Yonadav Barry Ginat

Detection prospects for the GW background of Galactic (sub)solar mass primordial black holes

ArXiv 2410.04522 (2024)

Authors:

Frans van Die, Ivan Rapoport, Yonadav Barry Ginat, Vincent Desjacques

Three-body binary formation in clusters: analytical theory

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 531:1 (2024) 739-750

Authors:

Yonadav Barry Ginat, Hagai B Perets

Frequency-domain distribution of astrophysical gravitational-wave backgrounds

Physical Review D American Physical Society (APS) 109:8 (2024) 083526

Authors:

Yonadav Barry Ginat, Robert Reischke, Ivan Rapoport, Vincent Desjacques

Three-Body Binary Formation in Clusters: Analytical Theory

ArXiv 2404.0804 (2024)

Authors:

Yonadav Barry Ginat, Hagai B Perets

Resonant dynamical friction around a supermassive black hole: analytical description

Monthly Notices of the Royal Astronomical Society Oxford University Press 525:3 (2023) 4202-4218

Authors:

Yonadav Barry Ginat, Taras Panamarev, Bence Kocsis, Hagai B Perets

Abstract:

We derive an analytical model for the so-called phenomenon of resonant dynamical friction, where a disc of stars around a supermassive black hole interacts with a massive perturber, so as to align its inclination with the disc’s orientation. We show that it stems from a singular behaviour of the orbit-averaged equations of motion, which leads to a rapid alignment of the argument of the ascending node of each of the disc stars, with that of the perturber, p, with a phase difference of 90◦. This phenomenon occurs for all stars whose maximum possible ˙ (maximized over all values of for all the disc stars) is greater than ˙ p; this corresponds approximately to all stars whose semi-major axes are less than twice that of the perturber. The rate at which the perturber’s inclination decreases with time is proportional to its mass and is shown to be much faster than Chandrasekhar’s dynamical friction. We find that the total alignment time is inversely proportional to the root of the perturber’s mass. This persists until the perturber enters the disc. The predictions of this model agree with a suite of numerical N-body simulations, which we perform to explore this phenomenon, for a wide range of initial conditions, masses, etc., and are an instance of a general phenomenon. Similar effects could occur in the context of planetary systems, too.