Your search keyword '"Fazeel Mahmood Khan"' showing total 4 results

1. The Stellar Orbital Structure in Axisymmetric Galaxy Models with Supermassive Black Hole Binaries.

Author

Baile Li, Kelly Holley-Bockelmann, and Fazeel Mahmood Khan

Subjects

STELLAR orbits, STELLAR structure, AXIAL flow, GRAVITATIONAL waves, SUPERMASSIVE black holes, BINARY stars, GALACTIC evolution

Abstract

It has been well established that particular centrophilic orbital families in non-spherical galaxies can, in principle, drive a black hole binary to shrink its orbit through three-body scattering until the black holes are close enough to strongly emit gravitational waves. Most of these studies rely on the orbital analysis of a static supermassive black hole (SMBH)-embedded galaxy potential to support this view; it is not clear, however, how these orbits transform as the second SMBH enters the center. So our understanding of which orbits actually interact with an SMBH binary is not ironclad. Here, we analyze two flattened galaxy models, one with a single SMBH and one with a binary, to determine which orbits actually do interact with the SMBH binary and how they compare with the set predicted in single SMBH-embedded models. We find close correspondence between the centrophilic orbits predicted to interact with the binary and those that are actually scattered by the binary, in terms of energy and Lz distribution, where Lz is the z component of a stellar particle’s angular momentum. Of minor note: because of the larger mass, the binary SMBH has a larger radius of influence than in the single SMBH model, which allows the binary to draw from a larger reservoir of orbits to scatter. Of the prediction particles and scattered particles, nearly half have chaotic orbits, 40% have fx:fy = 1:1 orbits and 10% have other resonant orbits. [ABSTRACT FROM AUTHOR]

Published

2018

2. SWIFT COALESCENCE OF SUPERMASSIVE BLACK HOLES IN COSMOLOGICAL MERGERS OF MASSIVE GALAXIES.

Author

Fazeel Mahmood Khan, Davide Fiacconi, Lucio Mayer, Peter Berczik, and Andreas Just

Subjects

SUPERMASSIVE black holes, GRAVITATIONAL waves, GALAXIES, KINEMATICS, GALACTIC nuclei

Abstract

Supermassive black holes (SMBHs) are ubiquitous in galaxies with a sizable mass. It is expected that a pair of SMBHs originally in the nuclei of two merging galaxies would form a binary and eventually coalesce via a burst of gravitational waves. So far, theoretical models and simulations, focusing only on limited phases of the orbital decay of SMBHs under idealized conditions of the galaxy hosts, have been unable to directly predict the SMBH merger timescale from ab-initio galaxy formation theory. The predicted SMBH merger timescales are long, of order Gyrs, which could be problematic for future gravitational wave (GW) searches. Here, we present the first multi-scale ΛCDM cosmological simulation that follows the orbital decay of a pair of SMBHs in a merger of two typical massive galaxies at , all the way to the final coalescence driven by GW emission. The two SMBHs, with masses , settle quickly in the nucleus of the merger remnant. The remnant is triaxial and extremely dense due to the dissipative nature of the merger and the intrinsic compactness of galaxies at high redshift. Such properties naturally allow a very efficient hardening of the SMBH binary. The SMBH merger occurs in only ∼10 Myr after the galactic cores have merged, which is two orders of magnitude smaller than the Hubble time. [ABSTRACT FROM AUTHOR]

Published

2016

3. CLASSIFICATION OF STELLAR ORBITS IN AXISYMMETRIC GALAXIES.

Author

Baile Li, Kelly Holley-Bockelmann, and Fazeel Mahmood Khan

Subjects

STELLAR orbits, ORBITS (Astronomy), BLACK holes, GRAVITATIONAL collapse, ORBITAL mechanics

Abstract

It is known that two supermassive black holes (SMBHs) cannot merge in a spherical galaxy within a Hubble time; an emerging picture is that galaxy geometry, rotation, and large potential perturbations may usher the SMBH binary through the critical three-body scattering phase and ultimately drive the SMBH to coalesce. We explore the orbital content within an N-body model of a mildly flattened, non-rotating, SMBH-embedded elliptical galaxy. When used as the foundation for a study on the SMBH binary coalescence, the black holes bypassed the binary stalling often seen within spherical galaxies and merged on gigayear timescales. Using both frequency-mapping and angular momentum criteria, we identify a wealth of resonant orbits in the axisymmetric model, including saucers, that are absent from an otherwise identical spherical system and that can potentially interact with the binary. We quantified the set of orbits that could be scattered by the SMBH binary, and found that the axisymmetric model contained nearly six times the number of these potential loss cone orbits compared to our equivalent spherical model. In this flattened model, the mass of these orbits is more than three times that of the SMBH, which is consistent with what the SMBH binary needs to scatter to transition into the gravitational wave regime. [ABSTRACT FROM AUTHOR]

Published

2015

4. GALAXY ROTATION AND RAPID SUPERMASSIVE BINARY COALESCENCE.

Author

Kelly Holley-Bockelmann and Fazeel Mahmood Khan

Subjects

BLACK holes, ROTATION of galaxies, BROWNIAN motion, ANGULAR momentum (Mechanics), GRAVITATIONAL waves

Abstract

Galaxy mergers usher the supermassive black hole (SMBH) in each galaxy to the center of the potential, where they form an SMBH binary. The binary orbit shrinks by ejecting stars via three-body scattering, but ample work has shown that in spherical galaxy models, the binary separation stalls after ejecting all the stars in its loss cone—this is the well-known final parsec problem. However, it has been shown that SMBH binaries in non-spherical galactic nuclei harden at a nearly constant rate until reaching the gravitational wave regime. Here we use a suite of direct N-body simulations to follow SMBH binary evolution in both corotating and counterrotating flattened galaxy models. For N > 500 K, we find that the evolution of the SMBH binary is convergent and is independent of the particle number. Rotation in general increases the hardening rate of SMBH binaries even more effectively than galaxy geometry alone. SMBH binary hardening rates are similar for co- and counterrotating galaxies. In the corotating case, the center of mass of the SMBH binary settles into an orbit that is in corotation resonance with the background rotating model, and the coalescence time is roughly a few 100 Myr faster than a non-rotating flattened model. We find that counterrotation drives SMBHs to coalesce on a nearly radial orbit promptly after forming a hard binary. We discuss the implications for gravitational wave astronomy, hypervelocity star production, and the effect on the structure of the host galaxy. [ABSTRACT FROM AUTHOR]

Published

2015