Your search keyword '"Dempsey, Adam M."' showing total 6 results

1. Runaway Eccentricity Growth: A Pathway for Binary Black Hole Mergers in AGN Disks.

Author

Calcino, Josh, Dempsey, Adam M., Dittmann, Alexander J., and Li, Hui

Subjects

*ECCENTRICS (Machinery), *MERGERS & acquisitions, *ASTROPHYSICAL fluid dynamics, *SUPERMASSIVE black holes, *ACTIVE galactic nuclei, *BINARY black holes, *ACCRETION disks

Abstract

Binary black holes (BBHs) embedded within the accretion disks that fuel active galactic nuclei (AGN) are promising progenitors for the source of gravitational wave (GW) events detected by LIGO/VIRGO. Several recent studies have shown that when these binaries form, they are likely to be highly eccentric and retrograde. However, many uncertainties remain concerning the orbital evolution of these binaries as they either inspiral toward merger or disassociate. Previous hydrodynamical simulations exploring their orbital evolution have been predominantly two-dimensional or have been restricted to binaries on nearly circular orbits. We present the first high-resolution, three-dimensional local shearing-box simulations of both prograde and retrograde eccentric BBHs embedded in AGN disks. We find that retrograde binaries shrink several times faster than their prograde counterparts and exhibit significant orbital eccentricity growth, the rate of which monotonically increases with binary eccentricity. Our results suggest that retrograde binaries may experience runaway orbital eccentricity growth, which may bring them close enough together at pericenter for GW emission to drive them to coalescence. Although their eccentricity is damped, prograde binaries shrink much faster than their orbital eccentricity decays, suggesting they should remain modestly eccentric as they contract toward merger. Finally, binary precession driven by the AGN disk may dominate over precession induced by the supermassive black hole depending on the binary accretion rate and its location in the AGN disk, which can subdue the evection resonance and von Ziepel–Lidov–Kozai cycles. [ABSTRACT FROM AUTHOR]

Published

2024

2. Hot Circumsingle Disks Drive Binary Black Hole Mergers in Active Galactic Nucleus Disks.

Author

Li, Ya-Ping, Dempsey, Adam M., Li, Hui, Li, Shengtai, and Li, Jiaru

Published

2022

3. Orbital Evolution of Binary Black Holes in Active Galactic Nucleus Disks: A Disk Channel for Binary Black Hole Mergers?

Author

Li, Ya-Ping, Dempsey, Adam M., Li, Shengtai, Li, Hui, and Li, Jiaru

Subjects

*ACTIVE galactic nuclei, *BINARY black holes, *TIDAL forces (Mechanics), *ACCRETION disks, *BLACK holes, *ANGULAR momentum (Mechanics)

Abstract

We perform a series of high-resolution 2D hydrodynamical simulations of equal-mass binary black holes (BBHs) embedded in active galactic nucleus (AGN) accretion disks to study whether these binaries can be driven to merger by the surrounding gas. We find that the gravitational softening adopted for the BBH has a profound impact on this result. When the softening is less than 10% of the binary separation, we show that, in agreement with recent simulations of isolated equal-mass binaries, prograde BBHs expand in time rather than contract. Eventually, however, the binary separation becomes large enough that the tidal force of the central AGN disrupts them. Only when the softening is relatively large do we find that prograde BBHs harden. We determine through detailed analysis of the binary torque, that this dichotomy is due to a loss of spiral structure in the circum-single disks orbiting each black hole when the softening is a significant fraction of the binary separation. Properly resolving these spirals—both with high resolution and small softening—results in a significant source of binary angular momentum. Only for retrograde BBHs do we find consistent hardening, regardless of softening, as these BBHs lack the important spiral structure in their circum-single disks. This suggests that the gas-driven inspiral of retrograde binaries can produce a population of compact BBHs in the gravitational-wave-emitting regime in AGN disks, which may contribute a large fraction to the observed BBH mergers. [ABSTRACT FROM AUTHOR]

Published

2021

4. Ring Formation in Protoplanetary Disks Driven by an Eccentric Instability.

Author

Li, Jiaru, Dempsey, Adam M., Li, Hui, and Li, Shengtai

Subjects

*PROTOPLANETARY disks, *ANGULAR momentum (Mechanics), *NONLINEAR theories, *HYDRODYNAMICS, *DISC brakes

Abstract

We find that, under certain conditions, protoplanetary disks may spontaneously generate multiple, concentric gas rings without an embedded planet through an eccentric cooling instability. Using both linear theory and nonlinear hydrodynamics simulations, we show that a variety of background states may trap a slowly precessing, one-armed spiral mode that becomes unstable when a gravitationally stable disk rapidly cools. The angular momentum required to excite this spiral comes at the expense of nonuniform mass transport that generically results in multiple rings. For example, one long-term hydrodynamics simulation exhibits four long-lived, axisymmetric gas rings. We verify the instability evolution and ring-formation mechanism from first principles with our linear theory, which shows remarkable agreement with the simulation results. Dust trapped in these rings may produce observable features consistent with observed disks. Additionally, direct detection of the eccentric gas motions may be possible when the instability saturates, and any residual eccentricity left over in the rings at later times may also provide direct observational evidence of this mechanism. [ABSTRACT FROM AUTHOR]

Published

2021

5. Access channels can be effective, if used properly

Author

Dempsey, Adam M.

Subjects

New York, New York -- Laws, regulations and rules, Cable television broadcasting industry -- Laws, regulations and rules, Cable television -- Laws, regulations and rules, Government regulation, Cable television/data services, Arts and entertainment industries, Business, Mass communications

Abstract

The battle in New York over the use of the city's cable-access channels has served to lift the visibility and to underscore the importance of such analog channels to all [...]

Published

1996

6. THEORY AND SIMULATIONS OF ROTATING CONVECTION.

Author

Barker, Adrian J., Dempsey, Adam M., and Lithwick, Yoram

Subjects

*CONVECTION (Astrophysics), *STELLAR rotation, *BOUSSINESQ equations, *PLANETARY rotation, *MAGNITUDES of brightest stars

Abstract

We study thermal convection in a rotating fluid in order to better understand the properties of convection zones in rotating stars and planets. We first derive a mixing-length theory for rapidly rotating convection, arriving at the results of Stevenson via simple physical arguments. The theory predicts the properties of convection as a function of the imposed heat flux and rotation rate, independent of microscopic diffusivities. In particular, it predicts the mean temperature gradient, the rms velocity and temperature fluctuations, and the size of the eddies that dominate heat transport. We test all of these predictions with high resolution three-dimensional hydrodynamical simulations of Boussinesq convection in a Cartesian box. The results agree remarkably well with the theory across more than two orders of magnitude in rotation rate. For example, the temperature gradient is predicted to scale as the rotation rate to the four-fifths power at fixed flux, and the simulations yield 0.75 ± 0.06. We conclude that the mixing-length theory is a solid foundation for understanding the properties of convection zones in rotating stars and planets. [ABSTRACT FROM AUTHOR]

Published

2014