888 research outputs found
The Changing Fractions of Type Ia Supernova NUV-Optical Subclasses with Redshift
UV and optical photometry of Type Ia supernovae (SNe Ia) at low redshift have
revealed the existence of two distinct color groups, NUV-red and NUV-blue
events. The color curves differ primarily by an offset, with the NUV-blue u-
color curves bluer than the NUV-red curves by 0.4 mag. For a sample of 23 low-z
SNe~Ia observed with Swift, the NUV-red group dominates by a ratio of 2:1. We
compare rest-frame UV/optical spectrophotometry of intermediate and high-z SNe
Ia with UVOT photometry and HST spectrophotometry of low-z SNe Ia, finding that
the same two color groups exist at higher-z, but with the NUV-blue events as
the dominant group. Within each red/blue group, we do not detect any offset in
color for different redshifts, providing insight into how SN~Ia UV emission
evolves with redshift. Through spectral comparisons of SNe~Ia with similar peak
widths and phase, we explore the wavelength range that produces the UV/OPT
color differences. We show that the ejecta velocity of NUV-red SNe is larger
than that of NUV-blue objects by roughly 12% on average. This velocity
difference can explain some of the UV/optical color difference, but differences
in the strengths of spectral features seen in meanspectra require additional
explanation. Because of the different b-v colors for these groups, NUV-red SNe
will have their extinction underestimated using common techniques. This, in
turn, leads to under-estimation of the optical luminosity of the NUV-blue
SNe~Ia, in particular, for the high-redshift cosmological sample. Not
accounting for this effect should thus produce a distance bias that increases
with redshift and could significantly bias measurements of cosmological
parameters.Comment: submitted to Ap
WFIRST: Enhancing Transient Science and Multi-Messenger Astronomy
Astrophysical transients have been observed for millennia and have shaped our most basic assumptions about the Universe. In the last century, systematic searches have grown from detecting handfuls of transients per year to over 7000 in 2018 alone. As these searches have matured, we have discovered both large samples of "normal" classes and new, rare classes. Recently, a transient was the first object observed in both gravitational waves and light. Ground-based observatories, including LSST, will discover thousands of transients in the optical, but these facilities will not provide the high-fidelity near-infrared (NIR) photometry and high-resolution imaging of a space-based observatory. WFIRST can fill this gap. With its survey designed to measure the expansion history of the Universe with Type Ia supernovae, WFIRST will also discover and monitor thousands of other transients in the NIR, revealing the physics for these high-energy events. Small-scale GO programs, either as a supplement to the planned survey or as specific target-of-opportunity observations, would significantly expand the scope of transient science that can be studied with WFIRST
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