A stellar fly‐by close to the Galactic center: Can we detect stars on highly relativistic orbits?

Tursunov, Arman

doi:10.1002/asna.201813499

Cited by 8 publications

(5 citation statements)

References 27 publications

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“…Subsequently, the measured proper motions and relative velocities have been used to derive accelerations and stellar orbits for several S stars (Eckart et al, 2002;Schödel et al, 2002;Ghez et al, 2008;Gillessen et al, 2009;Boehle et al, 2016;Gillessen et al, 2017). In the future, this will allow to test the General Theory of Relativity based on the determined orbits of S stars (mainly S2) and potentially stars that will be found on even tighter orbits (Eckart et al, 2017;Parsa et al, 2017;Waisberg et al, 2018;Zajaček and Tursunov, 2018). In fact, the NIR-observations of S2 star moving around Sgr A* on a highly elliptical orbit with the period of ∼ 16 yr led to successful measurements of two relativistic effects -the combined gravitational redshift and relativistic transverse Doppler effect of ∼ 200 km s −1 (Gravity Collaboration et al, 2018a) and an indication of the periastron shift (Parsa et al, 2017) being consistent with the predicted value of 12 arcminutes per orbital period.…”

Section: Agn Structure and Unification Scenariosmentioning

confidence: 99%

“…6 for an illustration. The number of stars can thus fall below one at a certain radius, which marks the volume which lacks stars or one can refer to it as a sparse region, see also Zajaček and Tursunov (2018) for a detailed discussion. As a consequence, it is quite implausible to detect a cluster of stars in the strong-gravity regime, i.e.…”

Section: Agn Structure and Unification Scenariosmentioning

confidence: 99%

“…To quantify the length-scale, on which the number of stars is expected to fall below one for a certain stellar type T , it is straightforward to calculate the radius r 1T at which this is expected to happen. One can obtain the radius r 1T from the integral N (< r) = r 0 4πr 2 n (r)dr by setting N (< r) = 1 (see also Hopman and Alexander, 2006;Zajaček and Tursunov, 2018),…”

Section: Agn Structure and Unification Scenariosmentioning

confidence: 99%

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Selected Chapters on Active Galactic Nuclei as Relativistic Systems

Karas¹,

Svoboda²

2019

Preprint

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This chapter presents an overview of selected aspects and physical processes occurring in the inner regions of Active Galactic Nuclei (AGN). Observational evidence strongly suggests that strong gravitational fields play a significant role in governing the energy output of AGN and their influence on the surrounding medium, possibly due to the presence of a supermassive black hole (SMBH). We begin by an account of observational properties of AGN, their basic structural components and unification scenarios, and the arguments for the presence of SMBHs in their cores. Subsequently, in more detail we discuss selected phenomena that are related to black-hole accretion and relevant for the emerging radiation signal and the acceleration of matter in AGN cores. In order to reduce an unnecessary overlap with numerous reviews and textbook chapters on the similar subject, we focus on just a few topics, such as the launching scenarios of nuclear outflows and jets that start and pre-collimate in the immediate vicinity of black holes, at distance of only a only a few gravitational radii, and then can reach spectacular length-scales of ∼Mpc, extending far beyond the host galaxy. We also discuss the interaction between magnetic and gravitational fields in the strong-gravity regime of General Relativity. Some more recent aspects of the AGN unification scheme are included at the end of the chapter.

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Section: Agn Structure and Unification Scenariosmentioning

confidence: 99%

Section: Agn Structure and Unification Scenariosmentioning

confidence: 99%

Section: Agn Structure and Unification Scenariosmentioning

confidence: 99%

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Selected Chapters on Active Galactic Nuclei as Relativistic Systems

Karas¹,

Svoboda²

2019

Preprint

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“…Stars on long-period, higheccentricity orbits, which result from dynamical scattering into a loss cone, can in principle be located inside r for a short period of time. The probability of detecting such stars in a sparse region close to the SMBH was considered and estimated by Zajaček & Tursunov (2018).…”

Section: Occurrence Of Stars In the Innermost Regionmentioning

confidence: 99%

Stellar transits across a magnetized accretion torus as a mechanism for plasmoid ejection

Suková,

Zajaček,

Witzany

et al. 2021

Preprint

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The close neighbourhood of a supermassive black hole contains not only the accreting gas and dust but also stellar-sized objects, such as late-type and early-type stars and compact remnants that belong to the nuclear star cluster. When passing through the accretion flow, these objects perturb it by their winds, magnetic and gravitational fields. By performing General-Relativistic Magnetohydrodynamic (GRMHD) simulations, we investigate how the passages of a star can influence the black hole gaseous environment. We focus on the changes in the accretion rate and the emergence of blobs of plasma in the funnel of an accretion torus. We compare results from 2D and 3D numerical computations that have been initiated with comparable initial conditions. We show how a quasi-stationary inflow can be temporarily inhibited by a transiting star, and how the plasmoids can be ejected along the magnetic field lines near the rotation axis. Additionally, we observe the characteristic frequency of the perturbing motion in the power spectrum of the accretion variability, which provides an avenue for a multi-messenger detection of the event. Finally, we discuss the connection of our results to multiwavelength observations of galactic nuclei, with emphasis on several promising sources such as Sgr A*,

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“…The three-body interaction including the massive black hole can effectively fill the 'sparse region' around Sgr A*. In the classical quasi-spherical stellar cluster around Sgr A* with the power-law distribution of stellar number densities, there is a well-defined radius below which the number of stars statistically drops below one (Zajaček & Tursunov 2018),…”

mentioning

confidence: 99%

S62 and S4711: Indications of a population of faint fast moving stars inside the S2 orbit -- S4711 on a 7.6 year orbit around Sgr~A*

Peißker,

Eckart,

Zajaček

et al. 2020

Preprint

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We present high-pass filtered NACO and SINFONI images of the newly discovered stars S4711-S4715 between 2004 and 2016. Our deep H+K-band (SINFONI) and K-band (NACO) data shows the S-cluster star S4711 on a highly eccentric trajectory around Sgr A* with an orbital period of 7.6 years and a periapse distance of 144 AU to the super massive black hole (SMBH). S4711 is hereby the star with the shortest orbital period and the smallest mean distance to the SMBH during its orbit to date. The used high-pass filtered images are based on co-added data sets to improve the signal to noise. The spectroscopic SINFONI data let us determine detailed stellar properties of S4711 like the mass and the rotational velocity. The faint S-cluster star candidates, S4712-S4715, can be observed in a projected distance to Sgr A* of at least temporarily ≤ 120 mas. From these stars, S4714 is the most prominent one with an orbital period of 12 years and an eccentricity of 0.985. The stars S4712-S4715 show similar properties with comparable magnitudes and stellar masses to S4711. The MCMC simulations determine confidently precise uncertainties for the orbital elements of S62 and S4711-S4715. The presence of S4711 in addition to S55, S62, and the also newly found star S4714 implies a population of faint stars that can be found at distances to Sgr A* that are comparable to the size of our solar system. These short orbital time period stars in the dense cluster around the SMBH in the center of our Galaxy are perfect candidates to observe gravitational effects such as the periapse shift.

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A stellar fly‐by close to the Galactic center: Can we detect stars on highly relativistic orbits?

Cited by 8 publications

References 27 publications

Selected Chapters on Active Galactic Nuclei as Relativistic Systems

Selected Chapters on Active Galactic Nuclei as Relativistic Systems

Stellar transits across a magnetized accretion torus as a mechanism for plasmoid ejection

S62 and S4711: Indications of a population of faint fast moving stars inside the S2 orbit -- S4711 on a 7.6 year orbit around Sgr~A*

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