Charles D. Kilpatrick
University of California, Santa Cruz
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Science | 2017
D. A. Coulter; Ryan J. Foley; Charles D. Kilpatrick; M. R. Drout; Anthony L. Piro; B. J. Shappee; M. R. Siebert; J. D. Simon; N. Ulloa; Daniel Kasen; Barry F. Madore; A. Murguia-Berthier; Y.-C. Pan; Jason X. Prochaska; Enrico Ramirez-Ruiz; A. Rest; C. Rojas-Bravo
Photons from a gravitational wave event Two neutron stars merging together generate a gravitational wave signal and have also been predicted to emit electromagnetic radiation. When the gravitational wave event GW170817 was detected, astronomers rushed to search for the source using conventional telescopes (see the Introduction by Smith). Coulter et al. describe how the One-Meter Two-Hemispheres (1M2H) collaboration was the first to locate the electromagnetic source. Drout et al. present the 1M2H measurements of its optical and infrared brightness, and Shappee et al. report their spectroscopy of the event, which is unlike previously detected astronomical transient sources. Kilpatrick et al. show how these observations can be explained by an explosion known as a kilonova, which produces large quantities of heavy elements in nuclear reactions. Science, this issue p. 1556, p. 1570, p. 1574, p. 1583; see also p. 1554 A rapid astronomical search located the optical counterpart of the neutron star merger GW170817. On 17 August 2017, the Laser Interferometer Gravitational-Wave Observatory (LIGO) and the Virgo interferometer detected gravitational waves (GWs) emanating from a binary neutron star merger, GW170817. Nearly simultaneously, the Fermi and INTEGRAL (INTErnational Gamma-Ray Astrophysics Laboratory) telescopes detected a gamma-ray transient, GRB 170817A. At 10.9 hours after the GW trigger, we discovered a transient and fading optical source, Swope Supernova Survey 2017a (SSS17a), coincident with GW170817. SSS17a is located in NGC 4993, an S0 galaxy at a distance of 40 megaparsecs. The precise location of GW170817 provides an opportunity to probe the nature of these cataclysmic events by combining electromagnetic and GW observations.
Science | 2017
Charles D. Kilpatrick; Ryan J. Foley; Daniel Kasen; A. Murguia-Berthier; Enrico Ramirez-Ruiz; D. A. Coulter; M. R. Drout; Anthony L. Piro; B. J. Shappee; K. Boutsia; Carlos Contreras; F. Di Mille; Barry F. Madore; Nidia I. Morrell; Y.-C. Pan; Jason X. Prochaska; A. Rest; C. Rojas-Bravo; M. R. Siebert; J. D. Simon; N. Ulloa
Photons from a gravitational wave event Two neutron stars merging together generate a gravitational wave signal and have also been predicted to emit electromagnetic radiation. When the gravitational wave event GW170817 was detected, astronomers rushed to search for the source using conventional telescopes (see the Introduction by Smith). Coulter et al. describe how the One-Meter Two-Hemispheres (1M2H) collaboration was the first to locate the electromagnetic source. Drout et al. present the 1M2H measurements of its optical and infrared brightness, and Shappee et al. report their spectroscopy of the event, which is unlike previously detected astronomical transient sources. Kilpatrick et al. show how these observations can be explained by an explosion known as a kilonova, which produces large quantities of heavy elements in nuclear reactions. Science, this issue p. 1556, p. 1570, p. 1574, p. 1583; see also p. 1554 Optical and infrared observations indicate that GW170817 was a neutron star merger, independent of the gravitational wave data. Eleven hours after the detection of gravitational wave source GW170817 by the Laser Interferometer Gravitational-Wave Observatory and Virgo Interferometers, an associated optical transient, SSS17a, was identified in the galaxy NGC 4993. Although the gravitational wave data indicate that GW170817 is consistent with the merger of two compact objects, the electromagnetic observations provide independent constraints on the nature of that system. We synthesize the optical to near-infrared photometry and spectroscopy of SSS17a collected by the One-Meter Two-Hemisphere collaboration, finding that SSS17a is unlike other known transients. The source is best described by theoretical models of a kilonova consisting of radioactive elements produced by rapid neutron capture (the r-process). We conclude that SSS17a was the result of a binary neutron star merger, reinforcing the gravitational wave result.
Science | 2017
B. J. Shappee; J. D. Simon; M. R. Drout; Anthony L. Piro; Nidia I. Morrell; Jose Luis Palacio Prieto; Daniel Kasen; T. W.-S. Holoien; J. A. Kollmeier; D. D. Kelson; D. A. Coulter; Ryan J. Foley; Charles D. Kilpatrick; M. R. Siebert; Barry F. Madore; A. Murguia-Berthier; Y.-C. Pan; Jason X. Prochaska; Enrico Ramirez-Ruiz; A. Rest; C. Adams; K. Alatalo; Eduardo Bañados; J. Baughman; R. A. Bernstein; T. Bitsakis; K. Boutsia; J. R. Bravo; F. Di Mille; C. R. Higgs
Photons from a gravitational wave event Two neutron stars merging together generate a gravitational wave signal and have also been predicted to emit electromagnetic radiation. When the gravitational wave event GW170817 was detected, astronomers rushed to search for the source using conventional telescopes (see the Introduction by Smith). Coulter et al. describe how the One-Meter Two-Hemispheres (1M2H) collaboration was the first to locate the electromagnetic source. Drout et al. present the 1M2H measurements of its optical and infrared brightness, and Shappee et al. report their spectroscopy of the event, which is unlike previously detected astronomical transient sources. Kilpatrick et al. show how these observations can be explained by an explosion known as a kilonova, which produces large quantities of heavy elements in nuclear reactions. Science, this issue p. 1556, p. 1570, p. 1574, p. 1583; see also p. 1554 Spectra of a neutron star merger are unlike other astronomical transients and demonstrate rapid evolution of the source. On 17 August 2017, Swope Supernova Survey 2017a (SSS17a) was discovered as the optical counterpart of the binary neutron star gravitational wave event GW170817. We report time-series spectroscopy of SSS17a from 11.75 hours until 8.5 days after the merger. Over the first hour of observations, the ejecta rapidly expanded and cooled. Applying blackbody fits to the spectra, we measured the photosphere cooling from 11,000−900+3400 to 9300−300+300 kelvin, and determined a photospheric velocity of roughly 30% of the speed of light. The spectra of SSS17a began displaying broad features after 1.46 days and evolved qualitatively over each subsequent day, with distinct blue (early-time) and red (late-time) components. The late-time component is consistent with theoretical models of r-process–enriched neutron star ejecta, whereas the blue component requires high-velocity, lanthanide-free material.
The Astrophysical Journal | 2017
A. Murguia-Berthier; Enrico Ramirez-Ruiz; Charles D. Kilpatrick; Ryan J. Foley; Daniel Kasen; W. H. Lee; Anthony L. Piro; D. A. Coulter; M. R. Drout; Barry F. Madore; B. J. Shappee; Y.-C. Pan; Jason X. Prochaska; A. Rest; C. Rojas-Bravo; M. R. Siebert; J. D. Simon
The merging neutron star gravitational wave event GW170817 has been observed throughout the entire electromagnetic spectrum from radio waves to
Monthly Notices of the Royal Astronomical Society | 2017
Charles D. Kilpatrick; Ryan J. Foley; Louis E. Abramson; Y.-C. Pan; Cicero-Xinyu Lu; Peter Williams; Tommaso Treu; M. R. Siebert; C. D. Fassnacht; Claire E. Max
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Monthly Notices of the Royal Astronomical Society | 2017
Nathan Smith; Charles D. Kilpatrick; Jon C. Mauerhan; Jennifer E. Andrews; Raffaella Margutti; Wen Fai Fong; Melissa Lynn Graham; Wei Kang Zheng; Patrick L. Kelly; Alexei V. Filippenko; Ori D. Fox
-rays. The resulting energetics, variability, and light curves are shown to be consistent with GW170817 originating from the merger of two neutron stars, in all likelihood followed by the prompt gravitational collapse of the massive remnant. The available
The Astrophysical Journal | 2018
L. Tartaglia; David J. Sand; S. Valenti; S. Wyatt; J. P. Anderson; I. Arcavi; C. Ashall; M. T. Botticella; R. Cartier; T.-W. Chen; Aleksandar Cikota; D. A. Coulter; M. Della Valle; Ryan J. Foley; Avishay Gal-Yam; L. Galbany; C. Gall; J. B. Haislip; J. Harmanen; G. Hosseinzadeh; D. A. Howell; E. Y. Hsiao; C. Inserra; Saurabh W. Jha; E. Kankare; Charles D. Kilpatrick; Vladimir V. Kouprianov; Hanindyo Kuncarayakti; Thomas J. Maccarone; K. Maguire
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Monthly Notices of the Royal Astronomical Society | 2018
Charles D. Kilpatrick; Ryan J. Foley; Maria Rebecca Drout; Y.-C. Pan; Fiona H. Panther; D. A. Coulter; Alexei V. Filippenko; G. Howard Marion; Anthony L. Piro; Armin Rest; Ivo R. Seitenzahl; Giovanni Maria Strampelli; Xi E. Wang
-ray, X-ray and radio data provide a clear probe for the nature of the relativistic ejecta and the non-thermal processes occurring within, while the ultraviolet, optical and infrared emission are shown to probe material torn during the merger and subsequently heated by the decay of freshly synthesized
Monthly Notices of the Royal Astronomical Society | 2018
Christopher Bullivant; Nathan Smith; George Grant Williams; Jon C. Mauerhan; Jennifer E. Andrews; Wen-fai Fong; Christopher Bilinski; Charles D. Kilpatrick; Peter A. Milne; Ori D. Fox; S. Bradley Cenko; Alexei V. Filippenko; W. Zheng; Patrick L. Kelly; Kelsey I. Clubb
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Monthly Notices of the Royal Astronomical Society | 2016
Charles D. Kilpatrick; Jennifer E. Andrews; Nathan Smith; Peter A. Milne; G. H. Rieke; W. Zheng; Alexei V. Filippenko
-process material. The simplest hypothesis that the non-thermal emission is due to a low-luminosity short
