1. ALMA observations of Molecules in Supernova 1987A
Line survey
Chemistry, mixing and isotopologues
High angular resolution images
Clumps and torus
Evolution of ring dust (c.f. ejecta dust – Phil Cigan’s talk)
Mikako Matsuura (Cardiff University)
P. Cigan, F. Abellan, R. Indebetouw,
J. Kamenetzky, D. McCray, J. Larsson,
C. Fransson, M. J. Barlow, V. Bujarrabal, R. Chevalier,
E. Dwek, H. Gomez, S. Woosley, et al.

2. ALMA (Atacama Large millimetre and sub-millimetre array)
High sensitivities
(RMS~33 mJy in less than hour at 200 GHz)
High angular resolutions (0.05 arcsec – 0.3 arcsec)
SN 1987A
Ejecta
~0.9 arcsec
Ring

3. ALMA detections of molecules in 2012
Cold ( K) ‘molecular gas’ in the ejecta after 25 years
12CO J=2-1
12CO J=1-0
28SiO
29SiO CO
FWHM~
2300 km s-1
(Kamenetzky et al. 2013)

4. Contents Molecules Evolution of ring dust Line survey
What kind of molecules have formed in the ejecta?
What is the chemical processes?
Chemistry, mixing and isotopologues
High angular resolution images
Using molecular lines to prove dynamics of the ejecta
Clumps and torus
Evolution of ring dust
Does the interaction of blast winds destroy dust in the ring?

5. ALMA molecular survey in 2014/2015
SiO CO
SiO
CO+SiO
Synchrotron
Matsuura et al. (2017)

6. Estimating temperature and density by modelling molecular lines
SiO
T=20–170 K
Mass: 1x10-3 – 2x10-5 M
n(Hcorr): 106 cm-3
Only small fraction of Si (0.2 M) is in SiO (most Si in silicate dust?) CO
T=20–50 K
Mass: 0.5–9x10-3 M
n(Hcorr): 105–106 cm-3
Cold & Relatively high density gas

7. First detections of SO and HCO+ from SNe
29SiO SO +
29SiO
HCO+ +
SO2 SO
HCO+?
Matsuura et al. (2017)

8. How to form HCO+? Reactions
H2++H2 -> H3++H & H3+ + CO -> H2 + HCO+
C+H2 -> CH + H & CH + O -> HCO++ e-

9. Explosive nucleosynthesis without mixing
Elemental mass fraction
No mixing
= no HCO+
Interior Mass (M)
Explosive nucleosynthesis for SN 1987A　(Woosley in preparation)

10. Explosive nucleosynthesis with mixing between zones
HCO+ formation H C O
Elemental mass fraction
Explosive nucleosynthesis for SN 1987A　(Woosley in preparation)
Interior Mass (M)

11. Isotopologues
28SiO
At millimeter and submillimeter wavelengths, isotope shifts are larger than the SN expansion velocity (~2000 km s-1)
29SiO
30SiO

12. Constraints on SN nucleosynthesis: isotope ratio
28SiO CO
28SiO
29SiO+SO
29SiO+SO
ALMA
28SiO / 29SiO >13
Matsuura et al. (2017)

13. Si isotope ratios
SN 1987A could be slightly offset from presolar grains sequence
Low metallicity effects
Neutron-rich isotopes are poorer at lower metallicity
Measurements in presolar grains
28Si/30Si
44Ca decay fro 44 Ti
28Si/29Si
Matsuura et al. (2017)

14. Si isotope ratios
Models slightly under-predict 29Si and 30Si slightly, with respect to 28Si
SN 1987A (~30% of solar Z)
(Woosley)
28Si/30Si
Solar metallicity models
Sukhbold et al. (2016)
28Si/29Si
Matsuura et al. (2017)

15. Clumps – footprints of Rayleigh-Taylor instabilities at the time of explosion
t=350 sec
t=9000 sec
3D simulation of instability at the time of SN explosion
(Hammer et al. 2010; Wongwathanarat et al. 2015)
Carbon/Oxygen/Nickel

16. Contents Molecules Evolution of ring dust Line survey
What kind of molecules have formed in the ejecta?
What is the chemical processes?
Chemistry, mixing and isotopologues
High angular resolution images
Using molecular lines to prove dynamics of the ejecta
Clumps and torus
Evolution of ring dust
Does the interaction of blast winds destroy dust in the ring?

17. Blast wave has passed the circumstellar ring
Feb 2008
June 2014
Material outside of the ring is illuminated by shocks
Destruction of ring (Fransson et al. 2015)

18. Warm ring dust in SN 1987A Dust Gemini mid-IR resolved image (green)
Warm dust in the ring
Red-supergiant origin
(red)
(green)
Bouchet et al. (2006)
Warm ring dust
Cold ejecta dust
In 2000s, new telescopes have been built, and dust is detected with mid-infrared observations with Gemini and Spitzer Space Telescope. There is a famous ring bright in optical, and mid infrared image, which traces the thermal emission of dust, is found in red surrounding the ring. This ring itself is believed to be formed before the supernova explosion, when the star was red-supergiant phase. So that mid-infrared emission traces dust colliding into the ring, and heated by shocks. This is the spectral energy distribution of supernova 1987A before Herschel launch. Red and green shows the Spitzer observations. A model fit to this was like this blue line, and the flux drops sharply towards the longer wavelength. Herschel detection limits are here, so that the prediction was that supernova 1987A would not be detected with Herschel, which was launched in But fortunately and unexpectedly, we detected SN 1987A at far-infrared wavelength with Herschel.
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Blue dashed line shows the model spectrum to fit the Spitzer data.
This model can predict the dust emission in Herschel wavelength range,
And the expected flux was much lower than the Herschel detection limit.
Ejecta
Ring (red supergiant origin)

19. Summary Molecular line survey High resolution images Ring dust
Cold ( K) molecules in the ejecta, with high density gas (Ncoll~106 cm-3)
Finding of HCO+ & SO
Detection of HCO+ suggests mixing at the time of explosion
High resolution images
Clumps: tracing the instabilities at the time of explosions
Ring dust
Cold dust in post-shocked region?