babar and M. Asgher (2022)
[TABLE]
here, represents the arbitrary functions and is the constant term. After neglecting the higher orders in the Lagrangian equation (11), where the term is only taken into account in the WKB approximation for the order, we arrive at the equation system shown below:
[TABLE]
We take into consideration the idea of variable separation
[TABLE]
where with and indicate the particle angular momentum and energy of particle at angle , respectively. We obtain a matrix of order in the following way by applying the Eq. (17) into Eqs. (13)-(16).
[TABLE]
The specified matrix appears to be non-trivial. The components of it are mentioned below:
[TABLE]
where , and . Considering that the determinant of A is a non-trivial matrix result, set A to zero, which causes the imaginary part to act in the form:
[TABLE]
with
[TABLE]
The Eq. (18) implies
[TABLE]
here indicates the arbitrary parameter. The modified tunneling rate for boson particles can be determined by using the formula:
[TABLE]
where
[TABLE]
The Hawking temperature for symmergent BH under the effect of GUP parameter can be derived by utilizing Boltzmann factor as follows:
[TABLE]
As we can see, the quantum corrections and the BH geometry both have an impact on the corrected Hawking temperature. The zero order correction term is the same as the semi-classical original Hawking term, but the first-order correction term must be smaller than the preceding term while still satisfying GUP. The depends on the BH mass , arbitrary parameter , symmergent gravity parameter , loop parameter and correction parameter . Moreover, after neglecting the gravity parameter into equation (22), we recover the original temperature of symmergent BH in Çimdiker et al. (2021).
IV Graphical Analysis of for symmergent BH
This section analyze the effects of gravity parameter and on for symmergent BH. We investigate the stable condition of symmergent BH under the effects of quantum gravity parameter by fixing the values of arbitrary parameter and symmergent gravity parameter in the regions and .
Figure 1: versus for fixed .
Figure 1: (i) shows the graphical interpretation of with Mass in the domain for constant values of , as well as for different values of correction parameter . One can observe that the temperature exponentially increases with varying mass. The decreases as we increase the values of correction parameter . So, we can say the quantum corrections cause a reduction in the rise of temperature.
(ii) analyze the conduct of versus for various values of arbitrary parameter and constant values of . It can be seen that, the increases with increasing values of with positive temperature. This positive conduct of temperature states the stable condition of BH. The increases with the increasing values of parameter .
Figure 2: versus for fixed and .
Figure 2: (i) depicts the graphical analysis of via in the range for constant values of and changing values of correction parameter . For , the region shows the behavior of temperature when total number of fermions are larger than a total number of bosons while for shows the behavior of temperature when when total number of bosons are larger than a total number of fermions. It is also observable that the decreases for increasing values of in the region whereas it increases for increasing values of in the region .
(ii) describes the conduct of versus for different values of and constant values of . It can be observed that for and , the temperature shows negative behavior while for and , the temperature shows positive decreasing behavior. This type of conduct depicts the physical and stable form of BH. It has also worth mentioning here that, a deceleration in temperature can be observed for negative values of as compared to positive values of .
V Thermal fluctuations
In order to explore the impact of thermal fluctuations S. Upadhyay, N. islam and P. A. Ganai (2022), several thermodynamical potentials of the rotating BTZ BHs have been determined, and the Hawking temperature and corrected entropy are known. In this regard, the system’s leading-order corrected enthalpy energy for small BHs takes on an asymptotic value that corresponds to the correction parameter. They discovered a critical threshold below which the effects of thermal fluctuation are negligible and the logarithmic entropy correction for BTZ like BH, hairy BHs, Schwarzschild BH and Reissner-Nordstrom BH have been studied T. R. Govindarajan, R. K. Kaul and V. Suneeta (2001); J. Sadeghi, B. Pourhassan and F. Rahimi (2014); M.M. Akbar and S. Das (2004). The study of BH thermodynamics is greatly influenced by thermal fluctuations. The idea of Euclidean quantum gravity causes a shift in the temporal coordinates in favor of complex plans. The partition function in terms of density of states is provided Z. Akhtar, R. Babar and R. Ali (2023) as a way to verify the corrected entropy along these thermal fluctuations Gibbons and Hawking (1977); Iyer and Wald (1995)
[TABLE]
where and E is the thermal radiation’s average energy. The equation of density forms under the Laplace inverse transform
[TABLE]
where is known as the corrected entropy of the considered system. Under the steepest decent method, the equation of corrected entropy takes the the following form Das et al. (2002); Sadeghi et al. (2014)
[TABLE]
By using the conditions and , the corrected entropy relation under the first-order corrections has been modified Z. Akhtar, R. Babar and R. Ali (2023) and by neglecting the higher order terms, the exact expression of entropy is expressed as B. Pourhassan and M. Faizal (2015)
[TABLE]
where represents the logarithmic correction parameter. Pourhassan and Faizal have analyzed the effects of thermal fluctuations on a charged AdS black hole by introducing, for the first time, the corrected form of entropy in literature B. Pourhassan and M. Faizal (2015). Then using the Bekenstein-entropy and Hawking temperature into Eq. (26), we get
[TABLE]
.
Figure 3: Corrected entropy with respect to for fixed and and varying .
From Fig. 3, the behaviour of corrected entropy along is monotonically increasing. It is noted that for the graph of usual entropy shows increasing behaviour for small values of , so these logarithmic corrections are more useful for small BHs. With the help of corrected entropy, we can also check behaviour of other thermodynamic quantities in the influence of these corrections. So, the Helmholtz energy () leads to the form
[TABLE]
Figure 4: Helmholtz free energy with respect to for fixed , and varying .
Fig. 4 represents the curve of Helmholtz free energy along . For the different choices of correction parameter, the Helmholtz free energy depicts increasing behaviour, it means that the system under consideration changes state to equilibrium. Moreover, there is another important thermodynamic quantity internal energy () is given as
[TABLE]
Figure 5: Internal energy with respect to for and .
InFig. 5, the curves of internal energy depicts gradually increasing behaviour for the small values of . The corrected internal energy shows increasing behaviour (To sustain its state, the BH must absorb increasing amounts of heat from the environment). Furthermore, Pressure is a further significant thermodynamic quantity. The expression of BH pressure () for these corrections is given as
[TABLE]
Figure 6: Pressure with respect to for and
Fig. 6 shows how closely the pressure graph and the equilibrium state correspond. For various correction parameter values, the pressure dramatically reduces for the considered geometry. Enthalpy () is another significant thermodynamic quantity, is described as
[TABLE]
Figure 7: Enthalpy with respect to for and .
Fig. 7 shows that the usual enthalpy graph eventually downs and then exponentially increases. This implies that exothermic reactions exist and that a significant amount of energy will be released into the environment. Under the effect of thermal fluctuations, the Gibbs free energy () is expressed as
[TABLE]
Figure 8: Gibbs free energy with respect to for and .
Fig. 8 illustrates the graphical analysis of the Gibbs free energy with respect to . Positive energy indicates the presence of non-spontaneous processes, which means this system needs more energy to reach equilibrium. After a thorough analysis of thermodynamic quantities, another crucial idea is the system’s stability as determined by specific heat. The specific heat () is given as
[TABLE]
Figure 9: Specific heat with respect to for and .
Fig. 9 shows the behavior of specific heat with respect to . It is clear that whereas the uncorrected quantity (black) represents the specific heat lower than zero, indicating that the system is unstable, the corrected specific heat exhibits positive behavior across the whole examined area. This plot’s positivity identifies the region of stability. It is evident that the system is stable under the influence of these corrections.
VI Summary and Discussion
In this article, we have computed the corrected Hawking temperature for symmergent BH under the influence of GUP parameter. At first, we have studied about the metric of an exact spherically symmetric BH in the background of an symmergent gravity known as symmergent gravity. The gravity theory develops from quantum loops of the fundamental quantum field theory with the symmergent gravity constant and the loop parameter . In order to study the quantum corrected temperature for symmergent BH, we have used the semi-classical approach, WKB approximation and modified wave equation for spin- particles in the background of GUP. After accompanying the WKB approximation into modified wave equation, we have attained a set of field equations, and by considering the separation of variables strategy, we have derived a matrix of order four by four and after putting the determinant of the matrix equals to zero, we have calculated a non-trivial solution as an imaginary part of the particle action of bosons. We have investigated the tunneling probability and modified temperature for the symmergent BH at horizon by using the Boltzmann factor . It has worth to mention here that the both self-gravitational and back-reaction effects of the spin- particles on this symmergent BH have been neglected and the have been computed as a leading term. The depends on the BH mass , arbitrary parameter , symmergent gravity parameter , loop parameter and correction parameter . Moreover, after neglecting the gravity parameter into equation (22), we recover the original temperature for symmergent BH in Çimdiker et al. (2021).
In order to analyze the gravity effects on the symmergent BH, we have studied the graphical analysis of the corrected Hawking temperature versus mass and loop parameter under the effects of various parameters. We have graphically investigated the physical state and stability of BH under the influence of arbitrary parameter , and quantum gravity parameter . It can be observed that the temperature exponentially increases with varying mass in the region . The decreases with increasing values of correction parameter . So, we conclude that quantum corrections cause a reduction in the rise of temperature. Moreover, we have analyzed the conduct of versus for various values of arbitrary parameter . The increases with increasing values of with positive temperature. The positive conduct of temperature states the stable condition of BH. The increases with the increasing values of parameter .
We have depicted the graphical analysis of via in the range for changing values of correction parameter . For , we have observed the behavior of temperature when total number of fermions are larger than a total number of bosons while for , we have observed the behavior of temperature when the total number of bosons are larger than a total number of fermions. It is also observed that the decreases for increasing values of in the region whereas it increases for increasing values of in the region .
Furthermore, we have analyzed the conduct of versus for different values of . It can be observed that for and , the temperature shows negative behavior while for and , the temperature shows positive decreasing behavior. This type of conduct depicts the physical and stable form of BH. It has also worth to mention here that, a deceleration in temperature can be observed for negative values of as compared to positive values of .
Acknowledgements.
A. Ö. would like to acknowledge the contribution of the COST Action CA18108 - Quantum gravity phenomenology in the multi-messenger approach (QG-MM).
The reference list from the paper itself. Each links out to its DOI / PubMed record.
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