EFFECT OF A HIGH OPACITY ON THE LIGHT CURVES OF RADIOACTIVELY POWERED TRANSIENTS FROM COMPACT OBJECT MERGERS

• Published in: The Astrophysical journal Vol. 775; no. 1; pp. 18 - 9
• Main Authors: Barnes, Jennifer, Kasen, Daniel
• Format: Journal Article
• Language: English
• Published: United States Institute of Physics (IOP) 20.09.2013
• Subjects: abundances; Acquisitions; astronomy & astrophysics; ASTRONOMY AND ASTROPHYSICS; atomic data; Ejecta; Ejection; Infrared; Lanthanides; Mathematical models; nuclear reactions; nucleosynthesis; Opacity; radiative transfer; Spectral energy distribution; stars: neutron: supernovae: general
• ISSN: 0004-637X; 1538-4357
• DOI: 10.1088/0004-637X/775/1/18

The coalescence of compact objects is a promising astrophysical source of detectable gravitational wave signals. The ejection of r-process material from such mergers may lead to a radioactively powered electromagnetic counterpart signal which, if discovered, would enhance the science returns. As very little is known about the optical properties of heavy r-process elements, previous light-curve models have adopted opacities similar to those of iron group elements. Here we consider the effect of heavier elements, particularly the lanthanides, which increase the ejecta opacity by several orders of magnitude. We include these higher opacities in time-dependent, multi-wavelength radiative transport calculations to predict the broadband light curves of one-dimensional models over a range of parameters (ejecta masses ~10 super(-3)-10 super(-1) M sub([middot in circle]) and velocities ~0.1-0.3 c). We find that the higher opacities lead to much longer duration light curves which can last a week or more. The emission is shifted toward the infrared bands due to strong optical line blanketing, and the colors at later times are representative of a blackbody near the recombination temperature of the lanthanides (T ~ 2500 K). We further consider the case in which a second mass outflow, composed of super(56)Ni, is ejected from a disk wind, and show that the net result is a distinctive two component spectral energy distribution, with a bright optical peak due to super(56)Ni and an infrared peak due to r-process ejecta. We briefly consider the prospects for detection and identification of these transients.