3,022,775 research outputs found
Type Ia Supernovae
Type Ia Supernovae are in many aspects still enigmatic objects. Recent years
have witnessed a bonanza of supernova observations. The increased samples from
dedicated searches have allowed the statistical investigation of Type Ia
Supernovae as a class. The observational data on Type Ia Supernovae are very
rich, and the uniform picture of a decade ago has been replaced by several
correlations which connect the maximum luminosity with light curve shape, color
evolution, spectral appearance, and host galaxy morphology. These correlations
hold across almost the complete spectrum of Type Ia Supernovae, with a number
of notable exceptions. After 150 days past maximum, however, all observed
objects show the same decline rate and spectrum. Bolometric light curves are a
handy tool to investigate the overall appearance of Type Ia Supernovae. The
nickel masses derived this way show large variations, which combined with the
dynamics from line widths, indicate that the brighter events are also coming
from more massive objects. The lack of accurate distances and the uncertainty
in the correction for absorption are hampering further progress. Improvements
in these areas are vital for the detailed comparison of luminosities and the
determination of nickel masses.Comment: 33 pages with 4 embedded figures; To appear in Astronomy and
Astrophysics Revie
SweetSpot: Near-Infrared Observations of Thirteen Type Ia Supernovae from a New NOAO Survey Probing the Nearby Smooth Hubble Flow
We present 13 Type Ia supernovae (SNe Ia) observed in the restframe
near-infrared (NIR) from 0.02 < z < 0.09 with the WIYN High-resolution Infrared
Camera (WHIRC) on the WIYN 3.5-m telescope. With only 1-3 points per light
curve and a prior on the time of maximum from the spectrum used to type the
object we measure an H-band dispersion of spectroscopically normal SNe Ia of
0.164 mag. These observations continue to demonstrate the improved standard
brightness of SNe Ia in H-band even with limited data. Our sample includes two
SNe Ia at z ~ 0.09, which represent the most distant restframe NIR H-band
observations published to date.
This modest sample of 13 NIR SNe Ia represent the pilot sample for
"SweetSpot" - a three-year NOAO Survey program that will observe 144 SNe Ia in
the smooth Hubble flow. By the end of the survey we will have measured the
relative distance to a redshift of z ~ 0.05 to 1%. Nearby Type Ia supernova (SN
Ia) observations such as these will test the standard nature of SNe Ia in the
restframe NIR, allow insight into the nature of dust, and provide a critical
anchor for future cosmological SN Ia surveys at higher redshift.Comment: 36 pages, 8 figures, Submitted to Ap
The Relation Between Ejecta Velocity, Intrinsic Color, and Host-Galaxy Mass for High-Redshift Type Ia Supernovae
Recently, using a large low-redshift sample of Type Ia supernovae (SNe Ia),
we discovered a relation between SN Ia ejecta velocity and intrinsic color that
improves the distance precision of SNe Ia and reduces potential systematic
biases related to dust reddening. No SN Ia cosmological results have yet made a
correction for the "velocity-color" relation. To test the existence of such a
relation and constrain its properties at high redshift, we examine a sample of
75 SNe Ia discovered and observed by the Sloan Digital Sky Survey-II (SDSS-II)
Supernova Survey and Supernova Legacy Survey (SNLS). From each spectrum, we
measure ejecta velocities at maximum brightness for the Ca H&K and Si II 6355
features, v_Ca^0 and v_Si^0, respectively. Using SN light-curve parameters, we
determine the intrinsic B_max - V_max for each SN. Similar to what was found at
low-redshift, we find that SNe Ia with higher ejecta velocity tend to be
intrinsically redder than SNe Ia with lower ejecta velocity. The distributions
of ejecta velocities for SNe Ia at low and high redshift are similar,
indicating that current cosmological results should have little bias related to
the velocity-color relation. Additionally, we find a slight (2.4-sigma
significant) trend between SN Ia ejecta velocity and host-galaxy mass such that
SNe Ia in high-mass host galaxies tend to have lower ejecta velocities as
probed by v_Ca^0. These results emphasize the importance of spectroscopy for SN
Ia cosmology.Comment: 13 pages, 11 figures, accepted by Ap
Sampling the Probability Distribution of Type Ia Supernova Lightcurve Parameters in Cosmological Analysis
In order to obtain robust cosmological constraints from Type Ia supernova (SN
Ia) data, we have applied Markov Chain Monte Carlo (MCMC) to SN Ia lightcurve
fitting. We develop a method for sampling the resultant probability density
distributions (pdf) of the SN Ia lightcuve parameters in the MCMC likelihood
analysis to constrain cosmological parameters, and validate it using simulated
data sets. Applying this method to the Joint Lightcurve Analysis (JLA) data set
of SNe Ia, we find that sampling the SN Ia lightcurve parameter pdf's leads to
cosmological parameters closer to that of a flat Universe with a cosmological
constant, compared to the usual practice of using only the best fit values of
the SN Ia lightcurve parameters. Our method will be useful in the use of SN Ia
data for precision cosmology.Comment: 9 pages, 6 figures, 4 tables. Revised version accepted by MNRA
High-Velocity Features in Type Ia Supernova Spectra
We use a sample of 58 low-redshift (z <= 0.03) Type Ia supernovae (SNe Ia)
having well-sampled light curves and spectra near maximum light to examine the
behaviour of high-velocity features (HVFs) in SN Ia spectra. We take advantage
of the fact that Si II 6355 is free of HVFs at maximum light in all SNe Ia,
allowing us to quantify the strength of HVFs by comparing the structure of
these two lines. We find that the average HVF strength increases with
decreasing light-curve decline rate, and rapidly declining SNe Ia (dm_15(B) >=
1.4 mag) show no HVFs in their maximum-light spectra. Comparison of HVF
strength to the light-curve colour of the SNe Ia in our sample shows no
evidence of correlation. We find a correlation of HVF strength with the
velocity of Si II 6355 at maximum light (v_Si), such that SNe Ia with lower
v_Si have stronger HVFs, while those SNe Ia firmly in the "high-velocity"
(i.e., v_Si >= 12,000 km/s) subclass exhibit no HVFs in their maximum-light
spectra. While v_Si and dm_15(B) show no correlation in the full sample of SNe
Ia, we find a significant correlation between these quantities in the subset of
SNe Ia having weak HVFs. In general, we find that slowly declining (low
dm_15(B)) SNe Ia, which are more luminous and more energetic than average SNe
Ia, tend to produce either high photospheric ejecta velocities (i.e., high
v_Si) or strong HVFs at maximum light, but not both. Finally, we examine the
evolution of HVF strength for a sample of SNe Ia having extensive pre-maximum
spectroscopic coverage and find significant diversity of the pre-maximum HVF
behaviour.Comment: Version accepted by MNRA
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