Supernova radiative-transfer modelling: a new approach using non-local thermodynamic equilibrium and full time dependence

We discuss a new one-dimensional (1D) non-local thermodynamic equilibrium (non-LTE) time-dependent radiative-transfer technique for the simulation of supernova (SN) spectra and light curves. Starting from a hydrodynamical input characterizing the homologously expanding ejecta at a chosen post-explos...

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Published inMonthly notices of the Royal Astronomical Society Vol. 405; no. 4; pp. 2141 - 2160
Main Authors Dessart, Luc, Hillier, D. John
Format Journal Article
LanguageEnglish
Published Oxford, UK Blackwell Publishing Ltd 11.07.2010
Wiley-Blackwell
Oxford University Press
Subjects
Astronomy
Earth, ocean, space
Equilibrium
Exact sciences and technology
radiative transfer
stars: atmospheres
Supernovae
supernovae: general
supernovae: individual: SN 1987A
Thermodynamics
stars: atmospheres
supernovae: individual: SN 1987A
supernovae: general
radiative transfer
Supernovae
Consistency
Light curves
Spectral energy distribution
Thermodynamic non equilibrium
Stellar evolution
Non-LTE
Time dependence
Space-time
Stellar composition
Statistical equilibrium
Ionization
Blanketing
H lines
Supergiant stars
Models
Radiative transfer
LTE
Online AccessGet full text
ISSN0035-8711
1365-2966
DOI10.1111/j.1365-2966.2010.16611.x

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Abstract We discuss a new one-dimensional (1D) non-local thermodynamic equilibrium (non-LTE) time-dependent radiative-transfer technique for the simulation of supernova (SN) spectra and light curves. Starting from a hydrodynamical input characterizing the homologously expanding ejecta at a chosen post-explosion time, we model the evolution of the entire ejecta, including gas and radiation. The boundary constraints for this time-, frequency-, space- and angle-dependent problem are the adopted initial ejecta, a zero-flux inner boundary and a free-streaming outer boundary. This relaxes the often unsuitable assumption of a diffusive inner boundary, but will also allow for a smooth transition from photospheric to nebular conditions. Non-LTE, which holds in all regions at and above the photosphere, is accounted for. The effects of line blanketing on the radiation field are explicitly included, using complex model atoms and solving for all ion level populations appearing in the statistical-equilibrium equations. Here, we present results for SN1987A, evolving the model ‘lm18a7Ad’ of Woosley from 0.27 to 20.8 d. The fastest evolution occurs prior to day 1, with a spectral energy distribution peaking in the range ∼300–2000 Å, subject to line blanketing from highly ionized metal and CNO species. After day 1, our synthetic multiband light curve and spectra reproduce the observations to within 10–20 per cent in flux in the optical, with a greater mismatch for the faint UV flux. We do not encounter any of the former discrepancies associated with He i and H i optical lines, which can be fitted well with a standard blue-supergiant-star surface composition and no contribution from radioactive decay. The effects of time dependence on the ionization structure, discussed in Dessart & Hillier, are recovered, and thus nicely integrated in this new scheme. Despite the 1D nature of our approach, its high physical consistency and accuracy will allow reliable inferences to be made on explosion properties and pre-SN star evolution.
AbstractList We discuss a new one-dimensional (1D) non-local thermodynamic equilibrium (non-LTE) time-dependent radiative-transfer technique for the simulation of supernova (SN) spectra and light curves. Starting from a hydrodynamical input characterizing the homologously expanding ejecta at a chosen post-explosion time, we model the evolution of the entire ejecta, including gas and radiation. The boundary constraints for this time-, frequency-, space- and angle-dependent problem are the adopted initial ejecta, a zero-flux inner boundary and a free-streaming outer boundary. This relaxes the often unsuitable assumption of a diffusive inner boundary, but will also allow for a smooth transition from photospheric to nebular conditions. Non-LTE, which holds in all regions at and above the photosphere, is accounted for. The effects of line blanketing on the radiation field are explicitly included, using complex model atoms and solving for all ion level populations appearing in the statistical-equilibrium equations. Here, we present results for SN1987A, evolving the model 'lm18a7Ad' of Woosley from 0.27 to 20.8 d. The fastest evolution occurs prior to day 1, with a spectral energy distribution peaking in the range ∼300-2000 Å, subject to line blanketing from highly ionized metal and CNO species. After day 1, our synthetic multiband light curve and spectra reproduce the observations to within 10-20 per cent in flux in the optical, with a greater mismatch for the faint UV flux. We do not encounter any of the former discrepancies associated with He i and H i optical lines, which can be fitted well with a standard blue-supergiant-star surface composition and no contribution from radioactive decay. The effects of time dependence on the ionization structure, discussed in Dessart & Hillier, are recovered, and thus nicely integrated in this new scheme. Despite the 1D nature of our approach, its high physical consistency and accuracy will allow reliable inferences to be made on explosion properties and pre-SN star evolution. [PUBLICATION ABSTRACT]
We discuss a new one-dimensional (1D) non-local thermodynamic equilibrium (non-LTE) time-dependent radiative-transfer technique for the simulation of supernova (SN) spectra and light curves. Starting from a hydrodynamical input characterizing the homologously expanding ejecta at a chosen post-explosion time, we model the evolution of the entire ejecta, including gas and radiation. The boundary constraints for this time-, frequency-, space- and angle-dependent problem are the adopted initial ejecta, a zero-flux inner boundary and a free-streaming outer boundary. This relaxes the often unsuitable assumption of a diffusive inner boundary, but will also allow for a smooth transition from photospheric to nebular conditions. Non-LTE, which holds in all regions at and above the photosphere, is accounted for. The effects of line blanketing on the radiation field are explicitly included, using complex model atoms and solving for all ion level populations appearing in the statistical-equilibrium equations. Here, we present results for SN1987A, evolving the model 'lm18a7Ad' of Woosley from 0.27 to 20.8 d. The fastest evolution occurs prior to day 1, with a spectral energy distribution peaking in the range similar to 300-2000 Aa, subject to line blanketing from highly ionized metal and CNO species. After day 1, our synthetic multiband light curve and spectra reproduce the observations to within 10-20 per cent in flux in the optical, with a greater mismatch for the faint UV flux. We do not encounter any of the former discrepancies associated with He i and H i optical lines, which can be fitted well with a standard blue-supergiant-star surface composition and no contribution from radioactive decay. The effects of time dependence on the ionization structure, discussed in Dessart & Hillier, are recovered, and thus nicely integrated in this new scheme. Despite the 1D nature of our approach, its high physical consistency and accuracy will allow reliable inferences to be made on explosion properties and pre-SN star evolution.
We discuss a new one-dimensional (1D) non-local thermodynamic equilibrium (non-LTE) time-dependent radiative-transfer technique for the simulation of supernova (SN) spectra and light curves. Starting from a hydrodynamical input characterizing the homologously expanding ejecta at a chosen post-explosion time, we model the evolution of the entire ejecta, including gas and radiation. The boundary constraints for this time-, frequency-, space- and angle-dependent problem are the adopted initial ejecta, a zero-flux inner boundary and a free-streaming outer boundary. This relaxes the often unsuitable assumption of a diffusive inner boundary, but will also allow for a smooth transition from photospheric to nebular conditions. Non-LTE, which holds in all regions at and above the photosphere, is accounted for. The effects of line blanketing on the radiation field are explicitly included, using complex model atoms and solving for all ion level populations appearing in the statistical-equilibrium equations. Here, we present results for SN1987A, evolving the model 'lm18a7Ad' of Woosley from 0.27 to 20.8 d. The fastest evolution occurs prior to day 1, with a spectral energy distribution peaking in the range ∼300-2000 Å, subject to line blanketing from highly ionized metal and CNO species. After day 1, our synthetic multiband light curve and spectra reproduce the observations to within 10-20 per cent in flux in the optical, with a greater mismatch for the faint UV flux. We do not encounter any of the former discrepancies associated with He i and H i optical lines, which can be fitted well with a standard blue-supergiant-star surface composition and no contribution from radioactive decay. The effects of time dependence on the ionization structure, discussed in Dessart & Hillier, are recovered, and thus nicely integrated in this new scheme. Despite the 1D nature of our approach, its high physical consistency and accuracy will allow reliable inferences to be made on explosion properties and pre-SN star evolution.
ABSTRACT We discuss a new one‐dimensional (1D) non‐local thermodynamic equilibrium (non‐LTE) time‐dependent radiative‐transfer technique for the simulation of supernova (SN) spectra and light curves. Starting from a hydrodynamical input characterizing the homologously expanding ejecta at a chosen post‐explosion time, we model the evolution of the entire ejecta, including gas and radiation. The boundary constraints for this time‐, frequency‐, space‐ and angle‐dependent problem are the adopted initial ejecta, a zero‐flux inner boundary and a free‐streaming outer boundary. This relaxes the often unsuitable assumption of a diffusive inner boundary, but will also allow for a smooth transition from photospheric to nebular conditions. Non‐LTE, which holds in all regions at and above the photosphere, is accounted for. The effects of line blanketing on the radiation field are explicitly included, using complex model atoms and solving for all ion level populations appearing in the statistical‐equilibrium equations. Here, we present results for SN1987A, evolving the model ‘lm18a7Ad’ of Woosley from 0.27 to 20.8 d. The fastest evolution occurs prior to day 1, with a spectral energy distribution peaking in the range ∼300–2000 Å, subject to line blanketing from highly ionized metal and CNO species. After day 1, our synthetic multiband light curve and spectra reproduce the observations to within 10–20 per cent in flux in the optical, with a greater mismatch for the faint UV flux. We do not encounter any of the former discrepancies associated with He i and H i optical lines, which can be fitted well with a standard blue‐supergiant‐star surface composition and no contribution from radioactive decay. The effects of time dependence on the ionization structure, discussed in Dessart & Hillier, are recovered, and thus nicely integrated in this new scheme. Despite the 1D nature of our approach, its high physical consistency and accuracy will allow reliable inferences to be made on explosion properties and pre‐SN star evolution.
Author Dessart, Luc
Hillier, D. John
Author_xml – sequence: 1
  givenname: Luc
  surname: Dessart
  fullname: Dessart, Luc
  email: luc.dessart@oamp.fr, * luc.dessart@oamp.fr
  organization: Laboratoire d'Astrophysique de Marseille, Université de Provence, CNRS, 38 rue Frédéric Joliot-Curie, F-13388 Marseille Cedex 13, France
– sequence: 2
  givenname: D. John
  surname: Hillier
  fullname: Hillier, D. John
  organization: Department of Physics and Astronomy, University of Pittsburgh, Pittsburgh, PA 15260, USA
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Issue 4
Keywords stars: atmospheres
supernovae: individual: SN 1987A
supernovae: general
radiative transfer
Supernovae
Consistency
Light curves
Spectral energy distribution
Thermodynamic non equilibrium
Stellar evolution
Non-LTE
Time dependence
Space-time
Stellar composition
Statistical equilibrium
Ionization
Blanketing
H lines
Supergiant stars
Models
Radiative transfer
LTE
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PublicationTitle Monthly notices of the Royal Astronomical Society
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SSID ssj0004326
Score 2.368034
Snippet We discuss a new one-dimensional (1D) non-local thermodynamic equilibrium (non-LTE) time-dependent radiative-transfer technique for the simulation of supernova...
ABSTRACT We discuss a new one‐dimensional (1D) non‐local thermodynamic equilibrium (non‐LTE) time‐dependent radiative‐transfer technique for the simulation of...
SourceID proquest
pascalfrancis
crossref
wiley
oup
istex
SourceType Aggregation Database
Index Database
Enrichment Source
Publisher
StartPage 2141
SubjectTerms Astronomy
Earth, ocean, space
Equilibrium
Exact sciences and technology
radiative transfer
stars: atmospheres
Supernovae
supernovae: general
supernovae: individual: SN 1987A
Thermodynamics
Title Supernova radiative-transfer modelling: a new approach using non-local thermodynamic equilibrium and full time dependence
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