SN2014J gamma rays from the<sup>56</sup>Ni decay chain

Diehl, R.; Siegert, Thomas; Hillebrandt, W.; Krause, Martin; Greiner, J.; Maeda, Keiichi; Röpke, F. K.; Sim, Stuart; Wang, Wei; Zhang, Xiaoling

doi:10.1051/0004-6361/201424991

Cited by 83 publications

(118 citation statements)

References 24 publications

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“…Churazov et al (2014) derive 56 Ni = 0.62 ± 0.13 M . Diehl et al (2015) find a slightly lower mass of M56 Ni = 0.56 ± 0.10 M .…”

Section: Test With Well-observed Sne Iamentioning

confidence: 76%

“…Since t 2 is independent of reddening, we can use the derived correlation to determine the peak luminosity and estimate the 56 Ni mass for heavily reddened SNe Ia. We tested this relation on SN 2014J, which has a direct γ-ray detection from the 56 Ni → 56 Co decay chain (Churazov et al 2014;Diehl et al 2015). Using the best fit relation for the reddening-free sample, we obtain M56 Ni = 0.64 ± 0.15 M for a t 2 = 31.99 ± 1.15 days and a rise time of 19 days.…”

Section: Test With Well-observed Sne Iamentioning

confidence: 99%

See 1 more Smart Citation

A reddening-free method to estimate the⁵⁶Ni mass of Type Ia supernovae

Dhawan

Leibundgut

Spyromilio

et al. 2016

A&A

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The increase in the number of Type Ia supernovae (SNe Ia) has demonstrated that the population shows greater diversity than has been assumed in the past. The reasons (e.g. parent population, explosion mechanism) for this diversity remain largely unknown. We investigated a sample of SNe Ia near-infrared light curves and correlated the phase of the second maximum with the bolometric peak luminosity. The peak bolometric luminosity is related to the time of the second maximum (relative to the B light curve maximum) as follows: L max (10 43 erg s −1 ) = (0.039 ± 0.004) × t 2 (J)(days) + (0.013 ± 0.106). 56 Ni masses can be derived from the peak luminosity based on Arnett's rule, which states that the luminosity at maximum is equal to the instantaneous energy generated by the nickel decay. We checked this assumption against recent radiative-transfer calculations of Chandrasekhar-mass delayed detonation models and find this assumption is valid to within 10% in recent radiative-transfer calculations of Chandrasekhar-mass delayed detonation models. The L max vs. t 2 relation is applied to a sample of 40 additional SNe Ia with significant reddening (E(B − V) > 0.1 mag), and a reddening-free bolometric luminosity function of SNe Ia is established. The method is tested with the 56 Ni mass measurement from the direct observation of γ-rays in the heavily absorbed SN 2014J and found to be fully consistent. Super-Chandrasekhar-mass explosions, in particular SN 2007if, do not follow the relations between peak luminosity and second IR maximum. This may point to an additional energy source contributing at maximum light. The luminosity function of SNe Ia is constructed and is shown to be asymmetric with a tail of low-luminosity objects and a rather sharp high-luminosity cutoff, although it might be influenced by selection effects.

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“…Churazov et al (2014) derive 56 Ni = 0.62 ± 0.13 M . Diehl et al (2015) find a slightly lower mass of M56 Ni = 0.56 ± 0.10 M .…”

Section: Test With Well-observed Sne Iamentioning

confidence: 76%

Section: Test With Well-observed Sne Iamentioning

confidence: 99%

A reddening-free method to estimate the⁵⁶Ni mass of Type Ia supernovae

Dhawan

Leibundgut

Spyromilio

et al. 2016

A&A

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“…INTEGRAL could detect the long awaited gamma-ray signatures of the thermonuclear runaway, through the early emission from the decay of 56 Ni (mean lifetime τ 8.8 days) about 20 days after the explosion, and the main gamma-ray lines at 847, 1238, and 511 keV from the decay of 56 Co (τ 111 days). These data suggested either a surface explosion or some unusual morphology of the runaway [44,45,53,54,76], either case in stark contrast to the conventional Chandrasekhar model. Clearly, the glimpse offered by SN2014J observations underlines the importance of gamma-ray line diagnostics in these systems and emphasize that more and better observations hold the key to a deeper understanding of how the thermonuclear explosion of a white dwarf star unfolds.…”

Section: Antimatter and Wimp Dark Mattermentioning

confidence: 83%

“…4 in Ref. [54], red data points) are compared to a family of candidate models [137]. A simulation of the response to a time evolution such as in the W7 model [99] shows that the sensitivity improvement by e-ASTROGAM (blue points) will lead to breakthrough science.…”

Section: Antimatter and Wimp Dark Mattermentioning

confidence: 99%

The e-ASTROGAM mission

et al. 2017

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e-ASTROGAM ('enhanced ASTROGAM') is a breakthrough Observatory space mission, with a detector composed by a Silicon tracker, a calorimeter, and an anticoincidence system, dedicated to the study of the non-thermal Universe in the photon energy range from 0.3 MeV to 3 GeV -the lower energy limit can be pushed to energies as low as 150 keV, albeit with rapidly degrading angular resolution, for the tracker, and to 30 keV for calorimetric detection. The mission is based on an advanced space-proven detector technology, with unprecedented sensitivity, angular and energy resolution, combined with polarimetric capability. Thanks to its performance in the MeV-GeV domain, substantially improving its predecessors, e-ASTROGAM will open a new window on the non-thermal Universe, making pioneering observations of the most powerful Galactic and extragalactic sources, elucidating the nature of their relativistic outflows and their effects on the surroundings. With a line sensitivity in the MeV energy range one to two orders of magnitude better than previous generation instruments, e-ASTROGAM will determine the origin of key isotopes fundamental for the understanding of supernova explosion and the chemical evolution of our Galaxy. The mission will provide unique data of significant interest to a broad astronomical community, complementary to powerful observatories such as LIGO-Virgo-GEO600-KAGRA, SKA, ALMA, E-ELT, TMT, LSST, JWST, Athena, CTA, IceCube, KM3NeT, and the promise of eLISA.

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“…The general results from INTEGRAL, which detected the 847 and 1238 keV γ -ray lines of radioactive 56 Co (Churazov et al 2014(Churazov et al , 2015Diehl et al 2014Diehl et al , 2015, showed that the general nickel distribution was stratified with a total 56 Ni mass of ∼0.5 M . Due to the low signal to noise, there is some ambiguity about just how to interpret the results, that is, whether the γ -rays favour symmetric nickel distributions (Churazov et al 2014(Churazov et al , 2015 or whether the lines are significantly Doppler-broadened asymmetric ones (Diehl et al 2014(Diehl et al , 2015. We are not terribly sensitive to small asymmetries, and therefore we cannot distinguish between these different interpretations.…”

Section: O M Pa R I S O N W I T H Smentioning

confidence: 99%

Supernova 2014J at M82 – II. Direct analysis of a middle-class Type Ia supernova

Vallely

Moreno-Raya

Baron

et al. 2016

Mon. Not. R. Astron. Soc.

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We analyze a time series of optical spectra of SN 2014J from almost two weeks prior to maximum to nearly four months after maximum. We perform our analysis using the SYNOW code, which is well suited to track the distribution of the ions with velocity in the ejecta. We show that almost all of the spectral features during the entire epoch can be identified with permitted transitions of the common ions found in normal SNe Ia in agreement with previous studies.We show that 2014J is a relatively normal SN Ia. At early times the spectral features are dominated by Si II, S II, Mg II, and Ca II. These ions persist to maximum light with the appearance of Na I and Mg I. At later times iron-group elements also appear, as expected in the stratified abundance model of the formation of normal type Ia SNe.We do not find significant spectroscopic evidence for oxygen, until 100 days after maximum light. The +100 day identification of oxygen is tentative, and would imply significant mixing of unburned or only slight processed elements down to a velocity of 6,000 km s −1 . Our results are in relatively good agreement with other analyses in the IR. We briefly compare SN 2011fe to SN 2014J and conclude that the differences could be due to different central densities at ignition or differences in the C/O ratio of the progenitors.

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SN2014J gamma rays from the⁵⁶Ni decay chain

Cited by 83 publications

References 24 publications

A reddening-free method to estimate the⁵⁶Ni mass of Type Ia supernovae

A reddening-free method to estimate the⁵⁶Ni mass of Type Ia supernovae

The e-ASTROGAM mission

Supernova 2014J at M82 – II. Direct analysis of a middle-class Type Ia supernova

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SN2014J gamma rays from the56Ni decay chain

Cited by 83 publications

References 24 publications

A reddening-free method to estimate the56Ni mass of Type Ia supernovae

A reddening-free method to estimate the56Ni mass of Type Ia supernovae

The e-ASTROGAM mission

Supernova 2014J at M82 – II. Direct analysis of a middle-class Type Ia supernova

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Product

Resources

About

SN2014J gamma rays from the⁵⁶Ni decay chain

A reddening-free method to estimate the⁵⁶Ni mass of Type Ia supernovae

A reddening-free method to estimate the⁵⁶Ni mass of Type Ia supernovae