The Electromagnetic Counterpart of the Binary Neutron Star Merger LIGO/Virgo GW170817. III. Optical and UV Spectra of a Blue Kilonova from Fast Polar Ejecta
Berger, E.; Rest, A.; Annis, J.; Sako, M.; Soares-Santos, M.; Clemens, J. C.; Chornock, R.; Pelisoli, I.; Brout, D.; Fong, W.; Massaro, F.; Nicholl, M.; Eftekhari, T.; Metzger, B. D.; Briceño, C.; Elias, J.; Brown, D. A.; Ricci, F.; Strader, J.; Margutti, R.; Alexander, K. D.; Blanchard, P. K.; Dennihy, E.; Williams, P. K. G.; Bahramian, A.; Kasen, D.; Villar, V. A.; Cowperthwaite, P. S.; Chen, H. -Y.; Holz, D. E.; Brown, W.; Marchesini, E.; Dunlap, B.; Moskowitz, N.
United States, Chile, Argentina, Italy, Brazil, United Kingdom
Abstract
We present optical and ultraviolet spectra of the first electromagnetic counterpart to a gravitational-wave (GW) source, the binary neutron star merger GW170817. Spectra were obtained nightly between 1.5 and 9.5 days post-merger, using the Southern Astrophysical Research and Magellan telescopes; the UV spectrum was obtained with the Hubble Space Telescope at 5.5 days. Our data reveal a rapidly fading blue component (T≈ 5500 K at 1.5 days) that quickly reddens; spectra later than ≳ 4.5 days peak beyond the optical regime. The spectra are mostly featureless, although we identify a possible weak emission line at ∼7900 Å at t≲ 4.5 days. The colors, rapid evolution, and featureless spectrum are consistent with a “blue” kilonova from polar ejecta comprised mainly of light r-process nuclei with atomic mass number A≲ 140. This indicates a sightline within {θ }{obs}≲ 45^\circ of the orbital axis. Comparison to models suggests ∼0.03 M ⊙ of blue ejecta, with a velocity of ∼ 0.3c. The required lanthanide fraction is ∼ {10}-4, but this drops to < {10}-5 in the outermost ejecta. The large velocities point to a dynamical origin, rather than a disk wind, for this blue component, suggesting that both binary constituents are neutron stars (as opposed to a binary consisting of a neutron star and a black hole). For dynamical ejecta, the high mass favors a small neutron star radius of ≲ 12 km. This mass also supports the idea that neutron star mergers are a major contributor to r-process nucleosynthesis.