Next Article in Journal
Stable Wormholes in the Background of an Exponential f(R) Gravity
Previous Article in Journal
The Scale-Invariant Vacuum (SIV) Theory: A Possible Origin of Dark Matter and Dark Energy
Previous Article in Special Issue
Investigation of Infrasound Background Noise at Mátra Gravitational and Geophysical Laboratory (MGGL)
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Entropy and Energy of Static Spherically Symmetric Black Hole in f(R) Theory

by
Yaoguang Zheng
1,† and
Rong-Jia Yang
1,2,3,*,†
1
College of Physical Science and Technology, Hebei University, Baoding 071002, China
2
Hebei Key Lab of Optic-Electronic Information and Materials, Hebei University, Baoding 071002, China
3
Key Laboratory of High-pricision Computation and Application of Quantum Field Theory of Hebei Province, Hebei University, Baoding 071002, China
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Universe 2020, 6(3), 47; https://doi.org/10.3390/universe6030047
Submission received: 11 February 2020 / Revised: 15 March 2020 / Accepted: 15 March 2020 / Published: 20 March 2020
(This article belongs to the Special Issue Black Hole Physics and Astrophysics)

Abstract

:
We consider the new horizon first law in f ( R ) theory. We derive the general formulas to computed the entropy and energy for static spherically symmetric black hole. For applications, some nontrivial solutions in some popular f ( R ) theories are investigated, the entropies and the energies of static spherically symmetric black holes in these models are first calculated.

1. Introduction

There is a deep connection between thermodynamics and gravity. For a black hole, its area can be regarded as the entropy [1], and four laws for dynamics like in thermodynamics were suggested [2]. For diffeomorphism invariance of gravitational theory, the entropy of a black hole can be seen as a Noether charge [3,4]. The Einstein equations had been derived from the first law of thermodynamics [5], which was generalized to the non-equilibrium thermodynamics of spacetime [6]. This connection was also investigated in modified gravity theories—such as Lancos-Lovelock gravity [7], f ( R ) theory [8], and the scalar-Gauss-Bonnet gravity [9]. It was shown that the equation of motion for generalized gravity theory is equivalent to the thermodynamical relationship δ Q = T δ S [10]. In spherically symmetric spacetime Padmanabhan presented a general form for understanding the thermodynamics of the horizon [11]. For a time-dependent evolution horizon or a fixed axis-symmetric horizon, the Einstein equations on horizon can be rewritten as a thermodynamic identity [12]. In cubic and quartic quasi-topological gravity, the field equations on n + 1 dimensional topological black holes horizon with constant curvature can be expressed like the form of the first thermodynamical law [13]. In References [14,15], one can obtain the thermal entropy density of any spacetime from Einstein equations without assuming the temperature or the horizon.
In higher-order theories of gravity, issues about the entropy and energy of black hole are important. Especially the problems related to the energy of black hole are problematic, some attempts have been made to find a satisfactory answer to this question [16,17,18,19,20]. Using the first law of the horizon, one can derived the entropy and energy of black hole in Einstein gravity [11]. Recently, as shown in Reference [21], the entropy and energy of black hole in f ( R ) theories can be obtained simultaneously though the new horizon first law which was proposed in Reference [22]. Here we will consider the more complicated case: for the general spherically symmetric black hole we hope to obtain the energy and the entropy of black hole in f ( R ) theory, which can reduce to the results in References [16,21] for some special cases.
The rest of this article is organized as follows. In Section 2, we briefly review the new horizon first law. In Section 3, we investigate the entropy and energy of black holes in f ( R ) Theories. In Section 4, we calculate the energies and entropies for black holes in some f ( R ) theories for applications. Conclusion and discussion are given in Section 5.

2. The New Horizon First Law

Usually if the radial component of the stress-energy tensor acts as the thermodynamic pressure, P = T r r | r + , which is a special case of the assumption firstly proposed in Reference [15], and assume an horizon equation of state P = P ( V , T ) with the temperature identified as the Hawking temperature and a geometric volume V = V ( r + ) assigned to the horizon [23], then the radial Einstein equation can be written as the first law of thermodynamics, which can be rewritten as a horizon first law by considering a imaginary displacement of the horizon [11]
δ E = T δ S P δ V ,
where E is the quasilocal energy and S is the horizon entropy of the black hole. In Einstein gravity, E proves to be the Misner-Sharp energy [24]. The horizon first law (1) is a special case of the ‘unified first law’ [25].
There are two problems in this procedure that are needed to be further examined. The first problem is that the thermodynamic variables was vague in the original derivation, which require further determination. Secondly because both S and V are functions of only r + , which makes the horizon first law (1) to be of a function only depending on r + . As a matter of fact, Equation (1) can be rewritten as δ E = T S + P V δ r + , where the primes stands for the derivative with respected to r + . This makes the terms ‘heat’ and ‘work’ confused and results to a ‘vacuum interpretation’ of the first law (1) [22]. To avoid the problems mentioned above, a new horizon first law was proposed in Reference [22], by varying the horizon equation of state with the temperature T and the pressure P as independent thermodynamic quantities
δ G = S δ T + V δ P ,
which obviously depends on both T and P, meaning that T and P can vary independently. The energy, and therefore the standard horizon first law (1) can be obtained via a degenerate Legendre transformation E = G + T S P V . The Gibbs free energy G and the horizon entropy S are derived concepts for specified volume. This new horizon first law has practical utility and provides further evidence for the connection between gravity and thermodynamics.
In 4-dimensional Einstein gravity, we briefly review this approach to explain how it works [22]. Considering the geometry of a static spherically symmetric black hole, which is given by
d s 2 = N ( r ) d t 2 + d r 2 N ( r ) + r 2 d Ω 2 ,
The horizon is local at r = r + where N ( r + ) = 0 with N ( r + ) 0 .
Supposing minimal coupling to the matter and that the thermal sources are also the gravitational sources [15], we have P = T r r and identify the Hawking temperature as the thermal temperature T [11], the ( 1 1 ) component of the Einstein equation can be written as at the horizon
P = T 2 r + 1 8 π r + 2 ,
which is the horizon equation of state, where we take the units G = c = = 1 .
Since the identification of the Hawking temperature as the thermal temperature does not fall back on any gravitational field equations [22]. According to the conjecture suggested in Reference [15], the definition of the pressure is identified as the ( r r ) component of the matter stress-energy, which is also independent of any gravitational theories. So it is reasonable to speculate that the radial component of the gravitational field equations under consideration takes the following form [22]
P = D ( r + ) + C ( r + ) T ,
where C and D are some functions of r + , generally depending on the gravitational theory under consideration. Varying the generalized equation of state (5) and multiplying the volume V ( r + ) of black hole, it is easy to get
V δ P = S δ T + δ G ,
where
G = r + V ( r ) D ( r ) d r + T r + V ( r ) C ( r ) d r = P V S T r + V ( r ) D ( r ) d r ,
and
S = r + V ( r ) C ( r ) d r ,
by using the integration by parts. Taking the degenerate Legendre transformation E = G + T S P V , we finally derive the energy as
E = r + V ( r ) D ( r ) d r .
Hypothesizing that T, P, and V can be identified as the temperature, the pressure, and the volume, we can find that G, S, and E are the Gibbs free energy, the entropy, and the energy of the black hole, respectively. For Einstein gravity in four dimensions, it is easily to have C ( r + ) = 1 2 r + and D ( r + ) = 1 8 π r + 2 from (4), substituting them into Equations (8) and (9), we obtain S = π r + 2 and E = r + 2 . It has been shown that the new horizon first law still works in f ( R ) theories [21].

3. The Entropy and Energy of Black Holes in f ( R ) Theories

We consider the general spherically symmetric and static black hole in f ( R ) theories, whose geometry takes the form
d s 2 = W ( r ) d t 2 + d r 2 N ( r ) + r 2 d Ω 2 ,
where W ( r ) and N ( r ) are general functions of the coordinate r. Taking the largest positive root of N ( r + ) = 0 , yields the event horizon which fulfils N ( r + ) 0 . The surface gravity is given by [26]
κ K = W ( r + ) N ( r + ) 2 ,
which gives the temperature of the black hole as
T = κ K 2 π = W ( r + ) N ( r + ) 4 π .
In four-dimensional spacetime, the general action of f ( R ) gravity theories with source is
I = d 4 x g f ( R ) 2 k 2 + L m ,
where k 2 = 8 π , f ( R ) is a function only depending on the Ricci scalar R, and L m is the matter Lagrangian. Physically f ( R ) must fulfil stability conditions [27]: (a) no ghosts, d f / d R > 0 ; (b) no tachyons, d 2 f / d R 2 > 0 [28]; (c) stable solutions, d f / d R / d 2 f / d R 2 > R [29]. Additionally f ( R ) must also satisfy lim R ( f ( R ) R ) / R = 0 for the existence of an effective cosmological constant at high curvature and lim R d ( f ( R ) R ) / d R = 0 for recovering general relativity at early time. Varying the action (13) with respect to the metric, yields the gravitational field equations
G μ ν R μ ν 1 2 g μ ν R = k 2 1 F T μ ν + 1 k 2 T μ ν ,
where F = d f d R and T μ ν = 2 g δ L m δ g μ ν is the energy-momentum tensor for the matter. The tress-energy tensor for the effective curvature fluid, T μ ν , is given as following
T μ ν = 1 F ( R ) 1 2 g μ ν ( f R F ) + μ ν F g μ ν F ,
where = γ γ . Taking the trace of Equation (13), gives the relation as follow
R F ( R ) 2 f ( R ) + 3 F ( R ) = k 2 T .
For the general spherically symmetric and static black hole (10), the ( 1 1 ) components of the Einstein tensor and the stress-energy tensor of the effective curvature fluid are respectively given by
G 1 1 = 1 r 2 ( 1 + r N W W + N ) ,
and
T 1 1 = 1 F 1 2 ( R F f ) + N 2 W W F + 2 r N F ,
where the prime denotes the derivative with respected to r. Substituting Equations (17) and (18), and T 1 1 = P into Equation (14), we derive
k 2 P = F r 2 + 1 2 ( f R F ) + N W F r + 1 2 F W N + N F r 2 + 2 N F r .
At the horizon, r = r + , thinking of the temperature (12) and N ( r + ) = 0 , Equation (19) reduces to
P = 1 8 π F r + 2 + 1 2 f R F + 1 4 N W 2 F r + + F T .
Comparing Equation (5) with Equation (20), we then have
D ( r + ) = 1 8 π F r + 2 + 1 2 f R F ,
and
C ( r + ) = 1 4 N W 2 F r + + F .
The volume V of the black hole (10) is given by [23]
V ( r + ) = 0 r + 0 π 0 2 π g d r d θ d ϕ = 4 π 0 r + W N r 2 d r .
where we have used the relation N ( r + ) W ( r + ) = N ( r + ) W ( r + ) [26]. Substituting Equations (23) and (19) into Equation (8), we obtain the entropy as
S = r + ( 2 π r F + π r 2 F ) d r = π r + 2 F ,
thought the black hole (10) has different temperature and volume, its entropy (24) has the same form for the entropy of black hole with W ( r ) = N ( r ) obtained in Reference [21]. The formula (24) can be obtained by using the Euclidean semiclassical approach or the Wald entropy formula [30,31,32]. Using the degenerate Legendre transformation E = G + T S P V , inserting Equations (23) and (21) into Equation (9), then the energy of the black hole is given as follow
E = 1 2 r + W N F r 2 + 1 2 ( f R F ) r 2 d r .
For W ( r ) = N ( r ) e 2 α ( r ) , Equation (25) reduces to the results obtained in Reference [16] where the entropy was obtained by using the Wald method. For W ( r ) = N ( r ) , Equation (25) gives the result obtained in Reference [21]. Equations (24) and (25) show that the new horizon first law still work in f ( R ) theories for the general spherically symmetric and static black hole.

4. Applications

In this section, we will use Equations (24) and (25) to calculate the entropies and energies of black holes (10) in some popular f ( R ) theories to illustrate the method described above. These models allowe solutions with constant Ricci curvature (such as Schwarzschild-de Sitter or Schwarzschild solutions) or solutions with non-constant Ricci curvature. For a Schwarzschild-de Sitter solution, we have N ( r + ) = 1 2 M / r R 0 r 2 / 12 = 0 at the horizon [33], which gives
2 M = r + 1 12 R 0 r + 3 .
This equation relates the mass M, the radius r + , and the Ricci curvature R 0 together.
We firstly start with a f ( R ) model which unifies inflation and cosmic acceleration under the same picture and was confirmed by the solar system tests [34]. This model takes the form
f ( R ) = R f 0 0 R e α R 1 2 n x R 1 2 n f 0 x Λ i d x ,
where R 1 is a constant which is given by f 0 R 1 0 1 e α / x 2 d x = R now with 0 < f 0 < 1 and R now the Ricci scalar at present. The effective cosmological constant is f ( ) = Λ i in the early universe and is 2 R 0 in the present era. The stability condition, f ( R ) > 0 , gives
f 0 Λ i > 2 n R 1 2 n R R 1 2 n + 1 .
Due to the fact that f ( 0 ) = 0 , this model allows a Schwarzschild solution. For a Schwarzschild-de Sitter solution, we obtain from Equation (16),
R 0 + f 0 R 0 e α R 1 2 n R 0 R 1 2 n f 0 R 0 Λ i = 2 f 0 0 R e α R 1 2 n x R 1 2 n f 0 x Λ i d x .
For the black hole (10), we calculate the entropy from Equation (24) as
S = π r + 2 1 f 0 e α R 1 2 n R R 1 2 n f 0 R Λ i .
The nonnegativity of the entropy gives additional limits on the parameters: 1 > f 0 e α R 1 2 n R R 1 2 n f 0 R Λ i . The entropy for Schwarzschild-de Sitter black hole is
S = π r + 2 1 f 0 e α R 1 2 n R 0 R 1 2 n f 0 R 0 Λ i ,
where R 0 must fulfil Equations (28) and (29).
For Schwarzschild black hole ( R 0 = 0 ), the stability condition (28) reduces to n < f 0 R 1 2 Λ i , and the entropy (31) reduces to
S = π r + 2 1 f 0 e α .
Computing the energy by using Equation (25), we have
E = 1 4 r + W N 2 + f 0 R r 2 2 e α R 1 2 n R R 1 2 n f 0 R Λ i f 0 r 2 0 R e α R 1 2 n x R 1 2 n f 0 x Λ i d x d r .
For the Schwarzschild-de Sitter black hole, Equation (33) reduces to
E = r + 12 6 + f 0 R 0 r + 2 6 e α R 1 2 n R 0 R 1 2 n f 0 R 0 Λ i f 0 r + 2 0 R 0 e α R 1 2 n x R 1 2 n + f 0 x Λ i d x = r + 12 6 1 2 R 0 r + 2 + 1 2 R 0 r + 2 6 f 0 e α R 1 2 n R 0 R 1 2 n f 0 R 0 Λ i = 1 f 0 e α R 1 2 n R 0 R 1 2 n f 0 R 0 Λ i M ,
where Equations (26) and (29) were used. For the Schwarzschild black hole, R 0 = 0 , Equation (34) reduces to
E = r + 2 1 f 0 e α .
Since S 0 and E 0 , Equations (32) and (35) give new constraints on the parameters: (a) 1 > f 0 e α R 1 2 n R 0 R 1 2 n f 0 R 0 Λ i for Schwarzschild-de Sitter black hole; and (b) 1 f 0 e α for Schwarzschild black hole.
The second f ( R ) model we consider here was recovered from the entropy of black holes [35]
f ( R ) = R q R β + 1 α β + α + β ϵ β + 1 + q ϵ R β + 1 ln a 0 β R β c ,
where 0 ϵ e 4 ( 1 + 4 e α ) and q = 4 a 0 β / c ( β + 1 ) with α 0 , β > 0 , a 0 = l p 2 and c a constant. Since R 0 , this type of f ( R ) theory admits no Schwarzschild solution. Use Equation (16), we get the condition for the Schwarzschild-de Sitter solution
1 + β q α R 0 β + q α β R 0 β 2 q β ϵ R 0 β = β 2 1 q ϵ R 0 β ln a 0 β R 0 β c .
From the Equation (24), the entropy of the black hole (10) is computed as
S = π r + 2 1 β + 1 q α R β + β + 1 q ϵ R β ln a 0 β R β c ,
The nonnegativity of the entropy gives additional constraints on the parameters: 1 > β + 1 q α R β + β + 1 q ϵ R β ln a 0 β R β c . For Schwarzschild-de Sitter black hole, the entropy is
S = π r + 2 1 β + 1 q α R 0 β + β + 1 q ϵ R 0 β ln a 0 β R 0 β c = 2 β q β ( α β α + 2 ϵ ) R 0 β β 1 π r + 2 = β 2 ( α β α + 2 ϵ ) q R 0 β β 1 π r + 2 ,
where the condition (37) was uesed. Since S 0 , gives new limits on the parameters: 2 > ( α β α + 2 ϵ ) q R 0 β for β > 1 and 2 < ( α β α + 2 ϵ ) q R 0 β for β < 1 .
The energy of the black hole (10) is derived from Equation (25) as
E = 1 4 r + W N r 2 R 1 α + α β + β ϵ β + 1 + q ϵ R β ln a 0 β R β c
r 2 R 2 1 β + 1 q α R β + β + 1 q ϵ R β ln a 0 β R β c d r = 1 4 W N 2 2 α ( β + 1 ) q R β α + α β + β ϵ β + 1 r 2 R
+ q α ( β + 1 ) r 2 R β + 1 + q ϵ 2 ( β + 1 ) β r 2 R R β ln a 0 β R β c d r .
For Schwarzschild-de Sitter black hole, Equation (40) takes the form
E = r + 12 q β R 0 β r + 2 R 0 12 α + α β ϵ ϵ ( β + 1 ) ln a 0 β R 0 β c = 2 q β R 0 β M α + α β ϵ ϵ ( β + 1 ) ln a 0 β R 0 β c = 2 β 1 + β ( β ϵ + α β 2 + ϵ α β ) q R 0 β β 1 M
where Equations (37) and (26) were used. The nonnegativity of the energy gives new constraints on the parameters: 1 + β > ( β ϵ + α β 2 + ϵ α β ) q R 0 β for β > 1 and 1 + β < ( β ϵ + α β 2 + ϵ α β ) q R 0 β for β < 1 .
We thirdly investigate the following f ( R ) theory which allows black hole solutions with non-constant Ricci curvature [36]
f ( R ) = 2 a R α ,
where α is a parameter of the model which is related to an effective cosmological constant and a > 0 is a parameter with units [distance] 1 . This model admits a static spherically symmetric solution (10) which takes the follow form [36]
N ( r ) = W ( r ) = 1 2 1 α r 2 6 + 2 Q r 2 ,
where Q is an integration constant. The event horizon of the black hole is located at: (a) r + = 3 α + α 9 + 12 α Q / α for α > 0 and Q > 0 ; (b) r + = 3 α α 9 + 12 α Q / α for α > 0 , Q < 0 and α Q > 3 / 4 ; (c) r + = 3 / α 9 + 12 α Q / α for α < 0 and Q < 0 ; and (d) r + = 6 / α for α > 0 and Q = 0 . The Ricci scalar evolves as
R = α + 1 r 2 ,
Substituting W ( r + ) = N ( r + ) into Equation (24), the entropy is calculated as
S = a π ( 3 + 9 + 12 α Q ) α , for r + = 3 α + α 9 + 12 α Q α ,
S = a π ( 3 9 + 12 α Q ) α , for r + = 3 α α 9 + 12 α Q α ,
S = a π ( 3 9 + 12 α Q ) α , for r + = 3 α 9 + 12 α Q α ,
S = 6 a π α , for r + = 6 α .
From Equation (25), the energy is given by
E = a 12 α ( 3 + 9 + 12 α Q ) ( 9 + 12 α Q 4 ) , for r + = 3 α + α 9 + 12 α Q α ,
E = a 12 α ( 3 9 + 12 α Q ) ( 4 + 9 + 12 α Q ) , for r + = 3 α α 9 + 12 α Q α ,
E = a 12 α ( 3 9 + 12 α Q ) ( 4 + 9 + 12 α Q ) , for r + = 3 α 9 + 12 α Q α ,
E = a 2 α , for r + = 6 α .
For α > 0 and Q > 0 , the nonnegativity of the energy gives additional constraints on the parameters: α Q < 7 / 12 .
We finally consider a power-law of F ( r ) , for example: F = α r a , with constants a and α . The functions W ( r ) and N ( r ) in (10) are found to take forms [37]
W = r 2 a ( a 1 ) a + 2 N
and
N = C 1 r 2 a 2 + 2 a + 2 a + 2 + ( a + 2 ) 2 ( 2 a 2 + 2 a + 2 ) ( 2 + 2 a a 2 ) .
where C 1 is a integration constant. The event horizon is local at r + = ( 2 + a ) 2 C 1 ( 2 a 2 + 2 a + 2 ) ( 2 + 2 a a 2 ) 2 + a 2 a 2 + 2 a + 2 . In this case, function f ( R ) is given by
f ( R ) = α 1 R 1 a 2 ,
where α 1 = 2 α ( 2 a ) a 2 1 3 a 2 + 2 a + a 2 a 2 . The entropy (24) and the energy (25) respectively reads
S = α π r + a + 2 = α π C 1 ( 2 a 2 + 2 a + 2 ) ( 2 + 2 a a 2 ) ( 2 + a ) 2 ( 2 + a ) 2 2 a 2 + 2 a + 2 ,
E = π 1 2 8 Γ ( 3 2 ) α ( a + 2 ) 3 r + 2 a 2 + 2 a + 2 a + 2 ( a 2 2 a 2 ) ( 2 a 2 + 2 a + 2 ) = 1 4 α C 1 ( 2 + a ) ,
For a = 0 , we obtain the results in Einstein’s gravity. The nonnegativity of the entropy and the energy give new constraints on the parameters: α 0 and C 1 ( a 2 ) 0 .

5. Conclusions and Discussion

We investigated whether the new horizon first law still holds in f ( R ) theory with general spherically symmetric black hole (10). We derived the general formulas to computed the entropy and energy of the black hole. For black hole (10), its temperature, volume and entropy have different forms, but its entropy (24) has the same form for the entropy of black hole (3) obtained in Reference [21]. For applications, some nontrivial black hole solutions in some popular f ( R ) theories are considered, the entropies and the energies of black holes in these models are first calculated. The nonnegativity of entropy or energy gives new constraints on the parameters of f ( R ) theories, which may be useful for future researches. The formulas presented here can be used to calculate the energies and entropies of black holes in other types f ( R ) theories, but cannot be used in the case discussed in Reference [38], where F ( R ) = 0 . In Reference [39], a picture of equilibrium thermodynamics on the apparent horizon in the expanding cosmological background was obtained for a wide class of modified gravity theories. Whether this procedure can be applied to the apparent horizon in the expanding cosmological background worths further study.

Author Contributions

Conceptualization, methodology, writing—review and editing, supervision, project administration, and funding acquisition, R.-J.Y.; calculation, writing—original draft preparation, Y.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This study is supported in part by National Natural Science Foundation of China (Grant No. 11273010), Hebei Provincial Natural Science Foundation of China (Grant No. A2014201068), the Outstanding Youth Fund of Hebei University (No. 2012JQ02), and the Midwest universities comprehensive strength promotion project.

Acknowledgments

We thank Jing Zhai for helpful advice.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

  1. Bekenstein, J.D. Black holes and entropy. Phys. Rev. D 1973, 7, 2333–2346. [Google Scholar] [CrossRef]
  2. Bardeen, J.M.; Carter, B.; Hawking, S.W. The Four laws of black hole mechanics. Commun. Math. Phys. 1973, 31, 161–170. [Google Scholar] [CrossRef]
  3. Wald, R.M. Black hole entropy is the Noether charge. Phys. Rev. D 1993, 48, R3427–R3431. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Iyer, V.; Wald, R.M. Some properties of Noether charge and a proposal for dynamical black hole entropy. Phys. Rev. D 1994, 50, 846–864. [Google Scholar] [CrossRef] [Green Version]
  5. Jacobson, T. Thermodynamics of space-time: The Einstein equation of state. Phys. Rev. Lett. 1995, 75, 1260–1263. [Google Scholar] [CrossRef] [Green Version]
  6. Eling, C.; Guedens, R.; Jacobson, T. Non-equilibrium thermodynamics of spacetime. Phys. Rev. Lett. 2006, 96, 121301. [Google Scholar] [CrossRef] [Green Version]
  7. Paranjape, A.; Sarkar, S.; Padmanabhan, T. Thermodynamic route to field equations in Lancos-Lovelock gravity. Phys. Rev. D 2006, 74, 104015. [Google Scholar] [CrossRef] [Green Version]
  8. Elizalde, E.; Silva, P.J. F(R) gravity equation of state. Phys. Rev. D 2008, 78, 061501. [Google Scholar] [CrossRef] [Green Version]
  9. Bamba, K.; Geng, C.-Q.; Nojiri, S.; Odintsov, S.D. Equivalence of modified gravity equation to the Clausius relation. Europhys. Lett. 2010, 89, 50003. [Google Scholar] [CrossRef] [Green Version]
  10. Brustein, R.; Hadad, M. The Einstein equations for generalized theories of gravity and the thermodynamic relation δQ=TδS are equivalent. Phys. Rev. Lett. 2009, 103, 101301. [Google Scholar] [CrossRef]
  11. Padmanabhan, T. Classical and quantum thermodynamics of horizons in spherically symmetric space-times. Class. Quant. Grav. 2002, 19, 5387–5408. [Google Scholar] [CrossRef]
  12. Kothawala, D.; Sarkar, S.; Padmanabhan, T. Einstein’s equations as a thermodynamic identity: The Cases of stationary axisymmetric horizons and evolving spherically symmetric horizons. Phys. Lett. B 2007, 652, 338–342. [Google Scholar] [CrossRef] [Green Version]
  13. Sheykhi, A.; Dehghani, M.H.; Dehghani, R. Horizon Thermodynamics and Gravitational Field Equations in Quasi Topological Gravity. Gen. Rel. Grav. 2014, 46, 1679. [Google Scholar] [CrossRef] [Green Version]
  14. Yang, R. The thermal entropy density of spacetime. Entropy 2013, 15, 156–161. [Google Scholar] [CrossRef]
  15. Yang, R.-J. Is gravity entropic force? Entropy 2014, 16, 4483–4488. [Google Scholar] [CrossRef] [Green Version]
  16. Cognola, G.; Gorbunova, O.; Sebastiani, L.; Zerbini, S. On the Energy Issue for a Class of Modified Higher Order Gravity Black Hole Solutions. Phys. Rev. D 2011, 84, 023515. [Google Scholar] [CrossRef] [Green Version]
  17. Deser, S.; Tekin, B. Energy in generic higher curvature gravity theories. Phys. Rev. D 2003, 6, 084009. [Google Scholar] [CrossRef] [Green Version]
  18. Deser, S.; Tekin, B. New energy definition for higher curvature gravities. Phys. Rev. D 2007, 75, 084032. [Google Scholar] [CrossRef] [Green Version]
  19. Abreu, G.; Visser, M. Tolman mass, generalized surface gravity, and entropy bounds. Phys. Rev. Lett. 2010, 105, 041302. [Google Scholar] [CrossRef] [Green Version]
  20. Cai, R.-G.; Cao, L.-M.; Hu, Y.-P.; Ohta, N. Generalized Misner-Sharp Energy in f(R) Gravity. Phys. Rev. D 2009, 80, 104016. [Google Scholar] [CrossRef] [Green Version]
  21. Zheng, Y.; Yang, R.-J. Horizon thermodynamics in f(R) theory. Eur. Phys. J. C 2018, 78, 682. [Google Scholar] [CrossRef]
  22. Hansen, D.; Kubiznak, D.; Mann, R. Horizon Thermodynamics from Einstein’s Equation of State. Phys. Lett. B 2017, 771, 277–280. [Google Scholar] [CrossRef]
  23. Parikh, M.K. The Volume of black holes. Phys. Rev. D 2006, 73, 124021. [Google Scholar] [CrossRef] [Green Version]
  24. Misner, C.W.; Sharp, D.H. Relativistic equations for adiabatic, spherically symmetric gravitational collapse. Phys. Rev. 1964, 36, B571–B576. [Google Scholar] [CrossRef]
  25. Hayward, S.A. Unified first law of black hole dynamics and relativistic thermodynamics. Class. Quant. Grav. 1998, 15, 3147–3162. [Google Scholar] [CrossRef]
  26. Di Criscienzo, R.; Hayward, S.A.; Nadalini, M.; Vanzo, L.; Zerbini, S. Hamilton-Jacobi tunneling method for dynamical horizons in different coordinate gauges. Class. Quant. Grav. 2010, 27, 015006. [Google Scholar] [CrossRef] [Green Version]
  27. Pogosian, L.; Silvestri, A. The pattern of growth in viable f(R) cosmologies. Phys. Rev. D 2008, 77, 023503. [Google Scholar] [CrossRef] [Green Version]
  28. Dolgov, A.D.; Kawasaki, M. Can modified gravity explain accelerated cosmic expansion? Phys. Lett. B 2003, 573, 1–4. [Google Scholar] [CrossRef] [Green Version]
  29. Sawicki, I.; Hu, W. Stability of Cosmological Solution in f(R) Models of Gravity. Phys. Rev. D 2007, 75, 127502. [Google Scholar] [CrossRef] [Green Version]
  30. Dyer, E.; Hinterbichler, K. Boundary Terms, Variational Principles and Higher Derivative Modified Gravity. Phys. Rev. D 2009, 79, 024028. [Google Scholar] [CrossRef] [Green Version]
  31. Vollick, D.N. Noether Charge and Black Hole Entropy in Modified Theories of Gravity. Phys. Rev. D 2007, 76, 124001. [Google Scholar] [CrossRef] [Green Version]
  32. Iyer, V.; Wald, R.M. A Comparison of Noether charge and Euclidean methods for computing the entropy of stationary black holes. Phys. Rev. D 1995, 52, 4430–4439. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Multamaki, T.; Vilja, I. Spherically symmetric solutions of modified field equations in f(R) theories of gravity. Phys. Rev. D 2006, 74, 064022. [Google Scholar] [CrossRef]
  34. Nojiri, D.; Odintsov, S.D. Unifying inflation with ΛCDM epoch in modified f(R) gravity consistent with Solar System tests. Phys. Lett. B 2007, 657, 238–245. [Google Scholar] [CrossRef] [Green Version]
  35. Caravelli, F.; Modesto, L. Holographic effective actions from black holes. Phys. Lett. B 2011, 702, 307–311. [Google Scholar] [CrossRef] [Green Version]
  36. Caate, P.; Jaime, L.G.; Salgado, M. Spherically symmetric black holes in f(R) gravity: Is geometric scalar hair supported ? Class. Quant. Grav. 2016, 33, 155005. [Google Scholar]
  37. Amirabi, Z.; Halilsoy, M.; Mazharimousavi, S.H. Generation of spherically symmetric metrics in f(R) gravity. Eur. Phys. J. C 2016, 76, 338. [Google Scholar] [CrossRef] [Green Version]
  38. Nashed, G.G.L.; Capozziello, S. Charged spherically symmetric black holes in f(R) gravity and their stability analysis. Phys. Rev. D 2019, 99, 104018. [Google Scholar] [CrossRef] [Green Version]
  39. Bamba, K.; Geng, C.-Q.; Shinji, T. Equilibrium thermodynamics in modified gravitational theories. Phys. Lett. B 2010, 688, 101–109. [Google Scholar] [CrossRef] [Green Version]

Share and Cite

MDPI and ACS Style

Zheng, Y.; Yang, R.-J. Entropy and Energy of Static Spherically Symmetric Black Hole in f(R) Theory. Universe 2020, 6, 47. https://doi.org/10.3390/universe6030047

AMA Style

Zheng Y, Yang R-J. Entropy and Energy of Static Spherically Symmetric Black Hole in f(R) Theory. Universe. 2020; 6(3):47. https://doi.org/10.3390/universe6030047

Chicago/Turabian Style

Zheng, Yaoguang, and Rong-Jia Yang. 2020. "Entropy and Energy of Static Spherically Symmetric Black Hole in f(R) Theory" Universe 6, no. 3: 47. https://doi.org/10.3390/universe6030047

APA Style

Zheng, Y., & Yang, R. -J. (2020). Entropy and Energy of Static Spherically Symmetric Black Hole in f(R) Theory. Universe, 6(3), 47. https://doi.org/10.3390/universe6030047

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop