H 0 Tension and the Phantom Regime: A Case Study in Terms of an Infrared f(T) Gravity

El-Zant, Amr; Hanafy, W. El; Elgammal, S.

doi:10.3847/1538-4357/aafa12

Cited by 31 publications

(28 citation statements)

References 87 publications

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“…[63,64]). Hopefully the present work will also contribute to the prospective use of the phenomenology of black holes to test teleparallel theories, like cosmology [65][66][67][68][69][70][71][72] and gravitational waves [73][74][75][76][77]. Funding: This research was funded by the Estonian Research Council through the projects IUT02-27, PUT790, and PRG356, as well as by the European Regional Development Fund through the Center of Excellence TK133 "The Dark Side of the Universe".…”

Section: Discussionmentioning

confidence: 99%

Flat Connection for Rotating Vacuum Spacetimes in Extended Teleparallel Gravity Theories

et al. 2019

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Teleparallel geometry utilizes Weitzenböck connection which has nontrivial torsion but no curvature and does not directly follow from the metric like Levi-Civita connection. In extended teleparallel theories, for instance in f (T) or scalar-torsion gravity, the connection must obey its antisymmetric field equations. So far only a few analytic solutions were known. In this note we solve the f (T, φ) gravity antisymmetric vacuum field equations for a generic rotating tetrad ansatz in Weyl canonical coordinates, and find the corresponding spin connection coefficients. By a coordinate transformation we present the solution also in Boyer-Lindquist coordinates, often used to study rotating solutions in general relativity. The result hints for the existence of another branch of rotating solutions besides the Kerr family in extended teleparallel gravities.

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Section: Discussionmentioning

confidence: 99%

Flat Connection for Rotating Vacuum Spacetimes in Extended Teleparallel Gravity Theories

et al. 2019

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“…In this model, core formation occurs from dark matter particles experiencing successive 'kicks' resulting from feedback-induced stochastic potential fluctuations, which cumulatively lead the particles to deviate from their trajectories as in a diffusion process. In the context of a fuzzy dark matter halo, Bar-Or et al (2018) similarly describe the effect on stars and black holes of stochastic density fluctuations due to the quantum nature of the dark matter particles they assume while Marsh & Niemeyer (2018) and El-Zant et al (2019) use the El-Zant et al (2016) model to place constraints on the fuzzy dark matter particle mass. .…”

Section: Motivation For This Workmentioning

confidence: 99%

A model for core formation in dark matter haloes and ultra-diffuse galaxies by outflow episodes

Freundlich¹,

Dekel

Jiang³

et al. 2019

Monthly Notices of the Royal Astronomical Society

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We present a simple model for the response of a dissipationless spherical system to an instantaneous mass change at its center, describing the formation of flat cores in dark matter haloes and ultra-diffuse galaxies (UDGs) from feedback-driven outflow episodes in a specific mass range. This model generalizes an earlier simplified analysis of an isolated shell into a system with continuous density, velocity and potential profiles. The response is divided into an instantaneous change of potential at constant velocities due to a given mass loss or gain, followed by energy-conserving relaxation to a new Jeans equilibrium. The halo profile is modeled by a two-parameter function with a variable inner slope and an analytic potential profile , which enables to determine the associated kinetic energy at equilibrium. The model is tested against NIHAO cosmological zoom-in simulations, where it successfully predicts the evolution of the inner dark-matter profile between successive snapshots in about 75% of the cases, failing mainly in merger situations. This model provides a simple understanding of the formation of dark-matter halo cores and UDGs by supernova-driven outflows, and a useful analytic tool for studying such processes.

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“…ΛCDM model [50]. [52,53] or by utilizing infrared gravity [54], see also [55,56]. In modified gravity framework one may search for an explanation for the accelerated expansion without assuming DE (cosmological constant), however we should not expect great deviations from the ΛCDM scenario.…”

Section: A Flat λCdm Modelmentioning

confidence: 99%

“…In fact, the local CMB and BAO observations (preassume ΛCDM model) favor a value of H 0 ≃ 68 km/s/Mpc and Ω m,0 ≃ 0.3, this is on contrary to the global SNIa and H 0 observations (model independent) which favor a larger H 0 ≃ 73 km/s/Mpc and smaller Ω m,0 ≃ 0.26. However, several approaches have been suggested to to reconcile local with global measurements by introducing dark neutrino species [51], using dynamical phantom DE [52,53] or by utilizing infrared gravity [54], see also [55,56]. In modified gravity framework one may search for an explanation for the accelerated expansion without assuming DE (cosmological constant), however we should not expect great deviations from the ΛCDM scenario.…”

Section: A Flat λCdm Modelmentioning

confidence: 99%

Phenomenological reconstruction of f(T) teleparallel gravity

Hanafy

Nashed

2019

Phys. Rev. D

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We present a novel reconstruction method of f (T ) teleparallel gravity from phenomenological parametrizations of the deceleration parameter or other alternatives. This can be used as a toolkit to produce viable modified gravity scenarios directly related to cosmological observations. We test two parametrizations of the deceleration parameter considered in recent literatures in addition to one parametrization of the effective (total) equation of state (EoS) of the universe. We use the asymptotic behavior of the matter density parameter as an extra constraint to identify the viable range of the model parameters. One of the tested models shows how tiny modification can produce viable cosmic scenarios quantitatively similar to ΛCDM but qualitatively different whereas the dark energy (DE) sector becomes dynamical and fully explained by modified gravity not by a cosmological constant.

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H ₀ Tension and the Phantom Regime: A Case Study in Terms of an Infrared f(T) Gravity

Cited by 31 publications

References 87 publications

Flat Connection for Rotating Vacuum Spacetimes in Extended Teleparallel Gravity Theories

Flat Connection for Rotating Vacuum Spacetimes in Extended Teleparallel Gravity Theories

A model for core formation in dark matter haloes and ultra-diffuse galaxies by outflow episodes

Phenomenological reconstruction of f(T) teleparallel gravity

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