Journal
NATURE ASTRONOMY
Volume 5, Issue 1, Pages -Publisher
NATURE RESEARCH
DOI: 10.1038/s41550-020-1183-3
Keywords
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Categories
Funding
- GROWTH (Global Relay of Observatories Watching Transients Happen) project - National Science Foundation under PIRE grant [1545949]
- National Science Foundation [PHY-2010970, 1106171, AST-1440341]
- Caltech
- IPAC
- Weizmann Institute for Science
- Oskar Klein Center at Stockholm University
- University of Maryland
- University of Washington (UW)
- Deutsches Elektronen-Synchrotron
- Humboldt University
- Los Alamos National Laboratories
- TANGO Consortium of Taiwan
- University of Wisconsin at Milwaukee
- Lawrence Berkeley National Laboratories
- Caltech Space Innovation Council
- Murty family
- Heising-Simons Foundation [12540303]
- GROWTH PIRE grant [1545949]
- National Aeronautics and Space Administration
- G.R.E.A.T. research environment
- Wenner-Gren Foundations
- NASA [80NSSC18K0565]
- NSF [PHY-1806278]
- DOE through CAREER grant [DE-SC0020435]
- National Science Foundation
- National Optical Astronomical Observatory
- U.S. Department of Energy (DOE) [DE-SC0020435] Funding Source: U.S. Department of Energy (DOE)
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The third observing run of LIGO and Virgo revealed the first neutron star-black hole merger candidates in gravitational waves, which are predicted to synthesize r-process elements and create kilonova emission. Optical follow-up and analysis of two high-significance NSBH merger candidates detected to date were conducted, revealing localization probabilities but no viable counterparts were found. State-of-the-art kilonova models tailored to NSBH systems placed constraints on ejecta properties, with potential to rule out certain scenarios.
LIGO and Virgo's third observing run revealed the first neutron star-black hole (NSBH) merger candidates in gravitational waves. These events are predicted to synthesize r-process elements(1,2)creating optical/near-infrared 'kilonova' emission. The joint gravitational wave and electromagnetic detection of an NSBH merger could be used to constrain the equation of state of dense nuclear matter(3), and independently measure the local expansion rate of the Universe(4). Here, we present the optical follow-up and analysis of two of the only three high-significance NSBH merger candidates detected to date, S200105ae and S200115j, with the Zwicky Transient Facility(5). The Zwicky Transient Facility observed similar to 48% of S200105ae and similar to 22% of S200115j's localization probabilities, with observations sensitive to kilonovae brighter than -17.5 mag fading at 0.5 mag d(-1)in the g- and r-bands; extensive searches and systematic follow-up of candidates did not yield a viable counterpart. We present state-of-the-art kilonova models tailored to NSBH systems that place constraints on the ejecta properties of these NSBH mergers. We show that with observed depths of apparent magnitude similar to 22 mag, attainable in metre-class, wide-field-of-view survey instruments, strong constraints on ejecta mass are possible, with the potential to rule out low mass ratios, high black hole spins and large neutron star radii.
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