Solutions and Thermodynamics of Charged Rotating Black Holes in a Fuzzy Space

In general relativity, there exist three classes of black holes, namely, Schwarzschild black hole, Kerr black hole and Reissner-Nordström black hole, or Kerr-Newman black hole [1]. In fact, the solutions of Einstein’s field equation for the gravitational field of an electrically charged point mass were obtained in 1918 by Nordström and Reissner [2, 3], not long after Karl Schwarzschild had found the Schwarzschild metric as a solution for a point mass without electric charge and angular momentum [4]. However, the cosmic behavior of black holes has been studied in different points such as the cosmic history of black hole [5], the dynamical evolution and observational signatures of massive black hole [6]. In this paper we will examine the effect of fuzzy space [7] on a static, charged, and rotating black hole. We will investigate thermodynamic properties such as Hawking temperature and entropy. This paper is organized as follows. In Section 2,we present Schwarzschild black hole in fuzzy space. In Section 3, we present the electric charged black hole in fuzzy space. We study a magnetic fuzzy black hole in Section 4. In Section 5, we give the combined case where J > 0 and Q > 0. We give some thermodynamic properties of fuzzy black hole in diverse cases in Section 6. Finally, we discuss our results in Section 7.


Introduction
In general relativity, there exist three classes of black holes, namely, Schwarzschild black hole, Kerr black hole and Reissner-Nordström black hole, or Kerr-Newman black hole [1]. In fact, the solutions of Einstein's field equation for the gravitational field of an electrically charged point mass were obtained in 1918 by Nordström and Reissner [2,3], not long after Karl Schwarzschild had found the Schwarzschild metric as a solution for a point mass without electric charge and angular momentum [4].
However, the cosmic behavior of black holes has been studied in different points such as the cosmic history of black hole [5], the dynamical evolution and observational signatures of massive black hole [6].
In this paper we will examine the effect of fuzzy space [7] on a static, charged, and rotating black hole. We will investigate thermodynamic properties such as Hawking temperature and entropy.
This paper is organized as follows. In Section 2, we present Schwarzschild black hole in fuzzy space. In Section 3, we present the electric charged black hole in fuzzy space. We study a magnetic fuzzy black hole in Section 4. In Section 5, we give the combined case where > 0 and > 0. We give some thermodynamic properties of fuzzy black hole in diverse cases in Section 6. Finally, we discuss our results in Section 7.

Fuzzy Schwarzschild Black Hole
We consider Schwarzschild black hole in a fuzzy space with the mass density of point particle described by [8] The covariant conservation law ∇ ] and the condition of the metric coefficient 00 = − −1 for the noncommutative Schwarzschild-like metric and the energy momentum tensor are given by where The asymptotic solution of Einstein's equation (2), using (1) as the matter source, is the same as replacing the mass of 2 ISRN High Energy Physics Dirac delta function source in Schwarzschild spacetime by the effective mass of smeared source [9] ℎ ( ) = ∫ 3 ℎ ( ) = 4 ∫ 0 2 ℎ ( ) The geometry of fuzzy black hole is described by the line element where The event horizon of the black hole is given by setting ( ℎ ) = 0, and the nonzero solution of this equation satisfies Instead of a single-event horizon, there are different possibilities: (i) we have two distinct horizons for > 0 , (ii) in this case, we have one degenerate horizon (external black hole) for = 0 , and (iii) no horizon for < 0 .

Charged Black Hole in a Fuzzy Space
In this case, we have a black hole with = 0 and > 0. As mentioned in [10], the geometry of a fuzzy black hole is described by the line element Its Einstein's field equations are written accordingly as Solving the previous equations, we find where Ei( ) represents the exponential integral function defined as and a smeared distribution function is described by In this case, the metric ( ) takes the following form: Note that when /ℎ → ∞, either when considering a large black hole ( → ∞) or the commutative limit (ℎ → 0), we obtain the following metric which defines charged BTZ solution [11]: The metric (13) describes the geometry of a fuzzy black hole with the corresponding event horizon given by the following condition imposed on ( ). Equation (13) cannot be solved in closed form. However, by plotting ( ), one can see obvious intersections with the r-axis and determine numerically the existence of horizons and their radii. In view of these results, there can be no black hole if the original mass is less than the lower limit mass 0 . The horizon of the external black hole is determined by the conditions = 0 and = 0, and the mass of the external black hole can be written as

Rotating Fuzzy Black Hole
The metric of a fuzzy black hole (with > 0 and = 0) is given in [12,13] by where Note that when ℎ → 0, we obtain the well-known BTZ rotating solution with angular momentum and total mass , ( ) = −8 + ( 2 / 2 )+( 2 /4 2 ). The metric (16) describes the geometry of a fuzzy black hole with the corresponding event horizon given by the following condition imposed on ( ): This equation cannot be solved in closed form. However, by plotting ( ), one can read intersections with the r-axis and determine numerically the existence of horizon(s) and their radii. Figure 1 shows that the existence of angular momentum introduces new behavior with respect to the noncommutative black hole studied by Myung and Yoon [14]. Instead of a single-event horizon, there are different possibilities: we have two distinct horizons for > 0 , we have one degenerate horizon (external black hole) for = 0 , and no horizon for < 0 .
In view of these results, there can be no black hole if the original mass is less than the lower limit mass 0 . The horizon of the external black hole is determined by the conditions = 0 and = 0, which gives and then, the mass of the extremal black hole can be written as (20) In the commutative limit ℎ → 0, the extreme black hole has the horizon at and its mass is

Charged Rotating Fuzzy Black Hole
In this section, we will combine our results for the case of an electric and magnetic charged black hole; such type is known as Kerr-Newman black hole ( > 0 and > 0). Its metric is given by The metric (23) describes the geometry of a fuzzy black hole with the corresponding event horizon given by the following condition imposed on ( ): The derivative of the metric function is given by

ISRN High Energy Physics
In view of these results, there can be no black hole if the original mass is less than the lower limit mass 0 . The horizon of the external black hole is determined by the conditions = 0 and = 0, which gives where ( , ℎ) = (1/2)( /ℎ) 2 + ( /ℎ) + 1, and then, the mass of the external black hole can be written as (28)

Charged Black Hole.
Hawking temperature [17] is as follows: where The first law of thermodynamics for a charged black hole form is where the electrostatic potential is given by ISRN High Energy Physics 5 We calculate the entropy as which gives 6.3. Rotating Black Hole. For rotating fuzzy black hole, the hawking temperature of the geometry of the fuzzy black hole is given by [18] = 1 4 ( ) The temperature is a monotonically increasing function towards the horizon radius for large black holes, and the temperature of the extreme black hole is zero. For large black holes, that is, ( + /ℎ) 6 0, one recovers the temperature of the rotating BTZ black hole The first law of thermodynamics for a charged black hole form is where the angular velocity of the black hole is given by It is the same rotating BTZ solution. Equation (37) can be written in the Gibbs form as [10,12] At the outer horizon, = + , we have = ( + , ) and Using (39) we get where is the entropy of the noncommutative black hole. From (20) we finally obtain where the entropy is a function of + . Note that, in the large black hole limit, the entropy function corresponds to the Bekenstein-Hawking entropy (area law), BH = + /2, for the rotating BTZ geometry.

Conclusion
In this paper, we have constructed a static, electric, and magnetic (rotating) black hole in a fuzzy space by using an anisotropic perfect fluid fuzzy black hole and a smeared distribution function as an electric and magnetic charge. We have investigated the Hawking temperature and entropy. We have also studied the combined case where both magnetic and electric charges of the black holes in a fuzzy space exist.
Note that when /ℎ → ∞, either when considering a large black hole ( → ∞) or the commutative limit (ℎ → 0), we obtain the metric of charged BTZ solutions with the electric charge and total mass ( ) = −8 + and we obtain the well-known BTZ rotating solution with angular momentum and the total mass