Type II Supernova Spectral Diversity. II. Spectroscopic and Photometric Correlations

We present an analysis of observed trends and correlations between a large range of spectral and photometric parameters of more than 100 type II supernovae (SNe II), during the photospheric phase. We define a common epoch for all SNe of 50 days post-explosion, where the majority of the sample is lik...

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Detalles Bibliográficos
Autores principales: Gutiérrez, Claudia P., Anderson, Joseph P., Hamuy, Mario, González Gaitan, Santiago, Galbany, Lluis, Dessart, Luc, Stritzinger, Maximilian D., Phillips, Mark M., Morrell, Nidia Irene, Folatelli, Gastón
Formato: Articulo
Lenguaje:Inglés
Publicado: 2017
Materias:
Ciencias Astronómicas
supernovae: general
surveys
Acceso en línea:http://sedici.unlp.edu.ar/handle/10915/87146
Aporte de:
SEDICI (UNLP) de Universidad Nacional de La Plata
Descripción
Sumario:We present an analysis of observed trends and correlations between a large range of spectral and photometric parameters of more than 100 type II supernovae (SNe II), during the photospheric phase. We define a common epoch for all SNe of 50 days post-explosion, where the majority of the sample is likely to be under similar physical conditions. Several correlation matrices are produced to search for interesting trends between more than 30 distinct light-curve and spectral properties that characterize the diversity of SNe II. Overall, SNe with higher expansion velocities are brighter, have more rapidly declining light curves, shorter plateau durations, and higher <sup>56</sup>Ni masses. Using a larger sample than previous studies, we argue that "<i>Pd</i>" - the plateau duration from the transition of the initial to "plateau" decline rates to the end of the "plateau" - is a better indicator of the hydrogen envelope mass than the traditionally used optically thick phase duration (<i>OPTd</i>: explosion epoch to end of plateau). This argument is supported by the fact that <i>Pd</i> also correlates with s<sub>3</sub>, the light-curve decline rate at late times: lower <i>Pd</i> values correlate with larger s<sub>3</sub> decline rates. Large s<sub>3</sub> decline rates are likely related to lower envelope masses, which enables gamma-ray escape. We also find a significant anticorrelation between <i>Pd</i> and s<sub>2</sub> (the plateau decline rate), confirming the long standing hypothesis that faster declining SNe II (SNe IIL) are the result of explosions with lower hydrogen envelope masses and therefore have shorter <i>Pd</i> values.

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