Bound orbits around Bardeen black holes

Bound orbits around modified Hayward black holes

Modern Physics Letters A ◽

10.1142/s0217732321502370 ◽

2021 ◽

Author(s):

Bo Gao ◽

Xue-Mei Deng

Keyword(s):

Black Holes ◽

Black Hole ◽

Angular Momentum ◽

Gravitational Field ◽

Periodic Orbits ◽

Kerr Black Hole ◽

Periodic Oscillations ◽

Test Particles ◽

Spin Parameter ◽

Bound Orbits

The neutral time-like particle’s bound orbits around modified Hayward black holes have been investigated. We find that both in the marginally bound orbits (MBO) and the innermost stable circular orbits (ISCO), the test particle’s radius and its angular momentum are all more sensitive to one of the parameters [Formula: see text]. Especially, modified Hayward black holes with [Formula: see text] could mimic the same ISCO radius around the Kerr black hole with the spin parameter up to [Formula: see text]. Small [Formula: see text] could mimic the ISCO of small-spinning test particles around Schwarzschild black holes. Meanwhile, rational (periodic) orbits around modified Hayward black holes have also been studied. The epicyclic frequencies of the quasi-circular motion around modified Hayward black holes are calculated and discussed with respect to the observed Quasi-periodic oscillations (QPOs) frequencies. Our results show that rational orbits around modified Hayward black holes have different values of the energy from the ones of Schwarzschild black holes. The epicyclic frequencies in modified Hayward black holes have different frequencies from Schwarzschild and Kerr ones. These might provide hints for distinguishing modified Hayward black holes from Schwarzschild and Kerr ones by using the dynamics of time-like particles around the strong gravitational field.

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Null and Timelike Geodesics near the Throats of Phantom Scalar Field Wormholes

Universe ◽

10.3390/universe6100183 ◽

2020 ◽

Vol 6 (10) ◽

pp. 183

Author(s):

Ivan Potashov ◽

Julia Tchemarina ◽

Alexander Tsirulev

Keyword(s):

Black Holes ◽

Scalar Field ◽

Circular Orbit ◽

Realistic Model ◽

Test Particles ◽

Stable Circular Orbit ◽

Phantom Scalar ◽

Metric Function ◽

Bound Orbits ◽

Phantom Scalar Field

We study geodesic motion near the throats of asymptotically flat, static, spherically symmetric traversable wormholes supported by a self-gravitating minimally coupled phantom scalar field with an arbitrary self-interaction potential. We assume that any such wormhole possesses the reflection symmetry with respect to the throat, and consider only its observable “right half”. It turns out that the main features of bound orbits and photon trajectories close to the throats of such wormholes are very different from those near the horizons of black holes. We distinguish between wormholes of two types, the first and second ones, depending on whether the redshift metric function has a minimum or maximum at the throat. First, it turns out that orbits located near the centre of a wormhole of any type exhibit retrograde precession, that is, the angle of pericentre precession is negative. Second, in the case of high accretion activity, wormholes of the first type have the innermost stable circular orbit at the throat while those of the second type have the resting-state stable circular orbit in which test particles are at rest at all times. In our study, we have in mind the possibility that the strongly gravitating objects in the centres of galaxies are wormholes, which can be regarded as an alternative to black holes, and the scalar field can be regarded as a realistic model of dark matter surrounding galactic centres. In this connection, we discuss qualitatively some observational aspects of results obtained in this article.

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Global embeddings and hydrodynamic properties of Kerr black hole

Modern Physics Letters A ◽

10.1142/s0217732316502047 ◽

2016 ◽

Vol 31 (35) ◽

pp. 1650204

Author(s):

Soon-Tae Hong

Keyword(s):

Black Holes ◽

Black Hole ◽

Equatorial Plane ◽

Kerr Black Hole ◽

Kerr Spacetime ◽

Stable Circular Orbit ◽

Massive Particles ◽

Flat Embedding ◽

Bound Orbits ◽

The Impact

In the presence of a rotating Kerr black hole, we investigate hydrodynamics of the massive particles and massless photons to construct relations among number density, pressure and internal energy density of the massive particles and photons around the rotating Kerr black hole and to study an accretion onto the black hole. On equatorial plane of the Kerr black hole, we investigate the bound orbits of the massive particles and photons around the black hole to produce their radial, azimuthal and precession frequencies. With these frequencies, we study the black holes GRO J1655-40 and 4U 1543-47 to explicitly obtain the radial, azimuthal and precession frequencies of the massive particles in the flow of perfect fluid. We next consider the massive particles in the stable circular orbit of radius of 1.0 ly around the supernovas SN 1979C, SN 1987A and SN 2213-1745 in the Kerr curved spacetime, and around the potential supermassive Schwarzschild black holes M87, NGC 3115, NGC 4594, NGC 3377, NGC 4258, M31, M32 and Galatic center, to estimate their radial and azimuthal frequencies, which are shown to be the same results as those in no precession motion. The photon unstable orbit is also discussed in terms of the impact parameter of the photon trajectory. Finally, on the equatorial plane of the Kerr black hole, we construct the global flat embedding structures possessing (9 + 3) dimensionalities outside and inside the event horizon of the rotating Kerr black hole. Moreover, on the plane, we investigate the warp products of the Kerr spacetime.

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On the black holes in alternative theories of gravity: The case of nonlinear massive gravity

International Journal of Modern Physics D ◽

10.1142/s0218271815500224 ◽

2015 ◽

Vol 24 (03) ◽

pp. 1550022 ◽

Cited By ~ 16

Author(s):

Ivan Arraut

Keyword(s):

Black Holes ◽

Black Hole ◽

Degrees Of Freedom ◽

Massive Gravity ◽

Alternative Theories Of Gravity ◽

De Sitter ◽

Theories Of Gravity ◽

Bound Orbits ◽

Black Hole Temperature ◽

Alternative Theories

I derive general conditions in order to explain the origin of the Vainshtein radius inside dRGT. The set of equations, which I have called "Vainshtein" conditions are extremal conditions of the dynamical metric (gμν) containing all the degrees of freedom of the theory. The Vainshtein conditions are able to explain the coincidence between the Vainshtein radius in dRGT and the scale [Formula: see text], obtained naturally from the Schwarzschild de-Sitter (S-dS) space inside general relativity (GR). In GR, this scale was interpreted as the maximum distance in order to get bound orbits. The same scale corresponds to the static observer position if we want to define the black hole temperature in an asymptotically de-Sitter space. In dRGT, the scale marks a limit after which the extra degrees of freedom of the theory become relevant.

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Recoiling supermassive black holes in analytical and numerical galaxy potential

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stz2107 ◽

2019 ◽

Vol 488 (4) ◽

pp. 5566-5579

Author(s):

Majda Smole ◽

Miroslav Micic ◽

Ana Mitrašinović

Keyword(s):

Black Holes ◽

Active Galactic Nuclei ◽

Numerical Models ◽

Galactic Nuclei ◽

Supermassive Black Holes ◽

Analytical Models ◽

Analytical Potential ◽

Major Merger ◽

Realistic Description ◽

Bound Orbits

ABSTRACTWe follow trajectories of recoiling supermassive black holes (SMBHs) in analytical and numerical models of galaxy merger remnants with masses of 1011 M⊙ and 1012 M⊙. We construct various merger remnant galaxies in order to investigate how the central SMBH mass and the mass ratio of progenitor galaxies influence escape velocities of recoiling SMBHs. Our results show that static analytical models of major merger remnant galaxies overestimate the SMBHs escape velocities. During major mergers violent relaxation leads to the decrease of galaxy mass and lower potential at large remnant radii. This process is not depicted in static analytical potential but clearly seen in our numerical models. Thus, the evolving numerical model is a more realistic description of dynamical processes in galaxies with merging SMBHs. We find that SMBH escape velocities in numerical major merger remnant galaxies can be up to 25 per cent lower compared to those in analytical models. Consequently, SMBHs in numerical models generally reach greater galactocentric distances and spend more time on bound orbits outside of the galactic nuclei. Thus, numerical models predict a greater number of spatially offset active galactic nuclei (AGNs).

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Topological black holes in mimetic gravity

International Journal of Modern Physics A ◽

10.1142/s0217751x21501864 ◽

2021 ◽

Author(s):

Ahmad Sheykhi ◽

Saskia Grunau

Keyword(s):

Black Holes ◽

Black Hole ◽

Dark Matter ◽

Einstein Gravity ◽

Rotation Curves ◽

Negative Constant ◽

Massive Particles ◽

Bound Orbits ◽

Mimetic Gravity ◽

Black Hole Solutions

In this paper, we construct some new classes of topological black hole solutions in the context of mimetic gravity and investigate their properties. We study the uncharged and charged black holes, separately. We find the following novel results: (i) In the absence of a potential for the mimetic field, black hole solutions can address the flat rotation curves of spiral galaxies and alleviate the dark matter problem without invoking particle dark matter. Thus, mimetic gravity can provide a theoretical background for understanding flat galactic rotation curves through modifying Schwarzschild space–time. (ii) We also investigate the casual structure and physical properties of the solutions. We observe that in the absence of a potential, our solutions are not asymptotically flat, while in the presence of a negative constant potential for the mimetic field, the solutions are asymptotically anti-de Sitter (AdS). (iii) Finally, we explore the motion of massless and massive particles and give a list of the types of orbits. We study the differences of geodesic motion in the Einstein gravity and in mimetic gravity. In contrast to the Einstein gravity, massive particles always move on bound orbits and cannot escape the black hole in mimetic gravity. Furthermore, we find stable bound orbits for massless particles.

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