Observational Clues to the Progenitors of Type Ia Supernovae

Maoz, Dan; Mannucci, F.; Nelemans, G.

doi:10.1146/annurev-astro-082812-141031

Cited by 939 publications

(928 citation statements)

References 531 publications

(720 reference statements)

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“…However, no (or a very weak) interaction signature from the SN-companion (because of a small companion) or SN-CSM (due to the low density CSM) interaction is predicted in this scenario, making it extremely difficult to explain the early excess UV luminosity seen in SN 2012cg. Also, the exact spin-down timescale of the WD in this model is quite unknown (Maoz, Mannucci & Nelemans 2014).…”

Section: Spin-up/spin-down Modelmentioning

confidence: 99%

Constraining the progenitor of the Type Ia Supernova SN 2012cg

Liu

Stancliffe

2016

Mon. Not. R. Astron. Soc.

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The nature of the progenitors of Type Ia supernovae (SNe Ia) is not yet fully understood. In the single-degenerate (SD) scenario, the collision of the SN ejecta with its companion star is expected to produce detectable ultraviolet (UV) emission in the first few days after the SN explosion within certain viewing angles. It was recently found that the B − V colour of the nearby SN Ia SN 2012cg at about sixteen days before the maximum B-band brightness was about 0.2 mag bluer than those of other normal SNe Ia, which was reported as the first evidence for excess blue light from the interaction of normal SN Ia ejecta with its companion star. In this work, we compare current observations for SN 2012cg from its pre-explosion phase to the late-time nebular phase with theoretical predictions from binary evolution and population synthesis calculations for a variety of popular progenitor scenarios. We find that a main-sequence donor or a carbon-oxygen white dwarf donor binary system is more likely to be the progenitor of SN 2012cg. However, both scenarios also predict properties which are in contradiction to the observed features of this system. Taking both theoretical and observational uncertainties into account, we suggest that it might be too early to conclude that SN 2012cg was produced from an explosion of a Chandrasekhar-mass white dwarf in the SD scenario. Future observations and improved detailed theoretical modelling are still required to place a more stringent constraint on the progenitor of SN 2012cg.

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Section: Spin-up/spin-down Modelmentioning

confidence: 99%

Constraining the progenitor of the Type Ia Supernova SN 2012cg

Liu

Stancliffe

2016

Mon. Not. R. Astron. Soc.

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“…The function DTDIa(τ ) physically represents the (unnormalized) number of Type Ia SNe, which are expected to explode at the time t = τ from a burst of star formation at t = 0, per unit mass of the simple stellar population (SSP) and per unit time of duration of the burst. Observational evidence suggests an integrated number of Type Ia SNe, which is ∼ 1 SN per M = 10 3 M of stellar mass formed, with a scatter of about 2-10 around this value (Bell et al 2003;Maoz et al 2014). In this work, the normalization constants of the examined DTDs are chosen so as to fulfill this criterion; in particular, the constant CIa is computed by requiring the following constraint:…”

Section: The Delay Time Distribution Of Type Ia Supernovaementioning

confidence: 99%

A simple and general method for solving detailed chemical evolution with delayed production of iron and other chemical elements

Vincenzo

Matteuccí²,

Spitoni³

2016

Mon. Not. R. Astron. Soc.

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We present a theoretical method for solving the chemical evolution of galaxies, by assuming an instantaneous recycling approximation for chemical elements restored by massive stars and the Delay Time Distribution formalism for the delayed chemical enrichment by Type Ia Supernovae. The galaxy gas mass assembly history, together with the assumed stellar yields and initial mass function, represent the starting point of this method. We derive a simple and general equation which closely relates the Laplace transforms of the galaxy gas accretion history and star formation history, which can be used to simplify the problem of retrieving these quantities in the galaxy evolution models assuming a linear Schmidt-Kennicutt law. We find that -once the galaxy star formation history has been reconstructed from our assumptions -the differential equation for the evolution of the chemical element X can be suitably solved with classical methods. We apply our model to reproduce the [O/Fe] and [Si/Fe] vs. [Fe/H] chemical abundance patterns as observed at the solar neighborhood, by assuming a decaying exponential infall rate of gas and different delay time distributions for Type Ia Supernovae; we also explore the effect of assuming a nonlinear Schmidt-Kennicutt law, with the index of the power law being k = 1.4. Although approximate, we conclude that our model with the single degenerate scenario for Type Ia Supernovae provides the best agreement with the observed set of data. Our method can be used by other complementary galaxy stellar population synthesis models to predict also the chemical evolution of galaxies.

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“…While there is a wide consensus that SNe Ia are the result of a thermonuclear explosion of a carbon-oxygen white dwarf, it is still unclear how the white dwarf is detonated and consumed (for a recent review, see Maoz et al 2014). Röpke et al (2012) have used the leptonic energy injection mechanisms due to the decays of 57 Co and 55 Fe described above to provide a testable prediction for two popular SN Ia explosion scenarios: the "delayed-detonation" and "violent merger" models (Khokhlov 1991; Pakmor et al 2011Pakmor et al , 2012.…”

Section: Introductionmentioning

confidence: 99%

LATE-TIME PHOTOMETRY OF TYPE IA SUPERNOVA SN 2012cg REVEALS THE RADIOACTIVE DECAY OF ⁵⁷Co

Graur

Zurek

Shara

et al. 2016

ApJ

103

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Seitenzahl et al. have predicted that roughly three years after its explosion, the light we receive from a Type Ia supernova (SN Ia) will come mostly from reprocessing of electrons and X-rays emitted by the radioactive decay chain 57 Co→ 57 Fe, instead of positrons from the decay chain 56 Co→ 56 Fe that dominates the SN light at earlier times. Using the Hubble Space Telescope, we followed the light curve of the SN Ia SN 2012cg out to 1055 days after maximum light. Our measurements are consistent with the light curves predicted by the contribution of energy from the reprocessing of electrons and X-rays emitted by the decay of 57 Co, offering evidence that 57 Co is produced in SN Ia explosions. However, the data are also consistent with a light echo ∼14 mag fainter than SN 2012cg at peak. Assuming no light-echo contamination, the mass ratio of 57 Ni and 56 Ni produced by the explosion, a strong constraint on any SN Ia explosion models, is 0.043 0.011 0.012 -+ , roughly twice Solar. In the context of current explosion models, this value favors a progenitor white dwarf with a mass near the Chandrasekhar limit.

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Observational Clues to the Progenitors of Type Ia Supernovae

Cited by 939 publications

References 531 publications

Constraining the progenitor of the Type Ia Supernova SN 2012cg

Constraining the progenitor of the Type Ia Supernova SN 2012cg

A simple and general method for solving detailed chemical evolution with delayed production of iron and other chemical elements

LATE-TIME PHOTOMETRY OF TYPE IA SUPERNOVA SN 2012cg REVEALS THE RADIOACTIVE DECAY OF ⁵⁷Co

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Observational Clues to the Progenitors of Type Ia Supernovae

Cited by 939 publications

References 531 publications

Constraining the progenitor of the Type Ia Supernova SN 2012cg

Constraining the progenitor of the Type Ia Supernova SN 2012cg

A simple and general method for solving detailed chemical evolution with delayed production of iron and other chemical elements

LATE-TIME PHOTOMETRY OF TYPE IA SUPERNOVA SN 2012cg REVEALS THE RADIOACTIVE DECAY OF 57Co

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LATE-TIME PHOTOMETRY OF TYPE IA SUPERNOVA SN 2012cg REVEALS THE RADIOACTIVE DECAY OF ⁵⁷Co