Michele Arzano scite author profile

In several approaches to the quantum-gravity problem evidence has emerged of the validity of a "GUP" (a Generalized position-momentum Uncertainty Principle) and/or a "MDR" (a modification of the energy-momentum dispersion relation), but very little is known about the implications of GUPs and MDRs for black-hole thermodynamics, another key topic for quantum-gravity research. We investigate an apparent link, already suggested in an earlier exploratory study involving two of us, between the possibility of a GUP and/or a MDR and the possibility of a log term in the area-entropy black-hole formula. We then obtain, from that same perspective, a modified relation between the mass of a black hole and its temperature, and we examine the validity of the "Generalized Second Law of black-hole thermodynamics" in theories with a GUP and/or a MDR. After an analysis of GUP-and MDR-modifications of the black-body radiation spectrum, we conclude the study with a description of the black-hole evaporation process.

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Hawking radiation as tunneling through the quantum horizon

Arzano

Medved

Vagenas

2005

J. High Energy Phys.

265

247

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Planck-scale corrections to the black-hole radiation spectrum in the Parikh-Wilczek tunneling framework are calculated. The corrective terms arise from modifications in the expression of the surface gravity in terms of the mass-energy of the black hole-emitted particle system.The form of the new spectrum is discussed together with the possible consequences for the fate of black holes in the late stages of evaporation.

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Dimensional reduction in the sky

et al. 2013

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We explore the cosmological implications of a mechanism found in several approaches to quantum-gravity, whereby the spectral dimension of spacetime runs from the standard value of 4 in the infrared (IR) to a smaller value in the ultraviolet (UV). Specifically, we invoke the picture where the phenomenon is associated with modified dispersion relations. With minimal assumptions, we find that UV behaviour leading to 2 spectral dimensions results in an exactly scale-invariant spectrum of vacuum scalar and tensor fluctuations, regardless of the equation of state. The fluctuation production mechanism is analogous to the one known for varying speed of sound/light models and, unlike in inflation, the spectrum is already scale-invariant before leaving the horizon, remaining so after freeze-in. In the light of Planck's recent results we also discuss scenarios that break exact scale-invariance, such as the possibility that the spectral dimension runs down to a value slightly higher than 2, or runs down to 2 but with an extremely slow transient. We further show that the tensor to scalar ratio is fixed by the UV ratio between the speed of gravity and the speed of light. Not only does our model not require inflation, but at its most minimal it seems incompatible with it. In contrast, we find that running spectral dimensions can improve the outlook of the cyclic/ekpyrotic scenario, solving the main problems present in its simplest and most appealing realisations.

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Coproduct and star product in field theories on Lie-algebra noncommutative space-times

2002

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We propose a new approach to field theory on κ-Minkowski non-commutative space-time, a popular example of Lie-algebra space-time. Our proposal is essentially based on the introduction of a star product, a technique which is proving to be very fruitful in analogous studies of canonical non-commutative space-times, such as the ones recently found to play a role in the description of certain string-theory backgrounds. We find to be incorrect the expectation, previously reported in the literature, that the lack of symmetry of the κ-Poincaré coproduct should lead to Green functions that are not symmetric under exchanges of the momenta of identical particles entering the relevant processes. We show that in κ-Minkowski the star product must indeed treat momenta in a non-symmetric way, but the overall structure of Green functions is symmetric under exchange of identical particles.

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Generalizing the Noether Theorem for Hopf-Algebra Spacetime Symmetries

et al. 2007

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Over these past few years several quantum-gravity research groups have been exploring the possibility that in some Planck-scale nonclassical descriptions of spacetime one or another form of nonclassical spacetime symmetries might arise. One of the most studied scenarios is based on the use of Hopf algebras, but previous attempts were not successful in deriving constructively the properties of the conserved charges one would like to obtain from the Hopf structure, and this in turn did not allow a crisp physical characterization of the new concept of spacetime symmetry. Working within the example of κ-Minkowski noncommutative spacetime, known to be particularly troublesome from this perspective, we observe that these past failures in the search of the charges originated from not recognizing the crucial role that the noncommutative differential calculus plays in the symmetry analysis. We show that, if the properties of the κ-Minkowski differential calculus are correctly taken into account, one can easily perform all the steps of the Noether analysis and obtain an explicit formula relating fields and energy-momentum charges. Our derivation also exposes the fact that an apparent source of physical ambiguity in the description of the Hopf-algebra rules of action, which was much emphasized in the literature, actually only amounts to a choice of conventions and in particular does not affect the formulas for the charges.1 The space indices j, l take values in {1, 2, 3} while 0 is the time index. We shall later also use the spacetime indices µ, ν, α, which take values in {0, 1, 2, 3}.2 Rather than our length scale λ a majority of authors use the energy scale κ, which is the inverse of λ (λ → 1/κ). 3 One notices that κ-Minkowski and the κ-Poincaré Hopf algebra form a "Heisenberg double" [8,9], i.e. κ-Minkowski and κ-Poincaré are linked, as algebras, in a way that is rather similar to the relationship between classical Minkowski spacetime and the classical Poincaré Lie algebra.

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Michele Arzano

Black-hole thermodynamics with modified dispersion relations and generalized uncertainty principles

Hawking radiation as tunneling through the quantum horizon

Dimensional reduction in the sky

Coproduct and star product in field theories on Lie-algebra noncommutative space-times

Generalizing the Noether Theorem for Hopf-Algebra Spacetime Symmetries

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