Target of Opportunity Observations of Gravitational Wave Events with Vera C. Rubin Observatory

Andreoni, Igor; Margutti, Raffaella; Salafia, Om Sharan; Parazin, B.; Villar, V. Ashley; Coughlin, Michael W.; Yoachim, Peter; Mortensen, Kris; Brethauer, Daniel; Smartt, S. J.; Kasliwal, Mansi M.; Alexander, Kate D.; Anand, Shreya; Berger, E.; Bernardini, Maria Grazia; Bianco, Federica B.; Blanchard, Peter K.; Bloom, Joshua S.; Brocato, Enzo; Bulla, Mattia; Cartier, Regis; Cenko, S. Bradley; Chornock, Ryan; Copperwheat, Christopher M.; Corsi, Alessandra; D'Ammando, Filippo; D'Avanzo, Paolo; Datrier, Laurence Elise Helene; Foley, Ryan J.; Ghirlanda, Giancarlo; Goobar, Ariel; Grindlay, Jonathan; Hajela, Aprajita; Holz, Daniel E.; Karambelkar, Viraj; Kool, E. C.; Lamb, Gavin P.; Laskar, Tanmoy; Levan, Andrew; Maguire, Kate; May, Morgan; Melandri, Andrea; Milisavljevic, Dan; Miller, A. A.; Nicholl, Matt; Nissanke, Samaya M.; Palmese, Antonella; Piranomonte, Silvia; Rest, Armin; Sagues-Carracedo, Ana; Siellez, Karelle; Singer, Leo P.; Smith, Mathew; Steeghs, D.; Tanvir, Nial

doi:10.48550/arxiv.2111.01945

Cited by 6 publications

(6 citation statements)

References 119 publications

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“…Observations will therefore need to be triggered in response to such a detection. In the context of the Vera Rubin Observatory, this would take the form of a target of opportunity (ToO) observations along similar lines to those discussed by Andreoni et al (2021), albeit in response to detections in the mass gap and tuned to a lensed NS-NS interpretation. With a required sensitivity of 26th magnitude, such observations will be more time consuming than envisaged for GW detections that are not lensed, with the lightcurves in Figure 10 indicating that up to 20 minutes per epoch per filter may be required, depending on the expected magnification of the source.…”

Section: Outline Observing Strategymentioning

confidence: 99%

Discovering gravitationally lensed gravitational waves: predicted rates, candidate selection, and localization with the Vera Rubin Observatory

Smith¹,

Robertson²,

Mahler³

et al. 2022

Preprint

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The first secure detection of a gravitationally lensed gravitational (GW) will be a watershed moment, as it will bring together these two pillars of General Relativity for the first time. Accurate selection and interpretation of candidate lensed GWs is challenging for numerous reasons, including large sky localization uncertainties for most GW detections, the broad range of gravitational lenses spanning galaxy/group/cluster-scales in the dark matter halo mass function, and uncertainty in the intrinsic mass function of compact object remnants of stellar evolution. We introduce a new magnification-based approach to predicting the rates of lensed GWs that is agnostic to the mass and structure of the lenses and combine it with expressions for arrival time difference for representative lenses and their catastrophes to delineate the range of expected arrival time differences. We also predict the lightcurves of lensed kilonova counterparts to lensed binary neutron star (NS-NS) mergers and assess the feasibility of detection with the Vera Rubin Observatory. Our main conclusions are: (1) selection of candidate lensed NS-NS mergers from the mass gap between NS and black holes in low latency is an efficient approach with a rate approaching one per year in the mid-2020s, (2) the arrival time differences of lensed NS-NS/kilonovae are typically 1 year, and thus well-matched to the operations of GW detectors and optical telescopes, and (3) detection of lensed kilonovae is feasible with the Vera Rubin Observatory. Whilst our predictions are motivated by lensing, they provide a physically well-understood approach to exploring the mass gap electromagnetically as the number of detections in this exciting region of parameter space grows.

show abstract

Section: Outline Observing Strategymentioning

confidence: 99%

Discovering gravitationally lensed gravitational waves: predicted rates, candidate selection, and localization with the Vera Rubin Observatory

Smith¹,

Robertson²,

Mahler³

et al. 2022

Preprint

Self Cite

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“…• BNV processes with final states involving photons, mesons, and charged leptons (e.g., n → e ∓ π ± ) can be expected to dump all of their energy back into the NS, raising the temperature of the NS to a potentially detectable level, given upcoming observational possibilities [474]. Put more pithily, old neutron stars should be if they are not, then this would really be quite a coup.…”

Section: Discussionmentioning

confidence: 99%

Neutron Stars with Baryon Number Violation, Probing Dark Sectors

Berryman,

Gardner,

Zakeri

2022

Preprint

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The neutron lifetime anomaly has been used to motivate the introduction of new physics with hidden-sector particles coupled to baryon number, and on which neutron stars provide powerful constraints. Although the neutron lifetime anomaly may eventually prove to be of mundane origin, we use it as motivation for a broader review of the ways that baryon number violation, be it real or apparent, and dark sectors can intertwine and how neutron star observables, both present and future, can constrain them.

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“…the brightness can depend on the line of sight; Kasen et al 2017). Recently, Andreoni et al (2021) highlighted that realistic predictions on joint GW-kilonova detection should conservatively built around the capability to detect the red kilonova component. In their work, the authors show that a firm detection of red kilonovae during O4 can be obtained only within ∼ 100 Mpc, while for joint GW-kilonova detection beyond such horizon we will have to wait for O5, when the Vera Rubin Observatory will be operational.…”

Section: Discussionmentioning

confidence: 99%

Prospects for multi-messenger detection of binary neutron star mergers in the fourth LIGO-Virgo-KAGRA observing run

Patricelli,

Bernardini,

Mapelli

et al. 2022

Preprint

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The joint detection of GW170817 and GRB 170817A opened the era of multi-messenger astronomy with gravitational waves (GWs) and provided the first direct probe that at least some binary neutron star (BNS) mergers are progenitors of short gamma-ray bursts (S-GRBs). In the next years, we expect to have more multi-messenger detections of BNS mergers, thanks to the increasing sensitivity of GW detectors. Here, we present a comprehensive study on the prospects for joint GW and electromagnetic observations of merging BNSs in the fourth LIGO-Virgo-KAGRA observing run with Fermi, Swift, INTEGRAL and SVOM. This work combines accurate population synthesis models with simulations of the expected GW signals and the associated S-GRBs, considering different assumptions about the GRB jet structure. We show that the expected rate of joint GW and electromagnetic detections could be up to ∼ 6 yr −1 when Fermi/GBM is considered. Future joint observations will help us to better constrain the association between BNS mergers and S-GRBs, as well as the geometry of the GRB jets.

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Target of Opportunity Observations of Gravitational Wave Events with Vera C. Rubin Observatory

Cited by 6 publications

References 119 publications

Discovering gravitationally lensed gravitational waves: predicted rates, candidate selection, and localization with the Vera Rubin Observatory

Discovering gravitationally lensed gravitational waves: predicted rates, candidate selection, and localization with the Vera Rubin Observatory

Neutron Stars with Baryon Number Violation, Probing Dark Sectors

Prospects for multi-messenger detection of binary neutron star mergers in the fourth LIGO-Virgo-KAGRA observing run

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