supernova progenitors
I lead a group searching for the
stellar progenitors of nearby core-collapse supernovae
in archive
images from the Hubble Space Telescope, and large
ground-based
telescopes. Nearby supernovae are rare (about 13
discovered every year
within about 30Mpc), but many of the host galaxies have
been observed
by Hubble. The most massive and luminous stars are
visible, and we have
confidently identified the progenitors of SN2003gd,
SN2005cs, SN2008ax
and SN2008bk, amongst others. Our latest results are
presented in Smartt
et
al. MNRAS 2009, "The death of massive stars I.
Observational
constraints on the progenitors of type II-P
supernovae". The
detection of the progenitor of the type IIb SN2008ax is
in Crockett
et
al., MNRAS, 2008. My annual review article is
available here
: S.J.
Smartt
ARAA,
2009,
47,
63
"Progenitors
of
core collapse SNe" We have
now expanded this
project into the ESO
NTT
Large
Programme
"Supernovae
variety and nucleosynthesis" with
a broad range of european collaborators. We identify the
supernovae
with potential imaging from before explosion and use our
VLT time to
attempt to identify the progenitor stars. The NTT
programme provides
detailed monitoring, analysis and nucleosynthesis
estimates (e.g. mass
of Ni-56 ejected from the explosion). The
first
paper from this new collaboration is on the detection
of the progenitor
of SN2009kr by Morgan Fraser et al. (ApJL, 2010).
pan-starrs
We are members of the Pan-STARRS
1 Science Consortium and are leading Key Project 7
"Massive stars and
supernovae progenitors". The aim of this project is to
study the
supernovae that arise from massive progenitors and
understand the
physical mechanisms behind the explosions. See
our pages on Transient
Searches.
explosions of the most massive stars
Recent
discoveries suggest that
the most massive stars known (between 50-150 solar
masses) may die in
diverse explosions. The explosions may be gamma-ray
bursts,
ultra-bright type II SNe, and SNe with pre-explosion
outbursts.
The most luminous type Ic SN known (SN2007bi) may be a
pair-instability
explosion, or the core-collapse of a massive
carbon-oxygen core from a
star originally 50-100 solar masses. We study the SNe
and the exotic
explosions that may have come from the most massive
stars. See Valenti
et
al. 2009 Nature; Pastorello
et
al.
2007
Nature ; Young
et
al. A&A , 2010. More recently we have
shown that one of
the new class of "ultra-bright" type I supernovae
(SN2010gx) cannot be
powered by nickel-56 decay, but must have some other
mechanism that
provides the enormous luminosity (absolute magnitudes
up to M_B = -22).
We also showed that SN2010gx turns into a type Ic at
around 30 days
after maximum, suggesting a Wolf-Rayet type progenitor
star. See
Pastorello,
Smartt et al. 2010 ApJL.
the flames survey of massive stars
I
was PI of
successful ESO Large Programme, now completed :
"The VLT-FLAMES Survey of Massive Stars was an ESO
Large Programme to
understand rotational mixing and
stellar mass loss in different metallicity
environments, in order to
better constrain massive star evolution. We gathered
high-quality
spectra of over 800 stars in the Galaxy and in the
Magellanic Clouds. A
sample of this size is unprecedented, enabled by the
first
high-resolution, wide-field, multi-object spectrograph
on an 8-m
telescope. We developed spectral analysis techniques
that, in
combination with non-LTE, line-blanketed model
atmospheres, were used
to quantitatively characterise
every star.
The large sample, combined with the theoretical
developments, has
produced exciting new insights into the evolution of
the most massive
stars." : C.J.
Evans
et al., 2008, ESO Messenger March 2008, Vol. 131,
p25)
The spectral data archive,
papers, results, and
details are available here.
Chris Evans (UK ATC) is now leading this consortium, with a new ESO Large Programme approved : The VLT-FLAMES Tarantula Survey. Paul Dunstall and Philip Dufton from Queen's are analysing the B-type stars from this spectroscopic survey.