In this study, the Generalized Uncertainty Principle (GUP) effect on the Hawking radiation formed by tunneling of a massive vector boson particle from the 2+1 dimensional new-type black hole was investigated. We used modified massive vector boson equation based on the GUP. Then, the Hamilton-Jacobi quantum tunneling approach was used to work out the tunneling probability of the massive vector boson particle and Hawking temperature of the black hole. Due to the GUP effect, the modified Hawking temperature was found to depend on the black hole properties, on the AdS3 radius, and on the energy, mass, and total angular momentum of the tunneling massive vector boson. In the light of these results, we also observed that modified Hawking temperature increases by the total angular momentum of the particle while it decreases by the energy and mass of the particle and the graviton mass. Also, in the context of the GUP, we see that the Hawking temperature due to the tunneling massive vector boson is completely different from both that of the spin-0 scalar and that of the spin-1/2 Dirac particles obtained in the previous study. We also calculate the heat capacity of the black hole using the modified Hawking temperature and then discuss influence of the GUP on the stability of the black hole.
Akdeniz ÜniversitesiTürkiye Bilimsel ve Teknolojik Arastirma Kurumu116F3291. Introduction
It was theoretically proved by Hawking that a black hole can emit thermal radiation as a result of quantum tunneling process of the particles created by the quantum fluctuation near the event horizon [1–4]. This suggestion has an important influence on understanding the quantization of black hole and gravity [5, 6]. Since the Hawking’s discovery, many different methods were developed to calculate black hole radiation, known as Hawking radiation, in the literature. For instance, the Hamilton-Jacobi approach is an effective way to study the Hawking radiation as a quantum tunneling process of particles from black holes. In this context, Hawking radiation is seen to be extensively investigated in the literature in the context of quantum tunneling of a point-like elementary particle [7–34]. These studies show that Hawking radiation of a black hole must be completely independent from the mass, total angular momentum, energy, and charge of a tunneling point particle.
On the other hand, alternative approaches about quantum gravity predict the presence of a minimal observable length in Planck scale [35–42]. The existence of such length leads to the GUP, a generalization of the standard Heisenberg uncertainty principle [36, 43–45]. Effects of the GUP on the standard quantum mechanical problems [46, 47], on the early and late times of the universe [48–51], and on thermodynamic properties of black holes [52–54] have been extensively discussed in the literature. To calculate the modified Hawking radiation in the GUP framework by Hamilton-Jacobi approach, Klein-Gordon equation for spin-0 particle, Dirac equation for spin-1/2 particle, and massive W∓-boson equation for spin-1 particle are modified [55–57]. It shows that the modified Hawking temperature depends not only on properties of black hole, but also on the properties of tunneling particle, such as mass, angular (orbital + spin) momentum, energy, charge [58–71]. Furthermore, it has been proved that the spin-0 and spin-1/2 particles tunnel through the horizon of the 2+1 dimensional black holes in the same way in the absence of the GUP effect. On the other hand, they tunnel differently in the presence of the GUP effect [72, 73]. Therefore, our plan was to figure out the effect of the GUP on the Hawking temperature of the 2+1 dimensional new-type black hole by using process of tunneling of the massive spin-1 particle described by the relativistic equation derived from the quantization of classical zitterbewegung model [74, 75]. This will provide a comparison of the results of the tunneling process of the different particles types from the new-type black hole under conditions with and without the GUP effect [32–34, 73]. The stability of the black hole will also be discussed in the context of the GUP.
The paper is organized as follows: in the following section, we modify the massive vector boson equation in the framework of the GUP. After that, in Section 3, we introduce the new-type black hole and then calculate its modified Hawking temperature by using the Hamilton-Jacobi approach. Moreover, using the modified Hawking temperature, the heat capacity of the black hole is calculated for analyzing the stability of the black hole. In Section 4, we summarize the results.
2. Modified Vector Boson Equation
In a curved space-time background, the massive vector boson equation can be written as in [74](1)iβμx∂μ-ΣμxΨx=m0ħΨxwhere the m0 and Ψx=ψ+,ψ0,ψ0,ψ-T are the mass and the wave function of the massive vector boson, respectively [74, 76–84]. βμ(x) and Σμ(x) are Kemmer matrices in 2+1 dimensional curved space-time and spin connection coefficients, respectively, and their expressions are given as(2)βμx=σ¯μx⊗I+I⊗σ¯μxΣμx=Γμx⊗I+I⊗Γμx, in terms of the Dirac matrices, σ¯μ(x), and spin connections for Dirac particle, Γμ(x) [85].
To investigate the quantum gravity effect on the tunneling process of the massive vector boson, (1) has to be rewritten in the framework of the GUP. The simplest and well-known form of the GUP relation is given as follows [86–89]:(3)ΔxΔp≥h21+αΔp2,where α=α0/Mp2 with Planck mass, Mp, and a dimensionless parameter, α0. Moreover, (3) can be derived by using the modified Heisenberg algebra relation given as [86–89](4)xi,pj=iħδij1+αp0i2,with modified position, xi, and modified momentum pj operators given in terms of the standard position, x0i, and momentum operators, p0j,(5)xi=x0i,pi=p0i1+αp02,respectively, and p02=p0jp0j [61]. On the other hand, the modified energy relation is given by the following form [56, 64, 87, 88]:(6)E~=E1-αE2=E1-αp2+m02,with the energy mass shell condition, E2=p2+m02. In addition, the square of the momentum operator can be expressed after neglecting the higher order terms of the α parameter as follows [89]:(7)p2=pipi≃-ħ2∂i∂i-2α∂j∂j∂i∂i.Including (5), (6), and (7), the modified massive vector boson equation can be written as follows:(8)iβix∂i-iβμxΣμ-m0ħ1+αħ2∂j∂j-αm02Ψ~+iβ0x∂0Ψ~=0,or in its explicit form:(9)iβ0∂0Ψ~+iβi1-αm02∂i+iαħ2βi∂i∂j∂jΨ~-m0ħ1+αħ2∂j∂j-αm02Ψ~-iβμΣμ1+αħ2∂j∂j-αm02Ψ~=0,where the Ψ~ is the modified wave function of a vector boson.
3. Tunneling of Vector Boson Particle from New-Type Black Hole
In the framework of the quantum gravity, several studies have been carried out with a focus on 2+1 dimensional theories (i.e., a toy model) [90–93]. The New Massive Gravity is just one of them [94]. It has topologically a graviton with mass [94–96]. This theory provides black hole solutions. For example, the new-type black hole, which is asymptotically anti-Sitter, static, and circular symmetric, is a solution to field equations of the theory. Also, the new-type black hole is conformally flat, and therefore it corresponds to a solution of the 2+1 dimensional conformal gravity theory [97, 98]. The space-time metric of the black hole is given as(10)ds2=L2frdt2-1frdr2-r2dϕ2,where f(r)=r2+br+c and b and c are two constant parameters related to the “gravitational hair” and “mass”, respectively [97–100]. L is the AdS3 radius defined as L2=1/2m2=1/2Λ in terms of the graviton mass, m (or the cosmological constant, Λ). The black hole has an outer and an inner horizon located at r+=1/2-b+b2-4c and r-=1/2-b-b2-4c, respectively. Also, it has a curvature singularity at r=0 when b≠0. This singularity is always surrounded by an event horizon. Also, the signatures of the b and c parameters play important role in the mathematical and physical properties of the black hole [97, 99]. The horizons coincide with each other when b2=4c; i.e., the black hole becomes extremal. Moreover, when b=0 and c<0, the black hole is reduced to the static Banados-Teitelboim-Zanelli (BTZ) black hole [97, 99].
In this work, the effect of the GUP on the Hawking temperature of the black hole was investigated by tunneling of the massive vector boson particle. In this investigation, the Kemmer matrices and spin connection coefficients from [34] were employed. Inserting the following ansatz for the modified wave function [74],(11)Ψ~x=expiħSt,r,ϕAt,r,ϕBt,r,ϕBt,r,ϕDt,r,ϕ,in (9) and neglecting the terms with ħ, we obtain the following three decoupled differential equations: (12)BiL2r∂S∂ϕ+iα1r3∂S∂ϕ3-αfr2∂S∂ϕ2∂S∂r+αL2m02f∂S∂r-L2f∂S∂r+Biαfr∂S∂ϕ∂S∂r2-αff∂S∂r3-iαm02L2r∂S∂ϕ+AiαLm02r2∂S∂ϕ2+iαLm0f2∂S∂r2+iL3m01-αm022+iL2f∂S∂t=0A-L2f∂S∂r-iαfr∂S∂ϕ∂S∂r2+iαm02L2r∂S∂ϕ-αff∂S∂r3-iα1r3∂S∂ϕ3+A-iL2r∂S∂ϕ-αfr2∂S∂ϕ2∂S∂r+αL2fm02∂S∂r+DiL2r∂S∂ϕ-iαm02L2r∂S∂ϕ+iαfr∂S∂ϕ∂S∂r2-L2f∂S∂r-αff∂S∂r3+DαL2m02f∂S∂r+iα1r3∂S∂ϕ3-αfr2∂S∂ϕ2∂S∂r+BiL3m01-αm0+iαLm0f∂S∂r2+iαm0Lr2∂S∂ϕ2=0B-L2f∂S∂r-iL2r∂S∂ϕ-αfr2∂S∂ϕ2∂S∂r+αL2m02∂S∂r-iα1r3∂S∂ϕ3+B-iαfr∂S∂ϕ∂S∂r2+iαm02L2r∂S∂ϕ-αff∂S∂r3+DiL3m01-αm022+iαLm02r2∂S∂ϕ2+iαLm0f2∂S∂r2-iL2f∂S∂t=0.where A(t,r,ϕ), B(t,r,ϕ), and D(t,r,ϕ) are functions of the space-time coordinates and S(t,r,ϕ) is the particle trajectory known as classical action. The nontrivial solution was found by the condition put on the determinants of the coefficients. Accordingly, we get the modified Hamilton-Jacobi equation as(13)1f∂S∂t2-1r2∂S∂ϕ2-f∂S∂r2-m02L24+α9m02f4∂S∂r2+1L2∂S∂t2∂S∂r2+α-6fL2r2∂S∂r2∂S∂ϕ2+9m024r2∂S∂ϕ2+3m04L24-3f2L2∂S∂r4-3L2r4∂S∂ϕ4+α1L2r2f∂S∂t2∂S∂ϕ2-m02f∂S∂t2=0.Using the separation of variables method, the action function, St,r,ϕ, is decomposed into its components as follows:(14)St,r,ϕ=-Et+jϕ+Kr+C,where E and j are the energy and total angular momentum of the particle, respectively, K(r)=K0(r)+αK1(r) [65], and the C is a complex constant. Inserting (14) into (13), we get the radial trajectory function, Kr, of the particle as follows:(15)K±r=±∫E2-fm02+j2/r2f1+αχdrwhere χ is (16)χ=14L2f5E2L2m02f-4E4E2-fm02+j2/r2. Here, K+r and K-r represent the radial trajectories of the outgoing and incoming particles on the outer horizon, respectively. Therefore, the integration in (15) is calculated as(17)K±r=±iπEr+-r-1+αΩ.Here Ω is (18)Ω=r+-r-29L2m02r+2-4j2+16E2r+28L2r+2r+-r-2. Accordingly, the outgoing and ingoing probabilities of the massive vector boson particles crossing the outer horizon are given by(19)Pout=exp-2ħImK+rPin=exp-2ħImK-r,respectively. Furthermore, the total tunneling probability of the massive vector boson particle crossing the horizon is expressed as [20](20)Γ=e-2/ħImSt,r,ϕ=PoutPin.Using (19) and (20) and the fact that ImK+r=-ImK-r, the total tunneling probability is obtained as follows:(21)Γ=exp-4ħImK+r=exp-4πEr+-r-1+αΩ.On the other hand, the tunneling probability can be expressed in terms of Boltzmann factor as(22)Γ=e-2/ħImS=e-βE,where β is the inverse of temperature. Finally, the modified Hawking temperature becomes(23)TH′=ħr+-r-4π1+αΩ-1.If we expand the TH′ in terms of the α powers and neglect the higher order terms, the modified Hawking temperature of the new-type black hole becomes as follows:(24)TH′=TH1-αΩ,where the TH=ħr+-r-/4π is the standard Hawking temperature of the black hole. From the TH′ expression, we see that the modified Hawking temperature can be related not only to the mass of the black hole, but also to the AdS3 radius L (and, hence, to the graviton mass) and the properties of the tunneled massive vector boson, such as angular momentum, energy, and mass. In addition, this result indicates that the modified Hawking temperature caused by tunneling vector boson particle is completely different from that of both scalar and Dirac particles [73]. Therefore, in the framework of the GUP, one can say that massive spin-0 scalar, massive spin-1/2 Dirac, and massive spin-1 vector boson particles probe the black hole in different manners. On the other hand, in the case of α=0, the modified Hawking temperature is reduced to the standard temperature obtained by quantum tunneling process of the point particles with spin-0, spin-1/2, and spin-1, respectively [32, 34].
The local stability of a black hole can be analyzed by its heat capacity [101]. The positive heat capacity means that black hole is locally stable; otherwise it is unstable [102–104]. The modified heat capacity of a black hole can be calculated from the relation(25)C′=∂M∂TH′where TH′ is the modified Hawking temperature given in (23) and M is mass of the black hole given as [99](26)M=r+2-r-216Gwith gravitational constant G. Hence, using (23) and (26), the modified heat capacity of the black hole is calculated as(27)C′=πr+-r-2ħG+απ9L2m02r+5+9L2m02r+3r-2+4j2r+3+20r+j2r-216ħGL2r+3r+-r--απ18L2m02r+4r-+16E2r+3+16j2r+2r-+8j2r+316ħGL2r+3r+-r-or(28)C′=πA-B16ħGL2r+3r+-r-,where the abbreviations A and B are (29)A=8L2r+5+8L2r+3r-2+9αL2m02r+5+4αj2r+3+9αL2m02r+3r-2+20αj2r+r-2,B=16L2r+4r-+18αL2m02r+4r-+16αj2r-r+2+16αE2r+3+8αj2r-3, respectively. The points where the heat capacity vanishes or diverges represent the phase transition points where the black hole transfers from an unstable state to a stable state. The points, where the heat capacity is vanished correspond to a first-order phase transition while the diverged points correspond to a second-order phase transition. According to (28), the modified heat capacity diverges at point r+=r-. This indicates that the black hole is stabilized by passing through a second-order phase transition. The modified heat capacity is positive for r+>r-. Hence in this region, the black hole is said to be locally stable. However, for r+<r-, the black hole is locally unstable. On the other hand, for r+>r-, the modified heat capacity vanishes at point A=B. This case indicates that the black hole undergoes a first-order phase transition to become stable. In the absence of the GUP effect the heat capacity becomes as(30)C=πr+-r-2ħG.According to this, it can be said that the heat capacity vanishes at point r+=r- whereas there is no point where it diverges. This indicates that the black hole has become stable through only the first-order phase transition.
4. Summary and Conclusion
In this study, we investigate the quantum gravity effect on the tunneling massive vector boson from the new-type black hole in the context of the 2+1 dimensional New Massive Gravity. For this, using the GUP relations, we first modified the massive vector boson equation. Then, using the Hamilton-Jacobi approach, the tunneling probability of the massive vector particle was derived, and, subsequently, the modified Hawking temperature of the black hole was calculated. We also found that the modified Hawking temperature not only depends on the black hole’s properties, but also depends on the emitted spin-1 vector boson’s mass, energy, and total angular momentum. It is also worth mentioning that the modified Hawking temperature is seen to be dependent on the mass of graviton in this context. As can be seen from (24), the Hawking temperature increases by the total angular momentum of the tunneled particle while it decreases by the energy and mass of the tunneled particle and the graviton mass.
In addition, according to (24), we can summarize some important results as follows:
If 9r+2(r+-r-)2m02/m2+16E2r+2>4j2(r+-r-)2, the modified Hawking temperature of the tunneling vector boson is lower than the standard temperature. However, when 9r+2(r+-r-)2m02/m2+16E2r+2<4j2(r+-r-)2, the corrected temperature is higher than the standard temperature. If 9r+2(r+-r-)2m02/m2+16E2r+2=4j2(r+-r-)2, then the contribution of the GUP effect is canceled, and the modified temperature of the tunneling vector boson reduces to the standard temperature.
As described previously, the new-type black hole is reduced to the static BTZ black hole in the case of b=0 and c<0. Hence, the modified Hawking temperature of the static BTZ black hole under the GUP effect is(31)TH′=TH1-αm29m02/2m2c-4j2+4E24c,
where r+=-r-=c is used and TH=ħc/2π is the standard Hawking temperature of the static BTZ black hole in the context of the 2+1 dimensional New Massive Gravity theory [32]. In this case, the modified Hawking temperature is higher than the standard Hawking temperature when 4E2+9m02/2m2c<4j2. On the other hand, as 4E2+9m02/2m2c>4j2, the modified Hawking temperature is lower than the standard Hawking temperature.
In the absence of the quantum gravity effect, i.e., α=0, the modified Hawking temperature is reduced to the standard temperature obtained by quantum tunneling of the massive spin-0, spin-1/2, and spin-1 point particles [32, 34].
In this study we also consider the local stability of the black hole under the GUP effect. At that case, we observe that in the absence of quantum gravity effect, the black hole undergoes first-order phase transition only, but, in the presence of the quantum gravity effect, it undergoes the first- and second-order phase transitions to become stable.
Data Availability
No data were used to support this study.
Conflicts of Interest
The authors declare that there are no conflicts of interest regarding the publication of this paper.
Acknowledgments
This work was supported by Akdeniz University Scientific Research Projects Unit, and the Scientific and Technological Research Council of Turkey (TUBITAK) 1002-QSP (Project no. 116F329).
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