A kilonova as the electromagnetic counterpart to a gravitational-wave   source

S. J. Smartt; T.-W. Chen; A. Jerkstrand; M. Coughlin; E. Kankare; S.; A. Sim; M. Fraser; C. Inserra; K. Maguire; K. C. Chambers; M. E. Huber; T.; Kruhler; G. Leloudas; M. Magee; L. J. Shingles; K. W. Smith; D. R. Young; J.; Tonry; R. Kotak; A. Gal-Yam; J. D. Lyman; D. S. Homan; C. Agliozzo; J. P.; Anderson; C. R. Angus C. Ashall; C. Barbarino; F. E. Bauer; M. Berton; M. T.; Botticella; M. Bulla; J. Bulger; G. Cannizzaro; Z. Cano; R. Cartier; A.; Cikota; P. Clark; A. De Cia; M. Della Valle; L. Denneau; M. Dennefeld; L.; Dessart; G. Dimitriadis; N. Elias-Rosa; R. E. Firth; H. Flewelling; A. Flors,; A. Franckowiak; C. Frohmaier; L. Galbany; S. Gonzalez-Gaitan; J. Greiner; M.; Gromadzki; A. Nicuesa Guelbenzu; C. P. Gutierrez; A. Hamanowicz; L. Hanlon,; J. Harmanen; K. E. Heintz; A. Heinze; M.-S. Hernandez; S. T. Hodgkin; I. M.; Hook; L. Izzo; P. A. James; P. G. Jonker; W. E. Kerzendorf; S. Klose; Z.; Kostrzewa-Rutkowska; M. Kowalski; M. Kromer; H. Kuncarayakti; A. Lawrence; T.; B. Lowe; E. A. Magnier; I. Manulis; A. Martin-Carrillo; S. Mattila; O.; McBrien; A. Muller; J. Nordin; D. O'Neill; F. Onori; J. T. Palmerio; A.; Pastorello; F. Patat; G. Pignata; Ph. Podsiadlowski; M. L. Pumo; S. J.; Prentice; A. Rau; A. Razza; A. Rest; T. Reynolds; R. Roy; A. J. Ruiter; K. A.; Rybicki; L. Salmon; P. Schady; A. S. B. Schultz; T. Schweyer; I. R.; Seitenzahl; M. Smith; J. Sollerman; B. Stalder; C. W. Stubbs; M. Sullivan; H.; Szegedi; F. Taddia; S. Taubenberger; G. Terreran; B. van Soelen; J. Vos; R.; J. Wainscoat; N. A. Walton; C. Waters; H. Weiland; M. Willman; P. Wiseman; D.; E. Wright; L. Wyrzykowski; O. Yaron

arXiv:1710.05841·astro-ph.HE·October 18, 2017

A kilonova as the electromagnetic counterpart to a gravitational-wave source

S. J. Smartt, T.-W. Chen, A. Jerkstrand, M. Coughlin, E. Kankare, S., A. Sim, M. Fraser, C. Inserra, K. Maguire, K. C. Chambers, M. E. Huber, T., Kruhler, G. Leloudas, M. Magee, L. J. Shingles, K. W. Smith, D. R. Young, J., Tonry, R. Kotak, A. Gal-Yam, J. D. Lyman, D. S. Homan

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TL;DR

This paper reports the observation and modeling of a kilonova associated with the gravitational-wave source GW170817, confirming neutron star mergers as sources of heavy element nucleosynthesis and electromagnetic transients.

Contribution

It provides the first detailed physical modeling of a kilonova linked to a gravitational-wave event, matching theoretical predictions with observed data.

Findings

01

Detected electromagnetic transient consistent with kilonova predictions

02

Ejected mass estimated at 0.04 solar masses with specific opacity and velocity

03

Spectral features indicate presence of light r-process elements

Abstract

Gravitational waves were discovered with the detection of binary black hole mergers and they should also be detectable from lower mass neutron star mergers. These are predicted to eject material rich in heavy radioactive isotopes that can power an electromagnetic signal called a kilonova. The gravitational wave source GW170817 arose from a binary neutron star merger in the nearby Universe with a relatively well confined sky position and distance estimate. Here we report observations and physical modelling of a rapidly fading electromagnetic transient in the galaxy NGC4993, which is spatially coincident with GW170817 and a weak short gamma-ray burst. The transient has physical parameters broadly matching the theoretical predictions of blue kilonovae from neutron star mergers. The emitted electromagnetic radiation can be explained with an ejected mass of 0.04 +/- 0.01 Msol, with an…

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