Probing Loop Quantum Gravity with Evaporating Black Holes

We introduce the notion of fluid approximation of a quantum spherical black hole in the context of Loop Quantum Gravity. In this limit, the microstates of the black hole are intertwiners between "large" representations s i which typically scale as s i ∼ √ a H where a H denotes the area of the horizon in Planck units. The punctures with large colors are, for the black hole horizon, similar to what are the fluid parcels for a classical fluid. We dub them puncels. Hence, in the fluid limit, the horizon is composed by puncels which are themselves interpreted as composed (in the sense of the tensor product) by a large number of more fundamental intertwiners. We study the spectrum of the euclidean volume acting on puncels and we compute its quantum fluctuations. Then, we propose an interpretation of black holes radiation based on the properties of the quantum fluctuations of the euclidean volume operator. We estimate a typical temperature of the black hole and we show that it scales as the Hawking temperature.

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“…Note that the black hole spectrum in the deep quantum regime (when n is small) has been studied numerically in [49,50] for instance.…”

Section: Discussionmentioning

confidence: 99%

Semiclassical analysis of black holes in loop quantum gravity: Modeling Hawking radiation with volume fluctuations

2017

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“…More precisely, we describe the black hole radiation process using statistical mechanical techniques together with some assumptions about the dynamical behavior of BHs close to equilibrium. In doing this we will basically follow the ideas of [27] leading to the computation of the integrated emission spectrum for a black hole (under some assumptions which will be made precise later). The simulated spectrography will allow for the study of deviations predicted by the old and new (holographic) models of LQG from the semiclassical Hawk-ing process expectation.…”

Section: Introductionmentioning

confidence: 99%

Black hole spectroscopy from loop quantum gravity models

et al. 2015

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Using Monte Carlo simulations, we compute the integrated emission spectra of black holes in the framework of Loop Quantum Gravity (LQG). The black hole emission rates are governed by the entropy whose value, in recent holographic loop quantum gravity models, was shown to agree at leading order with the Bekenstein-Hawking entropy. Quantum corrections depend on the Barbero-Immirzi parameter γ. Starting with black holes of initial horizon area A ∼ 10 2 in Planck units, we present the spectra for different values of γ. Each spectrum clearly decomposes in two distinct parts: a continuous background which corresponds to the semi-classical stages of the evaporation and a series of discrete peaks which constitutes a signature of the deep quantum structure of the black hole. We show that γ has an effect on both parts that we analyze in details. Finally, we estimate the number of black holes and the instrumental resolution required to experimentally distinguish between the considered models.

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“…The idea proposed in [39] is to search for possible LQG signatures in the spectrum of evaporating black holes. The state counting for black holes in LQG relies on the isolated horizon framework (that is a boundary of the underlying manifold considered before quantization).…”

Section: Black Holesmentioning

confidence: 99%

“…However it was understood in [41,42] that the situation is different in LQG because the spacing of the energy levels decreases exponentially with the energy. In [39], this issue was readdressed and it was shown that several different signatures can in fact be expected.…”

Section: Black Holesmentioning

confidence: 99%