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

Graur, Or; Zurek, David; Shara, Michael M.; Riess, Adam G.; Seitenzahl, Ivo R.; Rest, A.

doi:10.3847/0004-637x/819/1/31

Cited by 71 publications

(115 citation statements)

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“…For a comprehensive discussion, the results from other studies such as the deep radio observations of Chomiuk et al (2015), the detection of blueshifted Na i D (Maguire et al 2013) and the late-time photometry observations (Graur et al 2016) for SN 2012cg are also included in this table.…”

Section: Discussionmentioning

confidence: 99%

“…To place strict constraints on the properties of CSM and the observable signatures of the SN shock interacting with the CSM, detailed numerical hydrodynamical simulations for the interaction between the blast wave of the SN and CSM/ISM are required, coupled with different explosion models and the detailed pre-SN massloss history, i.e., different configurations of outflow material around progenitor systems. In addition, (Graur et al 2016) suggested that the decay of 57 Co and 55 Fe produced from current modelling for the two CO WDs merger model have difficulties in explaining the slow-down decline light curve of SN 2012cg at late times. How- ever, they also pointed out that a similar behavior of the late-time light curve of SN 2012cg can be explained by a light echo, which requires future follow-up observations for further confirmation.…”

Section: Discussionmentioning

confidence: 99%

“…By analyzing pre-explosion archival WFPC2 images of NGC 4424 in F606W and F814W band from the Hubble Space Telescope (HST), Graur et al (2016) found no source within a 2" radius of the location of SN 2012cg down to limits of M V ≈ −6.0 and M V ≈ −5.4 mags, and thus excluded most supergiants as potential binary companions of the progenitor of SN 2012cg. By taking into account Galactic and host-galaxy extinctions for these filters, they place an upper-limit on the luminosity of pre-explosion progenitor of SN 2012cg of < 840 L ⊙ .…”

Section: The Pre-explosion Progenitormentioning

confidence: 99%

“…If the spin-down timescale is longer than about 10 6 yrs, the CSM around the progenitor system could become diffuse and reach a density similar to that of the ISM, leading to the lack of radio and X-ray emission which are absent in SN 2012cg (Chomiuk et al 2015). Also, the MS or RG companion star might shrink rapidly before the SN Ia explosion occurs by exhausting most of its H-rich envelope during a long spin-down ( 10 8 yrs) phase, explaining the non-detection of a pre-explosion companion star (Graur et al 2016) and the absence of swept-up H in the late-time spectra of SN 2012cg (Maguire et al 2016). 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.…”

Section: Spin-up/spin-down Modelmentioning

confidence: 99%

“…Here, only Heburning donor stars are considered in the Sub-Ch-mass scenario. The gray dashed line gives an upper-limit on the progenitor luminosity of SN 2012cg from HST pre-explosion observations (Graur et al 2016). …”

Section: Sn 2012cgmentioning

confidence: 99%

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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: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: The Pre-explosion Progenitormentioning

confidence: 99%

Section: Spin-up/spin-down Modelmentioning

confidence: 99%

Section: Sn 2012cgmentioning

confidence: 99%

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Constraining the progenitor of the Type Ia Supernova SN 2012cg

Liu

Stancliffe

2016

Mon. Not. R. Astron. Soc.

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Nucleosynthesis in Thermonuclear Supernovae

Seitenzahl¹,

Townsley²

2017

Handbook of Supernovae

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The explosion energy of thermonuclear (Type Ia) supernovae is derived from the difference in nuclear binding energy liberated in the explosive fusion of light "fuel" nuclei, predominantly carbon and oxygen, into more tightly bound nuclear "ash" dominated by iron and silicon group elements. The very same explosive thermonuclear fusion event is also one of the major processes contributing to the nucleosynthesis of the heavy elements, in particular the iron-group elements. For example, most of the iron and manganese in the Sun and its planetary system was produced in thermonuclear supernovae. Here, we review the physics of explosive thermonuclear burning in carbon-oxygen white dwarf material and the methodologies utilized in calculating predicted nucleosynthesis from hydrodynamic explosion models. While the dominant explosion scenario remains unclear, many aspects of the nuclear combustion and nucleosynthesis are common to all models and must occur in some form in order to produce the observed yields. We summarize the predicted nucleosynthetic yields for existing explosions models, placing particular emphasis on characteristic differences in the nucleosynthetic signatures of the different suggested scenarios leading to Type Ia supernovae. Following this, we discuss how these signatures compare with observations of several individual supernovae, remnants, and the composition of material in our Galaxy and galaxy clusters.

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