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Exploring the global properties of SNe Ia. Paolo A. Mazzali Max-Planck Institut f ϋ r Astrophysik, Garching Astronomy Department and RESearch Centre for the Early Universe, University of Tokyo Istituto Naz. di Astrofisica, OATs. Spectra of Supernovae: the photospheric phase.
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Exploring the global properties of SNe Ia Paolo A. Mazzali Max-Planck Institut fϋr Astrophysik, Garching Astronomy Department and RESearch Centre for the Early Universe, University of Tokyo Istituto Naz. di Astrofisica, OATs
Spectra of Supernovae:the photospheric phase SN Ia SN II SN Ic SN Ib Galileo Galilei Institute
SNe Ia have similar light curvesAre they also equally luminous? Branch & Tammann 1992 Galileo Galilei Institute
87 SNe Ia: Observed B Light Curves Galileo Galilei Institute
87 SNe Ia: Normalised B Light Curves Galileo Galilei Institute
87 SNe Ia: Stretched B Light Curves Galileo Galilei Institute
The Phillips Relation (Absolute Magnitude - Decline Rate) Phillips 1992 Galileo Galilei Institute
Cosmology with SNe Ia Distant SNe are FAINT for their redshift From B.Schmidt Galileo Galilei Institute
Cosmology with SNe Ia Riess et al. 1999 Galileo Galilei Institute
empty universe fainter • High-z SN Search Team • (Riess et al. 1998) • Supernova Cosmology Project • (Perlmutter et al. 1999) brighter nearer further SN Ia as distance indicators • surprising result: • Distant SNe Ia appear fainter • than standard candles in an • empty Friedmann model • of the universe! • SN Ia luminosity distances • indicate • accelerated expansion! • Are SNIaStandard Candles • independent of age? • Or is there some evolution • of SN Ia luminosity with age? • Spectroscopy is a • powerful tool to • search for differences! Galileo Galilei Institute
Cosmology with SNe Ia: the Cosmological Constant From E.Baron Galileo Galilei Institute
Bolometric Light Curves Contardo et al. 2000 Galileo Galilei Institute
Soon after explosion (first few weeks), ejecta density is high enough for a `pseudo-photosphere’ to form. “Photospheric Epoch” (early time) P-Cygni Profiles superposed on continuum Later on, photosphere disappears as densities decrease. “Nebular Epoch” (late time) Emission-line spectrum Supernova Spectra evolve Galileo Galilei Institute
SNIa Spectral Evolution Gomez & Lopez 1998 Galileo Galilei Institute
Homologous expansion (v ≈ R) Ejecta are dense “Photospheric Epoch” Early-time spectrum absorption continuum τ=1 Galileo Galilei Institute
Early-time spectrum • Lines have P-Cygni profiles with But velocities are high: many lines overlap: “Line Blanketing” Galileo Galilei Institute
SNe Ia @ maximum “Branch normals” Galileo Galilei Institute
SNe Ia @ 20 days after maximum “Branch normal” Galileo Galilei Institute
Late-time spectra Spectrum: no continuum. Emission line profiles depend on velocity, abundance distribution. Homologous expansion, homogenous density and abundance: parabolic profiles Ejecta are thin: “Nebular Epoch” Gas heated by deposition of γ’s and cooled by forbidden line emission τ < 1 Galileo Galilei Institute
SNe Ia: late-time spectra Δm15(B) 1.93 1.77 1.27 1.51 0.87 Mazzali et al. 1998 Galileo Galilei Institute
Thermonuclear SNe (Type Ia)White Dwarf in BinarySystem WD accretes H until MWD~1.4M⊙, T~109K • Thermonuclear burning (C burning) to NSE • Explosion (KE~1051 erg) • Total disruption of WD • 56Ni produced (~0.7M⊙) RG CO-WD C,O Si, S 56Ni Galileo Galilei Institute
Type Ia SN 1996X spectral evolution Salvo et al. 2000 Galileo Galilei Institute
The Classical SN Ia explosion model: W7 Branch et al. 1985 Galileo Galilei Institute
I. Using observables to understand SNe Ia Questions • Properties of SNe Ia (eg Phillips rel’n) • Mode of explosion (deflagration, delayed detonation, other even less reasonable modes…) • Cosmology? Methods • Look at/model spectra & light curves Galileo Galilei Institute
What we need • Excellent photometric and spectroscopic coverage of a number of nearby SNe Ia • Comparison with the high-z sample • 3D models of the explosion Galileo Galilei Institute
How we get it: the EU-RTN • 16 well observed SNe (2002-2006) Abundance Tomography More signatures of CSM interaction Galileo Galilei Institute
Data: SNe 2002bo, 2003du Galileo Galilei Institute
Modelling early-time spectra Monte Carlo code • Composition • Density • Luminosity • Velocity Galileo Galilei Institute
Abundance Stratification • Model sequence of spectra to derive composition layering • How did the star burn? Stehle et al 2005 Galileo Galilei Institute
Model late-time spectra Monte Carlo LC code + NLTE nebular code • No radiative transfer • Get full view of inner ejecta (56Ni zone) • Estimate masses Galileo Galilei Institute
Composion in a typical SN Ia • Elements more mixed than in typical 1D models Galileo Galilei Institute
Test: Light Curve Monte Carlo code • Use W7 density • Composition from tomography • (56Ni ~0.50M⊙ ) Model LC matches data very well Galileo Galilei Institute
II. Outer regions of the ejecta: HVFs • Nearly all SNe show very high velocity (~20000 km/s) absorption features (HVF) in Ca II (some also in Si II) Galileo Galilei Institute
HVFs come in various forms Mazzali et al. (2005) Tanaka et al. (2006) Galileo Galilei Institute
What makes the HVFs • Abundance enhancement unlikely • Density enhancement more reasonable • Ejection of blobs or CSM interaction? • Blobs: line profiles depend on orientation Galileo Galilei Institute
Distribution of HVFs • Any model should reproduce the observed distribution of HVF wavelength (blob velocity) and strength (optical depth, covering factor) • Single blob does not Galileo Galilei Institute
Need a few blobs or a thick torus Galileo Galilei Institute
Use blobs to fit spectra Galileo Galilei Institute
3D Simulations (MPA) Reinecke et al. 2000 Galileo Galilei Institute
III. The Global View • Late time spectra suggest M(56Ni) Δm15(B) [ M(Bol)] v(Fe) Galileo Galilei Institute
Role of 54Fe, 58Ni • Stable Fe group isotopes radiate but do not heat • Some anticorrelation between 56Ni and (54Fe, 58Ni) • Very good correlation beween Σ(NSE)andΔm15(B) Galileo Galilei Institute
Composition Layering • Outer extent of Fe zone varies ( Δm15(B), Lum) • Inner extent of IME matches outer extent of Fe • Outer extent of IME ~ const. Galileo Galilei Institute
Include 54Fe, 58Ni: “Zorro” diagram A basic property of SNe Ia Mass probably constant Amount of burned material also probably constant • KE ~ const • What does it all mean? • Delayed detonation? • Multi-spot ignited deflagration? • Other possibilities….? Galileo Galilei Institute
IV. Role of Fe-group, IME on LC • 56Ni: light, opacity, KE • 54Fe, 58Ni: opacity, KE • IME: KE, (some opacity) • CO (if any): little opacity Galileo Galilei Institute
Explaining Phillips’ Relation • 56Ni: light, opacity, KE Reproduce • 54Fe, 58Ni: opacity, KE Phillips’ Relation • IME: KE, (some opacity) • CO (if any): little opacity (Mazzali et al. 2001) Galileo Galilei Institute
Spectra @ -7 days Mazzali et al. 2001 Galileo Galilei Institute
Spectra @ Maximum Mazzali et al. 2001 Galileo Galilei Institute
Spectra @ +15 days Mazzali et al. 2001 Galileo Galilei Institute
Using Zorro to reconstruct Phillips’ Rel’n • Use composition to compute LC parameters • Derive Phillips Relation Galileo Galilei Institute
Effect of 54Fe, 58Ni • Amount of 54Fe, 58Ni may be a fn. of WD metallicity (Timmes et al. 2003) • Ratio 56Ni/NSE affects light, not KE or opacity • LCs w/ different peak brightness, same decline rate • May explain spread in Phillips’ Relation. Galileo Galilei Institute