VLT Spectropolarimetry of the Type Ia SN 2005ke

Patat, F.; Hoêflich, P.; Baade, D.; Maund, Justyn R.; Wang, L.; Wheeler, J. C.

doi:10.1051/0004-6361/201219146

Cited by 63 publications

(87 citation statements)

References 99 publications

(138 reference statements)

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“…The explosions will produce a wide variety of envelope masses ranging from well below M Ch to super-M Ch and very asymmetric density distributions in their ejecta. This class of objects will show a significant continuum polarization that has not be observed, and we must expect a directional dependence of the luminosity, which would result in a wide spread of observed ∆m 15 and ∆m 15,s (Höflich et al 2006;Patat et al 2012;Bulla et al 2016).…”

Section: Alternative Explosion Scenariosmentioning

confidence: 95%

“…The comparison does not constitute spectral fits or analyzes. For dedicated fits and identification of features, we will refer to previous papers mentioned above (e.g., Hoeflich 1995;Wheeler et al 1998;Hoeflich et al 2002;Patat et al 2012). We will focus on spectral properties relevant for the LCs and the color evolution.…”

Section: Spectral Formation In Context Of Light Curvesmentioning

confidence: 99%

“…The suite of models involve a transition from deflagration to detonation burning parameterized by the transition density, ρ tr . While a wide variety of explosion mechanisms may be possible in nature, we choose the DDT scenario because it predicts some of the basic characteristics of SNe Ia: overall spherical density distributions as indicated by small continuum polarization (Howell et al 2001;Maund et al 2010;Patat et al 2012), overall spherical geometry of SN Ia remnants (SNR) with layered chemical structures (Rest et al 2005;Badenes et al 2006;Fesen et al 2007;Rest et al 2008), "broad" emission line profiles and stable…”

Section: Introductionmentioning

confidence: 99%

“…These models have been widely applied to analyze and fit individual SNe Ia, particularly flux in the optical and IR and polarization spectra (Hoeflich 1995;Hoeflich et al 1998;Wheeler et al 1998;Lentz et al 2001;Quimby et al 2006;Baron et al 2012;Patat et al 2012;Baron et al 2015;Diamond et al 2015;Telesco et al 2015). Note that very similar chemical abundances and velocity structures have been obtained by the analysis of observed spectral sequences using the method of "spectral tomog-…”

mentioning

confidence: 99%

See 3 more Smart Citations

Light and Color Curve Properties of Type Ia Supernovae: Theory Versus Observations

Hoêflich

Hsiao

Ashall

et al. 2017

ApJ

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102

178

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We study optical light curve(LC) relations of type Ia supernovae(SNe Ia) for their use in cosmology using high-quality photometry published by the Carnegie-Supernovae-Project(CSP-I). We revisit the classical luminosity-decline-rate (∆m 15 ) relation and the Lira-relation, as well as investigate the time evolution of the (B −V ) color and B(B −V ), which serves as the basis of the color-stretch relation and Color-MAGnitude-Intercept-Calibrations(CMAGIC). Our analysis is based on explosion and radiation transport simulations for spherically-symmetric delayed-detonation models(DDT) producing normalbright and subluminous SNe Ia. Empirical LC-relations can be understood as having the same physical underpinnings: i.e. the opacities, ionization balances in the photosphere, and radioactive energy deposition changing with time from below to above the photosphere. Some 3−4 weeks past maximum, the photosphere recedes to 56 Ni-rich layers of similar density structure, leading to a similar color evolution. An important secondary parameter is the central density ρ c of the WD because at higher densities more electron capture elements are produced at the expense of 56Ni production. This results in a ∆m 15 spread of 0.1 mag for normal-bright and 0.7 mag in sub-luminous SNe Ia and ≈ 0.2 mag in the Lira-relation. We show why color-magnitude diagrams emphasize the transition between physical regimes, and enables the construction of templates which depend mostly on ∆m 15 with little dispersion in both the CSP-I sample and our DDT-models. This allows to separate intrinsic SN Ia variations from the interstellar reddening characterized by E(B −V ) and R B . Invoking different scenarios causes a wide spread in empirical relations which may suggest one dominant scenario.

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Section: Alternative Explosion Scenariosmentioning

confidence: 95%

Section: Spectral Formation In Context Of Light Curvesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Light and Color Curve Properties of Type Ia Supernovae: Theory Versus Observations

Hoêflich

Hsiao

Ashall

et al. 2017

ApJ

Self Cite

102

178

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“…SN 1991bg became the prototype of a whole class of objects, some of which have properties nearly identical to SN 1991bg, while others seem to bridge the gap to normal SNe Ia, and again others deviate in certain respects and are sometimes even more extreme than SN 1991bg itself. In the following we will first focus on SN 1991bg and its close twins, which include SNe 1997cn (Turatto et al, 1998;Jha et al, 2006), 1998de (Modjaz et al, 2001;Jha et al, 2006;Matheson et al, 2008), 1999by Vinkó et al, 2001;Höflich et al, 2002;Garnavich et al, 2004;Silverman et al, 2012), 2005bl (Taubenberger et al, 2008, 2005ke (Hicken et al, 2009;Contreras et al, 2010;Blondin et al, 2012;Silverman et al, 2012;Patat et al, 2012), 2006bz (Hicken et al, 2009), and several other examples contained in the SN Ia samples of Hicken et al (2009), Contreras et al (2010, Ganeshalingam et al (2010), Stritzinger et al (2011), Blondin et al (2012 and Silverman et al (2012). In Sections 3.6 and 3.7 we will then discuss transitional 86G-like objects and the very subluminous and peculiar transient PTF 09dav, respectively.…”

Section: Bg-like Sne: Cool and Subluminousmentioning

confidence: 99%

The Extremes of Thermonuclear Supernovae

Taubenberger¹

2016

Handbook of Supernovae

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The majority of thermonuclear explosions in the Universe seem to proceed in a rather standardised way, as explosions of carbon-oxygen (CO) white dwarfs in binary systems, leading to 'normal' Type Ia supernovae (SNe Ia). However, over the years a number of objects have been found which deviate from normal SNe Ia in their observational properties, and which require different and not seldom more extreme progenitor systems. While the 'traditional' classes of peculiar SNe Ia -luminous '91T-like' and faint '91bg-like' objects -have been known since the early 1990s, other classes of even more unusual transients have only been established 20 years later, fostered by the advent of new wide-field SN surveys such as the Palomar Transient Factory. These include the faint but slowly declining '02es-like' SNe, 'Ca-rich' transients residing in the luminosity gap between classical novae and supernovae, extremely short-lived, fast-declining transients, and the very luminous so-called 'super-Chandrasekhar' SNe Ia. Not all of them are necessarily thermonuclear explosions, but there are good arguments in favour of a thermonuclear origin for most of them. The aim of this chapter is to provide an overview of the zoo of potentially thermonuclear transients, reviewing their observational characteristics and discussing possible explosion scenarios.

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Thermonuclear Supernovae: Prospecting in the Age of Time-Domain and Multi-wavelength Astronomy

Hoêflich

Ashall

Fisher

et al. 2019

Springer Proceedings in Physics

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We show how new and upcoming advances in the age of timedomain and multi-wavelength astronomy will open up a new venue to probe the diversity of SN Ia. We discuss this in the context of the ELT (ESO), as well as space based instrument such as James Webb Space Telescope (JWST). As examples we demonstrate how the power of very early observations, within hours to days after the explosion, and very late-time observations, such as light curves and mid-infraread spectra beyond 3 years, can be used to probe the link to progenitors and explosion scenarios. We identify the electron-capture cross sections of Cr, M n, and N i/Co as one of the limiting factors we will face in the future.

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VLT Spectropolarimetry of the Type Ia SN 2005ke

Cited by 63 publications

References 99 publications

Light and Color Curve Properties of Type Ia Supernovae: Theory Versus Observations

Light and Color Curve Properties of Type Ia Supernovae: Theory Versus Observations

The Extremes of Thermonuclear Supernovae

Thermonuclear Supernovae: Prospecting in the Age of Time-Domain and Multi-wavelength Astronomy

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