dc.description.abstract |
The group of hydrogen-deficient (H-deficient) and carbon rich supergiants spanning
a range in their effective temperatures are: hydrogen deficient carbon (HdC)
stars, R Coronae Borealis (RCB) stars, and extreme helium (EHe) stars, in the
order of their increasing effective temperature. The origin and evolution of these
stars is not yet clear. There are two proposed scenarios for their origin. In one
dubbed the double degenerate (DD) scenario, a helium white dwarf merges with
a carbon–oxygen (C–O) white dwarf. A merger of these two white dwarfs, both
having a very thin outer H-rich layer, makes the resulting star H-deficient. An
alternative scenario dubbed the final flash (FF) scenario involves a single postasymptotic
giant branch (AGB) star experiencing a final helium shell flash which
causes the H-rich envelope to be ingested by the He shell. The result is that the
star becomes a H-deficient supergiant for a brief period and is sometimes referred
in this condition as a ‘born-again’ AGB star. In this thesis, the origins and evolution
of H-deficient supergiants are investigated: First, by conducting a survey
for identifying H-deficient stars in the Galactic globular cluster ω Centauri, and to
pin-point their positions on the HR-diagram, and second, by deriving the Galactic
RCB/HdC stars C-abundances and the 12C/13C ratios that are potential clues to
their origin.
The distances are not accurately known to any of the Galactic H-deficient stars.
The position of a star on the HR-diagram, gives us an idea about its evolution
and possibly its origin. To place the H-deficient stars on the HR-diagram, one
of the best ways would be to search for these stars in the globular clusters of
the Galaxy. Hence, a survey was conducted to identify new H-deficient stars in
the largest and brightest globular cluster of the Galaxy: ω Centauri. Our survey
is based on the Str¨omgren photometric studies of red giant stars in ω Cen by
Calamida et al. (2009). From the photometric and the spectroscopic studies of
the red giant stars of ω Cen, it is clear that they show a large spread in their metallicity: −2.5<[Fe/H]<+0.5. This spread in metallicity, not as expected for
the globular cluster, is taken as a clue for the presence of H-deficient stars in
ω Cen. By applying the photometric and the spectroscopic characteristics of the
RCB/HdC stars, the program stars were selected. For these program stars, the
low-resolution spectra were obtained from the Vainu Bappu Observatory (VBO),
Kavalur, India. The analyses were carried out based on the strengths of the (0,0)
MgH band extending from 5330 to 4950˚A, with the band head at 5211˚A, and the
Mg b lines at 5167.32˚A, 5172.68˚A and 5183.60˚A. Based on the strengths of these
features, the three groups were identified in our sample: (i) the metal rich giants
with strong Mg b lines and the MgH band, (ii) the metal poor giants with weak
Mg b lines and no MgH band, and (iii) the metal rich giants with strong Mg b
lines, but no MgH band. By comparing the observed MgH bands among the stars
of (i) and (iii) group, with similar stellar parameters, four stars were identified
having weaker or absent MgH band. Two stars: 178243 and 73170 are from the
first group showing the strong Mg b lines, but weaker MgH band than expected
for their stellar parameters. The other two stars: 262788 and 193804 are from the
third group showing strong Mg b lines, but absent MgH band not as expected for
their stellar parameters. The MgH band strengths in the observed spectra of these
four stars along with all the first and third group stars, were further analyzed by
synthesis. The Mg abundances derived for these four stars are much lower than
that expected for the red giants of ω Cen as given by Norris & Da Costa (1995)
for their metallicities. The weak/absent MgH band in the observed spectra of
these four giants inspite of the presence of strong Mg b lines, may not be due to
the stellar parameters or a lower Mg abundance. The only plausible reason is
a relatively lower abundance of hydrogen in their atmosphere. Hence, from our
survey, we report the discovery of four giants with relatively lower abundance of
hydrogen in their atmospheres. In this survey we have not found any H-deficient
star of RCB-type. This result is in agreement with our prediction for the number
of H-deficient stars formed by the DD and FF scenario in the globular cluster, ω Cen.
To explore the origin of the Galactic RCB stars, the carbon abundances and the
12C/13C ratios of RCB and HdC stars were determined by synthesizing the (0, 0),
(1, 0) and (0, 1) C2 Swan bands, and matching them with the observed spectrum.
High-resolution optical spectra of RCB/HdC stars at maximum light were obtained
from the W. J. McDonald Observatory, USA, and the Vainu Bappu Observatory,
India. The carbon abundances determined from the Ci lines are a factor of four
lower than that adopted for the model atmosphere, and is dubbed as the ‘carbon
problem’ (Asplund et al. 2000). This discrepancy persists with the change in the
input carbon abundance of the adopted model atmosphere. Whereas, the carbon
abundance derived from the C2 Swan bands is about the same for the adopted
models constructed with different carbon abundances over the range 8.5 (C/He
= 0.1%) to 10.5 (C/He = 10%). The 12C/13C ratios determined for the majority
RCBs and all the HdCs are much higher than the CN-cycle equilibrium value of
3.4. These high values are consistent with that predicted for the cold merger of a
He white dwarf with a CO white dwarf. The two minority RCB stars (stars which
are metal poor and having high [Si/Fe] and [S/Fe] ratios, relative to the majority
RCB stars) are having low values of 12C/13C ratios, that are close to the CN-cycle
equilibrium value. These low values of 12C/13C ratios remain unaccounted due
to their distinctive pattern of elemental abundances. The carbon abundance and
the 12C/13C ratio were also determined for the final flash object, V4334 Sgr. The
carbon abundance of V4334 Sgr is about 10-100 times higher than the RCB/HdC
stars, and the 12C/13C ratio is about 3.4, the CN-cycle equilibrium value. These
values are as expected for the final flash object. |
en_US |