Magnetized accretion disks around Kerr black holes with scalar hair: Constant angular momentum disks

Gimeno-Soler, Sergio; Font, José A.; Herdeiro, Carlos; Radu, Eugen

doi:10.1103/physrevd.99.043002

Cited by 24 publications

(34 citation statements)

References 74 publications

(179 reference statements)

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“…Finally, we note that the similarities we have found in the evolutions of approaches KMh and KMρ are expected due to the small deviation of the value h 1 for a potential gap of |∆W | = 0.2216. However, other types of compact objects might provide larger potential gaps (e.g., the Kerr black holes with scalar hair described in Gimeno-Soler et al (2019) achieve values of |∆W | > 1). For this reason, we could expect to find differences in the evolution between approaches KMh and KMρ for such central objects even for low magnetised discs.…”

Section: Discussionmentioning

confidence: 99%

“…(26) that ρ c = 1/(1 − |W c − W in |) < 1. The interested reader is addressed to Gimeno-Soler & Font (2017) and Gimeno-Soler et al (2019) for an extensive discussion on the morphology of magnetised discs for different degrees of magnetisation.…”

Section: Initial Datamentioning

confidence: 99%

“…To this aim we build magnetised Polish doughnuts around rotating black holes, neglecting the self-gravity of the discs and using three different approaches to account for the magnetic field, namely: i) a purely hydrodynamical solution (see e.g. Abramowicz et al (1978); Font & Daigne (2002); Daigne & Font (2004)) in which an 'ad hoc' toroidal magnetic field is seeded afterwards; ii) the self-consistent solution from Komissarov (2006), in which the distribution of the rest-mass density of the disc is coupled to the toroidal magnetic field through the equation of state for the magnetic pressure; this approach assumes that the fluid is thermodynamically non-relativistic; and iii) the self-consistent approach of Komissarov (2006) but dropping the assumption of a thermodynamically nonrelativistic fluid, as done in Montero et al (2007) and Gimeno-Soler et al (2019). Using these three approaches we build initial data and compare their non-linear dynamical evolutions by means of axisymmetric numerical simulations, finding interesting differences.…”

Section: Introductionmentioning

confidence: 99%

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Non-linear evolutions of magnetized thick discs around black holes: dependence on the initial data

Cruz-Osorio

Gimeno-Soler

Font

2020

Monthly Notices of the Royal Astronomical Society

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We build equilibrium solutions of magnetised thick discs around a highly spinning Kerr black hole and evolve these initial data up to a final time of about 100 orbital periods. The numerical simulations reported in this paper solve the general relativistic magnetohydrodynamics equations using the BHAC code and are performed in axisymmetry. Our study assumes nonself-gravitating, polytropic, constant angular momentum discs endowed with a purely toroidal magnetic field. In order to build the initial data we consider three approaches, two of which incorporate the magnetic field in a self-consistent way and a third approach in which the magnetic field is included as a perturbation on to an otherwise purely hydrodynamical solution. To test the dependence of the evolution on the initial data, we explore four representative values of the magnetisation parameter spanning from almost hydrodynamical discs to very strongly magnetised tori. The initial data are perturbed to allow for mass and angular momentum accretion on to the black hole. Notable differences are found in the long-term evolutions of the initial data. In particular, our study reveals that highly magnetised discs are unstable, and hence prone to be fully accreted and expelled, unless the magnetic field is incorporated into the initial data in a self-consistent way.

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Section: Discussionmentioning

confidence: 99%

Section: Initial Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Non-linear evolutions of magnetized thick discs around black holes: dependence on the initial data

Cruz-Osorio

Gimeno-Soler

Font

2020

Monthly Notices of the Royal Astronomical Society

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“…The results herein indicate no significant differences are to be expected with respect to the m = 1 case in these models. It would, nonetheless, be interesting to study some phenomenological properties of this higher m solutions, such as BH shadows [17,28], X-ray spectrum [31], accretion disk morphology [64] or star trajectories [38], since these higher m solutions could play a role in the dynamical evolution of the BH/fundamental field system, in case such fundamental, ultra-light, scalar or vector fields exist in Nature.…”

Section: Discussionmentioning

confidence: 99%

Kerr black holes with synchronised scalar hair and higher azimuthal harmonic index

2019

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Kerr black holes with synchronised scalar hair and azimuthal harmonic index m > 1 are constructed and studied. The corresponding domain of existence has a broader frequency range than the fundamental m = 1 family; moreover, larger ADM masses, M and angular momenta J are allowed. Amongst other salient features, non-uniqueness of solutions for fixed global quantities is observed: solutions with the same M and J co-exist, for consecutive values of m, and the ones with larger m are always entropically favoured. Our analysis demonstrates, moreover, the qualitative universality of various features observed for m = 1 solutions, such as the shape of the domain of existence, the typology of ergo-regions, and the horizon geometry, which is studied through its isometric embedding in Euclidean 3-space. IntroductionKerr black holes (BHs) with synchronised scalar hair [1] are a counterexample to the no-hair conjecture [2]see [3-5] for reviews -occurring in a simple and physically sound model: Einstein-(complex and massive-)Klein-Gordon theory. Many related solutions, relying on a similar synchronisation mechanism, have been found in the last few years, in different setups and approximations. An incomplete list of references, including also various studies of physical properties, is .These hairy BH solutions have a relation with the physical phenomenon of superradiance [67], from which they can form dynamically from the Kerr solution [45-47] -see also [54,57] for a discussion on the metastability of these solutions against superradiance. They also reduce to Kerr BHs and boson stars [68,69], in appropriate limits. Boson stars are a sort of gravitating soliton interpreted as a Bose-Einstein condensate of an ultra-light scalar field, that could be a dark matter candidate [70,71]. Moreover, the existence of the hairy BH solutions does not rely on particular choices of scalar field potentials that violate energy conditions, unlike other examples of asymptotically flat BHs with scalar hair, see e.g. [72,73]. Thus, besides the issue of the no-hair conjecture in BH physics, these hairy BHs contain different angles of interest.Kerr BHs with synchronised hair comprise a family that, besides the continuous parameters mass, angular momentum and Noether charge, is labelled by two discrete numbers: the azimuthal harmonic index of the scalar field m ∈ Z + and its node number n. Most of the studies of the solutions have focused on the fundamental solutions, n = 0, with the smallest value of m = 1. Recently, excited solutions (n = 0) have also been constructed [63]. Solutions with m > 1, on the other hand, have only been considered in the solitonic (boson star) limit [14,74], with the exception of the non-minimal model studied in [16]. The purpose of this work is to construct solutions with m > 1 in the minimal, simplest model, and to study some of the basic physical properties of these new solutions.

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“…Thus, proposing and developing semi-analytical accretion and emission models (Bambi & Modesto 2013;Younsi et al 2016;Pu & Broderick 2018;Gimeno-Soler et al 2019;Narayan et al 2019;Gan et al 2021;Yang et al 2021), and studying the variation of image features with these models and with varying spacetime geometry, as a path-finding step, could already yield important insights. Such analyses require fewer expensive operations such as integrations, and greatly reduce the overall computational cost, enabling a broader parameter survey.…”

Section: Introductionmentioning

confidence: 99%

Distinguishing gravitational and emission physics in black-hole imaging: spherical symmetry

Kocherlakota,

Rezzolla

2022

Preprint

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Imaging a supermassive black hole and extracting physical information requires good knowledge of both the gravitational and the astrophysical conditions near the black hole. When the geometrical properties of the black hole are well understood, extracting information on the emission properties is possible. Similarly, when the emission properties are well understood, extracting information on the black-hole geometry is possible. At present however, uncertainties are present both in the geometry and in the emission, and this inevitably leads to degeneracies in the interpretation of the observations. We explore here the impact of varying geometry and emission coefficient when modelling the imaging of a spherically-accreting black hole. Adopting the Rezzolla-Zhidenko parametric metric to model arbitrary static black-holes, we first demonstrate how shadow-size measurements leave degeneracies in the multidimensional space of metric-deviation parameters, even in the limit of infinite-precision measurements. Then, at finite precision, we show that these degenerate regions can be constrained when multiple pieces of information, such as the shadow-size and the peak image intensity contrast, are combined. Such degeneracies can potentially be eliminated with measurements at increased angular-resolution and flux-sensitivity. While our approach is restricted to spherical symmetry and hence idealised, we expect our results to hold also when more complex geometries and emission processes are considered.

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Magnetized accretion disks around Kerr black holes with scalar hair: Constant angular momentum disks

Cited by 24 publications

References 74 publications

Non-linear evolutions of magnetized thick discs around black holes: dependence on the initial data

Non-linear evolutions of magnetized thick discs around black holes: dependence on the initial data

Kerr black holes with synchronised scalar hair and higher azimuthal harmonic index

Distinguishing gravitational and emission physics in black-hole imaging: spherical symmetry

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