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Transcript
The Chemical Signatures of
First-Generation Stars
{
Timothy C. Beers
University of Notre Dame
SDSS
Expected Signatures

First-generation objects of high mass presumably formed from
metal-free gas




Next-generation objects formed from the gas polluted by firstgeneration objects



Lived short lives (Myrs not Gyrs)
Exploded
Distributed (pre or post explosion) their nucleosynthetic products
A wider range of masses allowed, perhaps including stars with mainsequence lifetimes > a Hubble time
Further star formation (Pop II) contributed additional material, and
diluted the signatures of first/next-generation stars
We should look for a characteristic set of abundance signatures
ONLY found among the lowest metallicity stars
Expected Signatures

Among the lowest metallicity stars, there are two basic “families”




Stars with enhanced abundances of carbon (CEMP stars), and other light
elements (including the lowest [Fe/H] star yet discovered), and lack of
over-abundances of neutron-capture elements (CEMP-no stars)
Associated with production by “faint SNe” – progenitors with mass on the
order of 10-100 Mo undergoing mixing and fallback, or rapidly rotating
mega metal-poor (MMP; [Fe/H] < -6.0) stars, both of which eject large
amount of CNO, but little heavy metals. Low-mass stars formed with the
help of C, O cooling
Stars with “normal” carbon and light-element abundances, apparently
formed with cooling other than C, O – perhaps by silicates ?
Possibly associated with production by first-generation objects of very
high mass (100-300 Mo), which produce large amounts of heavy metals,
but little carbon
Frequencies of CEMP Stars Based
on Stellar Populations

Carbon-Enhanced Metal-Poor (CEMP) stars have been
recognized to be an important stellar component of the halo
system

CEMP star frequencies are:
 20% for [Fe/H] < -2.5
 30% for [Fe/H] < -3.0 EMP
 40% for [Fe/H] < -3.5
 75% for [Fe/H] < -4.0 UMP
 100% for [Fe/H] < -5.0 HMP

But Why ? – Atmospheric/Progenitor or Population Driven ?

Carollo et al. (2012,2014) suggest the latter
Cumulative Frequencies of CEMP Stars from
SDSS/SEGUE
Cumulative Frequencies of CEMP-no (ONLY) Stars
from SDSS/SEGUE, with Luminosity Corrections
Placco et al. (2014)
Exploration of Nature’s Laboratory
for Neutron-Capture Processes
Beers & Christlieb ARAA (2005)
The UMP/HMP Stars are (Almost) ALL CEMP-no Stars
 Aoki et al. (2007)
demonstrated that
the CEMP-no stars
occur preferentially
at lower [Fe/H] than
the CEMP-s stars
 About 80% of CEMP
stars are CEMP-s
or CEMP-r/s, 20% are
CEMP-no
 Global abundance
patterns of CEMP-no
stars incompatible
with AGB models
at low [Fe/H]
CEMP-no Stars are Associated with UNIQUE LightElement Abundance Patterns (Aoki et al. 2002)
CS 29498-043: [Fe/H] = -3.8; [C/Fe] = +1.9
Harbingers of Things to Come!
Last but Definitely NOT Least… (Christlieb et
al. 2002; Frebel et al. 2005)
HE 0107-5240 [Fe/H] = -5.3 [C/Fe] = +3.9
It is the SAME pattern among the light elements !
BD+44:493 – A 9th Magnitude
Messenger from the Early Universe

Ito et al. (2009) report on discovery that BD+44 is an
[Fe/H] = -3.8, CEMP-no star; more detailed observations
by Ito et al. (2013)

Light-element abundance patterns similar to those for
other CEMP-no stars

Previous RV monitoring by Carney et al. indicate no
variation at levels > 0.5 km/s over past 25 years

The same is true for other CEMP-no stars with available
RV monitoring (Hansen et al. 2013, and in prep;
Norris et al. 2013)
Something You Don’t Often See
An Object of COSMOLOGICAL Significance with Diffraction Spikes
Abundance Pattern Compared to
25 Mo Mixing/Fallback Model
Ito et al. (2013) : Note the low N, compared with some other
CEMP-no stars with enhanced N
HST/STIS Observations of Be and B in BD+44 at
the Lowest Levels Measured for Metal-Poor Stars
Dust in the Early Universe (Watson et al. 2015 – Nature)
This image, taken by the Hubble Space Telescope, shows a part of the galaxy cluster,
Abell 1689, whose gravitational field amplifies the distant galaxy behind it. The distant
dust-filled galaxy in zoom in the box, at a redshift z ~ 7.5
The Carbon-Low and Carbon-High Bands
 Recent observational evidence strongly suggests that CEMP-no stars are
associated with “low” absolute C abundances (A(C) ~ 6.5), while CEMP-s
stars are associated with “high” absolute C abundances (A(C) ~ 8.25)
 This recognition may provide a more fundamental definition of CEMP-no
stars, rather than simply [Ba/Fe] < 0 (which may take on higher values)
Spite et al. (2013)
The Carbon-Low and Carbon-High Bands
 Similar
results seen in the HERES sample (Barklem et al. 2005), as
summarized by Placco (private communication)
Placco et al. based on HERES Sample
The Carbon-Low and Carbon-High Bands
 Similarly
from Hansen et al. (2015)
Note that A(C) has been
corrected for luminosity
effects following Placco et al.
(2014)
CEMP-no ONLY 
Including stars from
Yong et al. (2013) 
The Carbon-Low and Carbon-High Bands
 Similarly
from Bonifacio et al. (2015)
The Distribution of A(C) for the Carbon-Low and
Carbon-High Bands (Bonifacio et al. 2015)
Bottom Line
 CEMP
stars in the Galaxy likely have had multiple sources of
carbon production
CEMP-s in AGB stars
CEMP-no in massive (50-100 Mo) rapidly rotating MMP stars
CEMP-no in intermediate high-mass (25-50 Mo) “faint” SNe
 CEMP-no stars occur preferentially at the lowest metallicities,
including all but 2 of the 20 stars known with [Fe/H] < -4.0
 CEMP stars are found in substantial numbers in the ultra-faint
SDSS dwarf galaxies, some of which have low n-capture abundances
 High-z DLA systems exhibit similar abundance patterns as
CEMP-no stars
 Discovery of “dusty galaxies” at high-z
We have observed (!) the nucleosynthesis products
of first generation stars (Pop III)
The Path Forward

Expansion of numbers of identified CEMP stars, in particular with
[Fe/H] < -2.5, which include both CEMP-s and CEMP-no stars, both from
HK/HES and the ~ 5-10 million medium-res spectra coming from LAMOST

We need bright stars to obtain Be, B with HST/STIS and CUBES (Be)

High-resolution follow-up spectroscopy of a core sample of 100-200 CEMP
stars, in order to assign classifications based on heavy elements, and to
determine CNO, alpha elements, and other light-element abundances

Radial velocity monitoring of CEMP stars, in order to determine binary
nature, as well as characterize correlations between chemical patterns and
nature of the detected binary

Full numerical GCE models, taking into account the effects of local mixing,
in order to match frequencies of CEMP stars and C-normal stars, as well
as Li-depletion phenomenon for very metal-poor stars
RV Monitoring – Hansen et al. (in prep): rI / rII
RV Monitoring – Hansen et al. (in prep): CEMP-s
and CEMP-r/s
RV Monitoring – Hansen et al. (in prep): CEMP-no
New Surveys for JINA-CEE
• Medium-res follow-up of HES VMP and carbonselected stars using “bad weather” time on Gemini
8m telescopes – some 2000 stars
• Medium-resolution follow-up of MP candidates from
Australian SkyMapper Southern Sky Survey on the
AAT 3.9m telescope – some 70,000 stars
• High-resolution follow-up with various 8m telescopes
(Magellan) ongoing for both samples of stars
JINA-CEE
NSF Physics Frontiers Center
New Surveys for JINA-CEE
• Medium-resolution follow-up of [Fe/H] < -2.0 stars
from RAVE, with various 4m and 8m telescopes, in
order to identify the important subset of BRIGHT
CEMP stars among them – some 1000 stars (some
with B ~ 10)
• Medium-resolution follow-up of disk and halo stars
of the MW, with the LAMOST 4m telescope in China
– some 6 Million stars
• High-resolution follow-up with various 8m telescopes ongoing
for both samples of stars
JINA-CEE
NSF Physics Frontiers Center
Medium-Res Spectra of RAVE Stars with [Fe/H] < -2.0
JINA-CEE
NSF Physics Frontiers Center
[C/Fe] vs. [Fe/H] (Medium-Res Results)
JINA-CEE
NSF Physics Frontiers Center