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Optical spectroscopy of Post-AGB stars

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Title: Optical spectroscopy of Post-AGB stars


1
Optical spectroscopy of Post-AGB stars
Pedro García-LarioEuropean Space Astronomy
Centre ESA,Villafranca del Castillo, Madrid
2
Why post-AGB stars?
  • Key objects in the study of the dramatic
    morphological and chemical changes which take
    place at the latest stages of stellar evolution
    in low- and intermediate-mass stars (0.8 8
    solar masses)
  • From the spectroscopic point of view ideal
    probes to test and study stellar nucleosynthesis
  • much easier to study than AGB stars
  • more complete information, on a wide number of
    atomic species
  • Is there any correlation between the physical
    properties derived from spectroscopic
    observations and the observed morphology?

3
Limitations
  • There is a limited number of galactic sources to
    study (326 in the most recent compilation)
  • The Torun catalogue of Galactic post-AGB and
    related objects (Szczerba et al. 2007)
  • Strong observational bias towards optically
    bright (classical) post-AGB stars
  • Lack of information from those strongly obscured
    in the optical (IRAS selected post-AGB stars)
    need to go to infrared wavelengths
  • Need to explore the whole parameter space of
    masses and metallicities

4
What can we learn?
  • Fundamental physical parameters of the stellar
    photosphere (log Teff, log g) from which masses
    can be inferred
  • Detailed chemical abundances for a large number
    of atomic species
  • Fe/H
  • CNO abundances
  • s-process elements
  • and their connection with known nuclear
    processes, such as
  • 3rd dredge up
  • hot bottom burning
  • neutron source dominating the production of
    s-elements
  • Evolutionary links with AGB and PNe based on the
    statistical analysis of their chemical properties

5
Recent progress
  • Atlas of low-resolution spectra of an infrared
    (IRAS) selected sample of 124 post-AGB stars and
    pre-PNe (Suárez et al. 2006)

6
Recent progress
  • A flatter distribution of
  • spectral types?

Classical post-AGB stars
Obscured post-AGB stars
  • Evidence for two different mass populations?

(from Suárez et al. 2006)
7
Recent progress
  • Compilation of stellar parameters and chemical
    abundances derived from high-resolution optical
    spectroscopy for 125 sources (Stasinska et al.
    2006)
  • Torun Catalogue of post-AGB stars, including SEDs
    covering from the optical to the infrared
    (Szczerba et al. 2006)

8
Recent progress
  • Compilation of stellar parameters and chemical
    abundances derived from high-resolution optical
    spectroscopy for 125 sources (Stasinska et al.
    2006)
  • Torun Catalogue of post-AGB stars, including SEDs
    covering from the optical to the infrared
    (Szczerba et al. 2006)

9
Recent progress
  • Low-resolution spectroscopy of individual
    sources 10 confirmed identifications (Pereira
    Miranda, 2007)
  • Detailed chemical abundance analysis of an
    increasing number of sources using high spectral
    resolution
  • IRAS 06530-0213, IRAS 08143-4406 (Reyniers et al.
    2003)
  • IRAS 193860155 (Pereira et al. 2004)
  • IRAS 13266-5551, IRAS 17311-4924 (Sarkar et al.
    2005)
  • IRAS 053811012 (Pereira Roig 2006)
  • IRAS 08281-4850, IRAS 14325-6428 (Reyniers et al.
    2007)

10
Recent progress
11
Recent progress
  • Atlas of 1500 spectral lines/features in HD
    56126, the canonical post-AGB star (Klochkova
    et al 2007)

HD 56126
F5Iab spectral type Fe/H -1.0 Strong excess
of C and s-process elements Double-peaked SED
21 micron feature at infrared wavelengths Relativ
ely high galactic latitude (b10.0 deg)
a Per
Variable and complex H-alpha profile interpreted
as shock waves estimulating mass outflow
12
Recent progress
  • Spectroscopic studies of massive O-rich AGB
    stars the precursors of heavily obscured
    post-AGBs? Determination of lithium, zirconium
    and rubidium abundances (Garcia Hernandez et al.
    2006a 2006b)
  • Strong Li interpreted as a HBB indicator (Mgt3-3.5
    M?)
  • Rb overabundances confirms the activation of the
    22Ne neutron source in massive AGB stars (Mgt4 M?)

Li I 6707
Rb I 7800
13
Binary post-AGB stars
  • Depletion in post-AGB stars surrounded by
    Keplerian dust disks (Maas et al. 2005, 2007 de
    Ruyter et al. 2006)
  • Refractory elements get locked in dust grains
  • Radial velocity variations of spectral lines with
    a period of a few hundred days are interpreted as
    the signature of binarity (van Winckel et al.
    1995)
  • Some of them confirmed as binary stars among
    them, HR 4049, HD 44179, HD 52961, HD 46703 or BD
    39 4926
  • Binarity promotes the formation of circumbinary
    stable, Keplerian dust disks

14
Recent progress
  • Diffuse Interstellar band studies indicators of
    circumstellar reddening?

(Reyniers et al. 2007)
(Luna et al. 2007)
15
Thick disk post-AGB stars
  • Classical post-AGB stars
  • Usually C-rich and s-process enriched (efficient
    dredge-up consistent with a 13C neutron source)
  • Mildly metal-deficient
  • Fe/H -0.5 to -1.0
  • Observations with HST reveal aspherical shapes in
    scattered light
  • Little to moderate reddening in the optical
  • Strong 21 micron emitters
  • Fluorescent H2 emission for stars earlier than
    A-type
  • Precursors of intermediate progenitor mass (1.0 -
    1.4 M?) C-rich PNe?

Hen 3-401
(from van Winckel 2003)
16
Galactic halo post-AGB stars
  • Optically bright, usually hot spectral types
  • Usually C-poor and non s-process enriched (no
    dredge-up)
  • Very low metallicities Fe/H lt -1.0
  • Observations with HST reveal only slight
    departures from round morphologies in scattered
    light
  • Little reddening in the optical
  • Most of them not detected by IRAS
  • May never develop a PN (progenitor mass below 1.0
    M?)

IRAS 19590-1249
Hen 3-401
IRAS 204623416
17
Thin disk post-AGB stars
IRAS 220365306
  • Usually heavily obscured and strong bipolar
    morphology
  • Shocked excited H2 emission
  • Most of them O-rich, non s-process enriched
    usually OH masers sometime CO as well (massive
    molecular envelopes)
  • Solar metallicities
  • Large dust grains including water ice
  • Sometimes show nebular emission
  • Their AGB progenitors show strong Li (HBB
    indicator) and Rb (22Ne neutron source)
    overabundances
  • Progenitors of O-rich (N-rich) type I PNe?
    (Mgt3-3.5 M?)
  • May never become observable in the optical as PNe
    in the most extreme cases

IRAS 17347-3139
18
A population of infrared PNe?
  • Rapidly evolving, heavily obscured post-AGB stars
    (some showing already nebular emission)

IRAS 17347-3139
Perea Calderón et al. (in prep.)
19
A population of infrared PNe?
  • The missing population of massive PNe with 4-8
    Msun progenitor masses?

IRAS 17347-3139
Perea Calderón et al. (in prep.)
20
Links to PNe observational facts
  • The nucleosynthesis pattern observed in galactic
    post-AGB stars is the consequence of the chemical
    branching experienced by their progenitor stars
    at the end of the AGB as a consequence of the 3rd
    dredge up).
  • Very low-mass AGB stars (Mlt1.0 M?) belonging to
    the halo population may never become PNe.
  • Low-mass AGB stars (Mlt1.0-1.4 M?) will remain
    O-rich (optically bright Miras) during the whole
    AGB evolution (progenitors of type II O-rich PNe)
  • Intermediate-mass AGB stars (Mgt 1.0-1.4 M?) may
    turn into C-rich Miras, leading eventually to
    C-rich PNe (s-process enriched as well)
  • High-mass AGB stars (Mgt3.0-3.5 M?) will activate
    the HBB and eventually become type I PNe
  • However, this branching is strongly dependent on
    the metallicity of the progenitor star
  • 3rd dredge-up is more efficient at low
    metallicity
  • HBB becomes activated at a lower mass limit at
    low metallicity

21
Summary
  • Post-AGB stars are chemically much more diverse
    than initially thought
  • Mass is the main driver of the diversity
    observed, which implies that the spectral
    properties observed, if understood, can be used
    as a mass indicator but
  • Metallicity play a crucial role as well and it is
    a necessary ingredient to fully understand and
    interpret the wide variety of spectroscopic
    properties observed
  • Mass loss and dust production is also depending
    on metallicity and introduce another complication
    in the analysis visibility is an issue
  • Massive post-AGB stars tend to show increasing
    degree of bipolarity
  • Need to extend the analysis of post-AGB stars to
    other metallicity environments (LMC, SMC?)
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