Spinning black-hole binaries as gravitational and cosmological probes
APA
Barausse, E. (2013). Spinning black-hole binaries as gravitational and cosmological probes. Perimeter Institute. https://pirsa.org/13060004
MLA
Barausse, Enrico. Spinning black-hole binaries as gravitational and cosmological probes. Perimeter Institute, Jun. 07, 2013, https://pirsa.org/13060004
BibTex
@misc{ pirsa_PIRSA:13060004,
doi = {10.48660/13060004},
url = {https://pirsa.org/13060004},
author = {Barausse, Enrico},
keywords = {Strong Gravity},
language = {en},
title = {Spinning black-hole binaries as gravitational and cosmological probes},
publisher = {Perimeter Institute},
year = {2013},
month = {jun},
note = {PIRSA:13060004 see, \url{https://pirsa.org}}
}
SISSA International School for Advanced Studies
Collection
Talk Type
Subject
Abstract
Spins play a major role in the strong-field dynamics of
black-hole binaries and their gravitational-wave emission. By detecting spin
effects in the waveforms, existing and future gravitational-wave detectors
therefore provide a natural way to test gravity in strong-field, highly
dynamical regimes.
In the first part of my talk, I will show that the
inclusion of the spins in the gravitational templates for future space-based
detectors will permit testing scenarios for the formation and cosmological
evolution of supermassive black holes, and possibly shed light on models of
galaxy formation. In the second part, I will show that the effective-one-body
(EOB) model provides an efficient way to account for spin effects in both the
dynamics and waveforms, by combining information from post-Newtonian theory,
the self-force formalism, and numerical-relativity simulations.
black-hole binaries and their gravitational-wave emission. By detecting spin
effects in the waveforms, existing and future gravitational-wave detectors
therefore provide a natural way to test gravity in strong-field, highly
dynamical regimes.
In the first part of my talk, I will show that the
inclusion of the spins in the gravitational templates for future space-based
detectors will permit testing scenarios for the formation and cosmological
evolution of supermassive black holes, and possibly shed light on models of
galaxy formation. In the second part, I will show that the effective-one-body
(EOB) model provides an efficient way to account for spin effects in both the
dynamics and waveforms, by combining information from post-Newtonian theory,
the self-force formalism, and numerical-relativity simulations.