Hydrodynamical Evolution of Merging Carbon–oxygen White Dwarfs: Their Pre-Supernova Structure and Observational Counterparts

Tanikawa, Ataru; Nakasato, Nobukazu; Sato, Yoshihito; Nomoto, Ken’ichi; Maeda, Keiichi; Hachisu, Izumi

doi:10.1088/0004-637x/807/1/40

Cited by 68 publications

(70 citation statements)

References 83 publications

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“…By contrast, we find that the highest temperature in the remnant phase is barely affected by the initial condition (see Figure 7). A similar discussion appears in Tanikawa et al (2015).…”

Section: Comparison With Previous Studiessupporting

confidence: 72%

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A SYSTEMATIC STUDY OF CARBON–OXYGEN WHITE DWARF MERGERS: MASS COMBINATIONS FOR TYPE Ia SUPERNOVAE

Sato

Nakasato

Tanikawa

et al. 2015

ApJ

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109

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Mergers of two carbon-oxygen (CO) white dwarfs (WDs) have been considered to be progenitors of Type Ia supernovae (SNe Ia). Based on smoothed particle hydrodynamics (SPH) simulations, previous studies have claimed that mergers of CO WDs lead to SN Ia explosions either in the dynamical merger phase or the stationary rotating merger remnant phase. However, the mass range of CO WDs that lead to SNe Ia has notyet been clearly identified. In the present work, we perform systematic SPH merger simulations for the WD masses ranging from M 0.5  to M 1.1  with higher resolutions than the previous systematic surveys and examine whether or not carbon burning occurs dynamically or quiescently in each phase. We further study the possibility of SNe Ia explosions and estimate the mass range of CO WDs that lead to SNe Ia. We found that when both WDs are massive, i.e., in the mass range of ⩽ ⩽ and the total mass exceeds M 1.38  , they can finally explode in the stationary rotating merger remnant phase. We estimate the contribution of CO WD mergers to the entire SN Ia rate in our galaxy to be of 9%  . Thus, it might be difficult to explain all galactic SNe Ia with CO WD mergers.

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“…By contrast, we find that the highest temperature in the remnant phase is barely affected by the initial condition (see Figure 7). A similar discussion appears in Tanikawa et al (2015).…”

Section: Comparison With Previous Studiessupporting

confidence: 72%

“…The details of the numerical method have already been described in Nakasato et al (2012) and Tanikawa et al (2015).…”

Section: Methodsmentioning

confidence: 99%

A SYSTEMATIC STUDY OF CARBON–OXYGEN WHITE DWARF MERGERS: MASS COMBINATIONS FOR TYPE Ia SUPERNOVAE

Sato

Nakasato

Tanikawa

et al. 2015

ApJ

Self Cite

109

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“…5, to account for the earlytime excess flux in SN 2012cg, a progenitor radius of ≈ 2.0 R ⊙ is required. This is much larger than the typical progenitor radius which is an isolated WD, in both the SD and DD scenarios, although some recent hydrodynamical studies suggested that the envelope of the exploding WD could spread out to a radius of ≈ 0.1 R ⊙ in the violent merger model (Tanikawa et al 2015). Therefore, one can conclude that the diffusion of radiation from the shock-heated ejecta in the shock breakout model of RLW12 is unlikely to be the contributor of the early excess luminosity seen in SN 2012cg.…”

Section: Cooling Of the Shock-heated Wdmentioning

confidence: 88%

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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“…On the curve, the 12 C + 12 C reaction timescale is equal to the local dynamical timescale. Both the timescale are defined in the same way as Tanikawa et al (2015). If a particle is on the upper side from the curve, the particle experiences the explosive nuclear burning.…”

Section: Discussionmentioning

confidence: 99%

Does Explosive Nuclear Burning Occur in Tidal Disruption Events of White Dwarfs by Intermediate-mass Black Holes?

Tanikawa

Sato

Nomoto

et al. 2017

ApJ

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We investigate nucleosynthesis in tidal disruption events (TDEs) of white dwarfs (WDs) by intermediate mass black holes (IMBHs). We consider various types of WDs with different masses and compositions by means of 3 dimensional (3D) smoothed particle hydrodynamics (SPH) simulations. We model these WDs with different numbers of SPH particles, N , from a few 10 4 to a few 10 7 , in order to check mass resolution convergence, where SPH simulations with N > 10 7 (or a space resolution of several 10 6 cm) have unprecedentedly high resolution in this kind of simulations. We find that nuclear reactions become less active with increasing N , and that these nuclear reactions are excited by spurious heating due to low resolution. Moreover, we find no shock wave generation. In order to investigate the reason for the absence of a shock wave, we additionally perform 1 dimensional (1D) SPH and mesh-based simulations with a space resolution ranging from 10 4 to 10 7 cm, using characteristic flow structure extracted from the 3D SPH simulations. We find shock waves in these 1D high-resolution simulations. One of these shock waves triggers a detonation wave. However, we have to be careful of the fact that, if the shock wave emerged at a bit outer region, it could not trigger the detonation wave due to low density. Note that the 1D initial conditions lack accuracy to precisely determine where a shock wave emerges. We need to perform 3D simulations with 10 6 cm space resolution in order to conclude that WD TDEs become optical transients powered by radioactive nuclei.

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Hydrodynamical Evolution of Merging Carbon–oxygen White Dwarfs: Their Pre-Supernova Structure and Observational Counterparts

Cited by 68 publications

References 83 publications

A SYSTEMATIC STUDY OF CARBON–OXYGEN WHITE DWARF MERGERS: MASS COMBINATIONS FOR TYPE Ia SUPERNOVAE

A SYSTEMATIC STUDY OF CARBON–OXYGEN WHITE DWARF MERGERS: MASS COMBINATIONS FOR TYPE Ia SUPERNOVAE

Constraining the progenitor of the Type Ia Supernova SN 2012cg

Does Explosive Nuclear Burning Occur in Tidal Disruption Events of White Dwarfs by Intermediate-mass Black Holes?

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