1. Studying the Ultraviolet Spectrum of the First Spectroscopically Confirmed Supernova at Redshift Two.
- Author
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M. Smith, M. Sullivan, R. C. Nichol, L. Galbany, C. B. D’Andrea, C. Inserra, C. Lidman, A. Rest, M. Schirmer, A. V. Filippenko, W. Zheng, S. Bradley Cenko, C. R. Angus, P. J. Brown, T. M. Davis, D. A. Finley, R. J. Foley, S. González-Gaitán, C. P. Gutiérrez, and R. Kessler
- Subjects
ULTRAVIOLET spectra ,SUPERNOVAE ,REDSHIFT ,ASTRONOMICAL spectroscopy ,STELLAR luminosity function - Abstract
We present observations of DES16C2nm, the first spectroscopically confirmed hydrogen-free superluminous supernova (SLSN-I) at redshift . DES16C2nm was discovered by the Dark Energy Survey (DES) Supernova Program, with follow-up photometric data from the Hubble Space Telescope, Gemini, and the European Southern Observatory Very Large Telescope supplementing the DES data. Spectroscopic observations confirm DES16C2nm to be at z = 1.998, and spectroscopically similar to Gaia16apd (a SLSN-I at z = 0.102), with a peak absolute magnitude of . The high redshift of DES16C2nm provides a unique opportunity to study the ultraviolet (UV) properties of SLSNe-I. Combining DES16C2nm with 10 similar events from the literature, we show that there exists a homogeneous class of SLSNe-I in the UV ( Å), with peak luminosities in the (rest-frame) U band, and increasing absorption to shorter wavelengths. There is no evidence that the mean photometric and spectroscopic properties of SLSNe-I differ between low () and high redshift (), but there is clear evidence of diversity in the spectrum at , possibly caused by the variations in temperature between events. No significant correlations are observed between spectral line velocities and photometric luminosity. Using these data, we estimate that SLSNe-I can be discovered to z = 3.8 by DES. While SLSNe-I are typically identified from their blue observed colors at low redshift (), we highlight that at these events appear optically red, peaking in the observer-frame z-band. Such characteristics are critical to identify these objects with future facilities such as the Large Synoptic Survey Telescope, Euclid, and the Wide-field Infrared Survey Telescope, which should detect such SLSNe-I to z = 3.5, 3.7, and 6.6, respectively. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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