Back to Search Start Over

Multi-messenger prospects for black hole-neutron star mergers in the O4 and O5 runs

Authors :
Colombo, A
Duqué, R
Sharan Salafia, O
Broekgaarden, F
Iacovelli, F
Mancarella, M
Andreoni, I
Gabrielli, F
Ragosta, F
Ghirlanda, G
Fragos, T
Levan, A
Piranomonte, S
Melandri, A
Giacomazzo, B
Colpi, M
Alberto Colombo
Raphaël Duqué
Om Sharan Salafia
Floor S. Broekgaarden
Francesco Iacovelli
Michele Mancarella
Igor Andreoni
Francesco Gabrielli
Fabio Ragosta
Giancarlo Ghirlanda
Tassos Fragos
Andrew J. Levan
Silvia Piranomonte
Andrea Melandri
Bruno Giacomazzo
Monica Colpi
Colombo, A
Duqué, R
Sharan Salafia, O
Broekgaarden, F
Iacovelli, F
Mancarella, M
Andreoni, I
Gabrielli, F
Ragosta, F
Ghirlanda, G
Fragos, T
Levan, A
Piranomonte, S
Melandri, A
Giacomazzo, B
Colpi, M
Alberto Colombo
Raphaël Duqué
Om Sharan Salafia
Floor S. Broekgaarden
Francesco Iacovelli
Michele Mancarella
Igor Andreoni
Francesco Gabrielli
Fabio Ragosta
Giancarlo Ghirlanda
Tassos Fragos
Andrew J. Levan
Silvia Piranomonte
Andrea Melandri
Bruno Giacomazzo
Monica Colpi
Publication Year :
2024

Abstract

The existence of merging black hole-neutron star (BHNS) binaries has been ascertained through the observation of their gravitational wave (GW) signals. However, to date, no definitive electromagnetic (EM) emission has been confidently associated with these mergers. Such an association could help unravel crucial information on these systems, for example, their BH spin distribution, the equation of state (EoS) of the neutron star and the rate of heavy element production. We modeled the multi-messenger (MM) emission from BHNS mergers detectable during the fourth (O4) and fifth (O5) observing runs of the LIGO-Virgo-KAGRA (LVK) GW detector network in order to provide detailed predictions that can help enhance the effectiveness of observational efforts and extract the highest possible scientific information from such remarkable events. Our methodology is based on a population synthesis approach, which includes the modeling of the signal-To-noise ratio of the GW signal in the detectors, the GW-inferred sky localization of the source, the kilonova (KN) optical and near-infrared light curves, the relativistic jet gamma-ray burst (GRB) prompt emission peak photon flux, and the GRB afterglow light curves in the radio, optical, and X-ray bands. The resulting prospects for BHNS MM detections during O4 are not promising, with an LVK GW detection rate of 15:0+15:48:8 yr-1, but joint MM rates of ∼10-1 yr-1 for the KN and 10-2 yr1 for the jet-related emission. In O5, we found an overall increase in expected detection rates by around an order of magnitude, owing to both the enhanced sensitivity of the GW detector network and the coming online of future EM facilities. Considering variations in the NS EoS and BH spin distribution, we find that the detection rates can increase further by up to a factor of several tens. Finally, we discuss direct searches for the GRB radio afterglow with large field-of-view instruments during O5 and beyond as a new possible follow-up strategy in the cont

Details

Database :
OAIster
Notes :
ELETTRONICO, English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1427430501
Document Type :
Electronic Resource