Growth of Perturbations in Tsallis and Barrow Cosmology

Farsi, Bita; Sheykhi, Ahmad

doi:10.48550/arxiv.2205.04138

Cited by 3 publications

(9 citation statements)

References 64 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This entropy model has later been considered as a model for holographic dark energy [387,388] (see also Refs. [389][390][391][392][393][394][395][396][397][398][399][400][401][402][403][404][405][406][407][408]). In the toy model considered, a three-dimensional FIG.…”

Section: T Barrow Entropy Modifications To the Schwarzschild Metricmentioning

confidence: 99%

Horizon-scale tests of gravity theories and fundamental physics from the Event Horizon Telescope image of Sagittarius A$^*$

Vagnozzi¹,

Roy²,

Tsai³

et al. 2022

Preprint

View full text Add to dashboard Cite

Horizon-scale images of black holes (BHs) and their shadows have opened an unprecedented window onto tests of gravity and fundamental physics in the strong-field regime, allowing us to test whether the Kerr metric provides a good description of the space-time in the vicinity of the event horizons of supermassive BHs. We consider a wide range of well-motivated deviations from classical General Relativity solutions, and constrain them using the Event Horizon Telescope (EHT) observations of Sagittarius A * (SgrA * ), connecting the size of the bright ring of emission to that of the underlying BH shadow and exploiting high-precision measurements of SgrA * 's mass-to-distance ratio. The scenarios we consider, and whose fundamental parameters we constrain, include various regular BH models, string-and non-linear electrodynamics-inspired space-times, scalar field-driven violations of the no-hair theorem, alternative theories of gravity, new ingredients such as the generalized uncertainty principle and Barrow entropy, and BH mimickers including examples of wormholes and naked singularities. We demonstrate that SgrA * 's image places particularly stringent constraints on models predicting a shadow size which is larger than that of a Schwarzschild BH of a given mass: for instance, in the case of Barrow entropy we derive constraints which are significantly tighter than the cosmological ones. Our results are among the first tests of fundamental physics from the shadow of SgrA * and, while the latter appears to be in excellent agreement with the predictions of General Relativity, we have shown that various well-motivated alternative scenarios (including BH mimickers) are far from being ruled out at present.

show abstract

Section: T Barrow Entropy Modifications To the Schwarzschild Metricmentioning

confidence: 99%

Horizon-scale tests of gravity theories and fundamental physics from the Event Horizon Telescope image of Sagittarius A$^*$

Vagnozzi¹,

Roy²,

Tsai³

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…However the "bare" gravitational constant G that appears at the level of the action is not the same as the effective G eff that appears in the modified Friedmann equation Eq. (10). Also, the Barrow entropy itself contains A 0 = 4G, which is the "bare" G. The fact that the G eff is smaller in the early universe could suggests that we may be able to ameliorate the arrow of time problem [41][42][43][44][45][46][47][48][49][50] following the same line of thought of Greene et.…”

Section: Discussionmentioning

confidence: 99%

“…Typically, the effective gravitational constant that governs structure formation may not be the same as the G eff that appears in the background Friedmann equation, which may also differ from the "bare" G. A concrete example is provided in [53]. Structure formation in the case of fixed BEI has been recently studied in [10]. In fact, a varying gravitational constant would cause many issues and early time cosmology would need to be re-examined in close details [54] (for example, CMB angular power spectrum would be modified [40,54]).…”

Section: Discussionmentioning

confidence: 99%

“…In this work, we will argue that δ has to be a function of energy scale and study the implications of Barrow entropy to cosmology (by the expansion of the universe, δ is thus a function of cosmic time). Such a possibility was also raised in [7,10]. We expect that, as quantum gravitational effects become more pronounced near the Big Bang, δ → 1.…”

Section: Introduction: Barrow Entropy and Quantum Gravitymentioning

confidence: 88%

See 1 more Smart Citation

Sign Switching Dark Energy from a Running Barrow Entropy

Di Gennaro,

Ong

2022

Preprint

View full text Add to dashboard Cite

“…In this work, we argue that δ has to be a function of the energy scale and study the implications of Barrow entropy for cosmology (by the expansion of the universe, δ is thus a function of cosmic time). Such a possibility was also raised in [7,10,11]. We expect that, as quantum gravitational effects become more pronounced near the Big Bang, δ → 1.…”

Section: Introduction: Barrow Entropy and Quantum Gravitymentioning

confidence: 89%

Sign Switching Dark Energy from a Running Barrow Entropy

Gennaro

Ong

2022

Universe

View full text Add to dashboard Cite

Barrow proposed that the area law of the entropy associated with a horizon might receive a “fractal correction” due to quantum gravitational effects—in place of S∝A, we have instead S∝A1+δ/2, where 0⩽δ⩽1 measures the deviation from the standard area law (δ=0). Based on black hole thermodynamics, we argue that the Barrow entropy should run (i.e., energy scale dependent), which is reasonable given that quantum gravitational corrections are expected to be important only in the high-energy regime. When applied to the Friedmann equation, we demonstrate the possibility that such a running Barrow entropy index could give rise to a dynamical effective dark energy, which is asymptotically positive and vanishing, but negative at the Big Bang. Such a sign switching dark energy could help to alleviate the Hubble tension. Other cosmological implications are discussed.

show abstract

Growth of Perturbations in Tsallis and Barrow Cosmology

Cited by 3 publications

References 64 publications

Horizon-scale tests of gravity theories and fundamental physics from the Event Horizon Telescope image of Sagittarius A$^*$

Horizon-scale tests of gravity theories and fundamental physics from the Event Horizon Telescope image of Sagittarius A$^*$

Sign Switching Dark Energy from a Running Barrow Entropy

Sign Switching Dark Energy from a Running Barrow Entropy

Contact Info

Product

Resources

About