Temperature and entropy of Schwarzschild–de Sitter space-time

Abstract: In the light of recent interest in quantum gravity in de Sitter space, we investigate semi-classical aspects of 4-dimensional Schwarzschild-de Sitter space-time using the method of complex paths. The standard semi-classical techniques (such as Bogoliubov coefficients and Euclidean field theory) have been useful to study quantum effects in space-times with single horizons; however, none of these approaches seem to work for Schwarzschild-de Sitter or, in general, for space-times with multiple horizons. We extend… Show more

“…On the other hand, Shankaranarayanan et al have applied the tunneling approach to obtain the Hawking temperature in different coordinates within a Complex paths scenario [20]. This technique has been successfully applied to obtain a global temperature for multi-horizon spacetimes [21]. In this paper, we are going to develop Parikh-Wilczek method to noncommutative coordinate coherent states.…”

Hawking radiation as quantum tunneling from a noncommutative Schwarzschild black hole

“…On the other hand, Shankaranarayanan et al have applied the tunneling approach to obtain the Hawking temperature in different coordinates within a Complex paths scenario [20]. This technique has been successfully applied to obtain a global temperature for multi-horizon spacetimes [21]. In this paper, we are going to develop Parikh-Wilczek method to noncommutative coordinate coherent states.…”

Hawking radiation as quantum tunneling from a noncommutative Schwarzschild black hole

“…On the positive sides, this method has been successfully applied to different types of horizons including anti-de Sitter(AdS) [24], de Sitter(dS) [20,21,22,23], BTZ [25,26],higher dimensional black holes and some exotic spacetimes [27,29,30,31] apart from the more conventional types of black holes, in each case producing the corresponding Hawking temperature correctly. Also, as the derivation involves only the local geometry, the tunnelling method can be applied to any local horizon, in particular to cosmological and weakly isolated horizons [28,29].…”

Near-extremal black holes

“…In this way, the tunneling approach turns out to be very useful when one wishes to incorporate back-reaction effects in order to describe black hole evaporation. In addition, even though calculations in the tunneling formalism are straightforward and relatively simple, they are robust in the sense that they can be applied to a wide variety of spacetimes [12][13][14][15][16][17][18][19][20][21][22][23][24][25].…”

Quantum Tunneling Radiation from Loop Quantum Black Holes and the Information Loss Paradox