PIRSA:25020052

The Gravitational Wave Bias Parameter from Angular Power Spectra: Bridging Between Galaxies and Binary Black Holes

APA

Dehghanizadeh, A. (2025). The Gravitational Wave Bias Parameter from Angular Power Spectra: Bridging Between Galaxies and Binary Black Holes. Perimeter Institute. https://pirsa.org/25020052

MLA

Dehghanizadeh, Amirhossein. The Gravitational Wave Bias Parameter from Angular Power Spectra: Bridging Between Galaxies and Binary Black Holes. Perimeter Institute, Feb. 24, 2025, https://pirsa.org/25020052

BibTex

          @misc{ pirsa_PIRSA:25020052,
            doi = {10.48660/25020052},
            url = {https://pirsa.org/25020052},
            author = {Dehghanizadeh, Amirhossein},
            keywords = {Other},
            language = {en},
            title = {The Gravitational Wave Bias Parameter from Angular Power Spectra: Bridging Between Galaxies and Binary Black Holes},
            publisher = {Perimeter Institute},
            year = {2025},
            month = {feb},
            note = {PIRSA:25020052 see, \url{https://pirsa.org}}
          }
          

Amirhossein Dehghanizadeh

The University of Waterloo

Talk number
PIRSA:25020052
Talk Type
Subject
Abstract

This study presents the modeling of the gravitational wave (GW) bias parameter by bridging a connection between simulated GW sources and galaxies in low redshift galaxy surveys 2MPZ and WISExSCOS (WISC). We study this connection by creating a mock GW catalog, populating galaxy surveys with binary black holes (BBHs) for different scenarios of the GW host-galaxy probability as a function of the galaxy stellar mass. We probe the observable consequences of this connection by exploring the spatial clustering of the GW sources in terms of the GW bias parameter. We consider a phenomenological broken power law model for the host-galaxy probability function, with a potential turnover M_K at high stellar mass (10^{11} solar mass in the fiducial model) where the star formation efficiency begins to drop. We vary the parameters of the GW host-galaxy probability function and find that generically the GW bias increases as M_K increases (and gets suppressed as M_K decreases). The change in the GW bias parameter shows a maximum change of about 30% for different scenarios explored in this work in comparison to the galaxy bias. Future measurements of the GW bias can help constrain M_K and the slopes of the host-galaxy probability function and thus offer insights into the underlying astrophysical processes.