论文信息 - Early spectra of the gravitational wave source GW170817: Evolution of a neutron star merger - 字舞流文

Early spectra of the gravitational wave source GW170817: Evolution of a neutron star merger

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.

B. J. Shappee | E. Ramirez-Ruiz | A. Rest | J. X. Prochaska | F. Di Mille | K. Boutsia | M. R. Drout | C. Adams | B. F. Madore | M. R. Siebert | K. Alatalo | J. L. Marshall | C. D. Kilpatrick | T. Bitsakis | V. M. Placco | D. A. Coulter | R. J. Foley | J. L. Prieto | T. W.-S. Holoien | J. Prieto | J. Prochaska | J. Marshall | D. Kasen | J. Kollmeier | A. Rest | Y.-C. Pan | R. Foley | M. Drout | D. Coulter | C. Kilpatrick | B. Madore | A. Murguia-Berthier | A. Piro | E. Ramirez-Ruiz | M. Siebert | J. Simon | N. Morrell | K. Boutsia | F. Di Mille | T. Holoien | C. Adams | K. Alatalo | E. Bañados | J. Baughman | R. Bernstein | T. Bitsakis | C. Higgs | A. Ji | G. Maravelias | Z. Wan | B. Shappee | F. D. Mille | V. Placco | D. Kelson | R. A. Bernstein | J. A. Kollmeier | J. D. Simon | N. Morrell | D. Kasen | Y.-C. Pan | Yen-Chen Pan | A. L. Piro | J. R. Bravo | G. Prieto | D. D. Kelson | A. Murguia-Berthier | E. Bañados | J. Baughman | C. R. Higgs | A. P. Ji | G. Maravelias | G. Prieto | Z. Wan | J. Marshall | J. Marshall | J. Baughman | J. Bravo | J. Simon

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