We investigate the Generalized Uncertainty Principle (GUP) effect on the Hawking radiation of the 2+1 dimensional Martinez-Zanelli black hole by using the Hamilton-Jacobi method. In this connection, we discuss the tunnelling probabilities and Hawking temperature of the spin-1/2 and spin-0 particles for the black hole. Therefore, we use the modified Klein-Gordon and Dirac equations based on the GUP. Then, we observe that the Hawking temperature of the scalar and Dirac particles depend on not only the black hole properties, but also the properties of the tunnelling particle, such as angular momentum, energy and mass. And, in this situation, we see that the tunnelling probability and the Hawking radiation of the Dirac particle is different from that of the scalar particle.
In the framework of the three dimensional New Massive
Gravity theory introduced by Bergshoeff, Hohm and Townsend, we
analyze the behavior of relativistic spin-1/2 and spin-0 particles
in the New-type Black Hole backgroud, solution of the New Massive
Gravity.We solve Dirac equation for spin-1/2 and Klein-Gordon
equation for spin-0. Using Hamilton-Jacobi method, we discuss tunnelling
probability and Hawking temperature of the spin-1/2 and spin-0
particles for the black hole. We observe that the tunnelling
probability and Hawking temperature are same for the spin-1/2 and spin-0.
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 AdS 3 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.
In this paper, we consider a gravitational theory including a Dirac field that is non-minimal coupled to gravity in 2 + 1 dimensions. Noether gauge symmetry approach can be used to fix the form of coupling function F (Ψ) and the potential V (Ψ) of the Dirac field and to obtain a constant of motion for the dynamical equations. In the context of 2 + 1 dimensions gravity, we investigate cosmological solutions of the field equations using these forms obtained by the existent of Noether gauge symmetry. In this picture, it is shown that for the non-minimal coupling case, the cosmological solutions indicate both an early-time inflation and late-time acceleration for the universe.PACS numbers:
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