Near-infrared light curves of type Ia supernovae

Aims. With our time-dependent model atmosphere code PHOENIX, our goal is to simulate light curves and spectra of hydrodynamical models of all types of supernovae. In this work, we simulate near-infrared light curves of SNe Ia and confirm the cause of the secondary maximum. Methods. We apply a simple energy solver to compute the evolution of an SN Ia envelope during the free expansion phase. Included in the solver are energy changes due to expansion, the energy deposition of {\gamma}-rays and interaction of radiation with the material. Results. We computed theoretical light curves of several SN Ia hydrodynamical models in the I, J, H, and K bands and compared them to the observed SN Ia light curves of SN 1999ee and SN 2002bo. By changing a line scattering parameter in time, we obtained quite reasonable fits to the observed near-infrared light curves. This is a strong hint that detailed NLTE effects in IR lines have to be modeled, which will be a future focus of our work. Conclusions. We found that IR line scattering is very important for the near-infrared SN Ia light curve modeling. In addition, the recombination of Fe III to Fe II and of Co III to Co II is responsible for the secondary maximum in the near-infrared bands. For future work the consideration of NLTE for all lines (including the IR subordinate lines) will be crucial.

[1]  E. Baron,et al.  Theoretical light curves of type Ia supernovae , 2011, 1105.3330.

[2]  J. Sollerman,et al.  An asymmetric explosion as the origin of spectral evolution diversity in type Ia supernovae , 2010, Nature.

[3]  E. Baron,et al.  Time-dependent radiative transfer with PHOENIX , 2009, 0907.1441.

[4]  R. Kotak,et al.  Signatures of Delayed Detonation, Asymmetry, and Electron Capture in the Mid-Infrared Spectra of Supernovae 2003hv and 2005df , 2007, astro-ph/0702117.

[5]  J. Wheeler,et al.  The Chemical Distribution in a Subluminous Type Ia Supernova: Hubble Space Telescope Images of the SN 1885 Remnant , 2006, astro-ph/0611779.

[6]  P. Mazzali,et al.  The Asymmetric Explosion of Type Ia Supernovae as Seen from Near-Infrared Observations , 2006, astro-ph/0610303.

[7]  D. Kasen Secondary Maximum in the Near-Infrared Light Curves of Type Ia Supernovae , 2006, astro-ph/0606449.

[8]  K. Nomoto,et al.  Signature of Electron Capture in Iron-rich Ejecta of SN 2003du , 2004, astro-ph/0409185.

[9]  S. E. Persson,et al.  Optical and Infrared Photometry of the Type Ia Supernovae 1991T, 1991bg, 1999ek, 2001bt, 2001cn, 2001cz, and 2002bo , 2004, astro-ph/0409036.

[10]  Kevin Krisciunas,et al.  Hubble Diagrams of Type Ia Supernovae in the Near-Infrared , 2003, astro-ph/0312626.

[11]  S. E. Persson,et al.  Optical and Infrared Photometry of the Nearby Type Ia Supernovae 1999ee, 2000bh, 2000ca, and 2001ba , 2003, astro-ph/0311439.

[12]  S. Sakai,et al.  Infrared Spectra of the Subluminous Type Ia Supernova SN 1999by , 2001, astro-ph/0112126.

[13]  P. Pinto,et al.  The Physics of Type Ia Supernova Light Curves. II. Opacity and Diffusion , 1996, astro-ph/9611195.

[14]  P. Nugent,et al.  NON-LOCAL THERMODYNAMIC EQUILIBRIUM EFFECTS IN MODELLING OF SUPERNOVAE NEAR MAXIMUM LIGHT , 1996 .

[15]  J. Wheeler,et al.  Delayed detonation models for normal and subluminous type Ia sueprnovae: Absolute brightness, light curves, and molecule formation , 1995 .

[16]  K. Nomoto Evolution of 8-10 solar mass stars toward electron capture supernovae. I - Formation of electron-degenerate O + NE + MG cores. , 1984 .

[17]  S. E. Persson,et al.  Infrared light curves of Type I supernovae , 1981, astro-ph/0211100.

[18]  K. Weiler,et al.  Supernovae and Supernova Remnants , 1988 .