Bibcode
DOI
Shchukina, Nataliya; Trujillo Bueno, Javier
Referencia bibliográfica
The Astrophysical Journal, Volume 550, Issue 2, pp. 970-990.
Fecha de publicación:
4
2001
Revista
Número de citas
159
Número de citas referidas
141
Descripción
This paper presents the results of a detailed theoretical investigation
of the iron line formation NLTE problem in a three-dimensional model of
the solar photosphere, which we have obtained from a very recent
radiation hydrodynamics simulation of solar surface convection. In this
first paper we have neglected the effects of horizontal radiative
transfer on the atomic level populations, but we have considered a
realistic atomic model for iron that contains hundreds of radiative
transitions from the UV to the IR. The self-consistent solutions of the
kinetic and transfer equations have been obtained with a new NLTE code,
which is based on very efficient iterative methods. We find that
overionization due to the near-UV radiation field does take place but
mainly in the granular atmospheric regions. This well-known NLTE
mechanism tends to produce underpopulation of all the Fe I levels and a
very small overexcitation of the Fe II levels. All over the
three-dimensional photospheric model Fe II is the dominant ionization
stage. We find significant LTE versus NLTE discrepancies mainly for the
low-excitation Fe I lines. This applies to both the vertically emergent
profiles from the granular regions and also to the spatially averaged
profiles. These discrepancies are due to the line opacity deficits that
result from the aforementioned underpopulation of the Fe I levels. The
emergent profiles of the low-excitation lines of Fe I are thus weaker in
NLTE than in LTE. In particular, the largest errors in the equivalent
widths (due to the LTE assumption) are found for the weakest
low-excitation lines of Fe I. We also give quantitative estimates of the
errors in the temperature structure of semiempirical solar granulation
models obtained via the application of LTE inversion techniques to
several groups of Fe I lines. For instance, the widely used Fe I 6301
and 6302 Å lines tend to lead to an overestimation of about
100-200 K in the granular regions but to a similar underestimation in
the intergranular plasma. The present paper considers also the case of
the Sun observed with low spatial resolution, with particular emphasis
on the long-standing iron abundance problem. We show that it is possible
to obtain a very good fit to the observed spectral line shapes by
slightly changing the iron abundance (for both the LTE and NLTE cases).
In general, the iron abundance we need for reaching the best NLTE fit to
observed equivalent widths is 0.074+/-0.03 dex larger than that needed
to obtain the best LTE fit. Our most relevant conclusion with regard to
the solar iron abundance issue is the following: if NLTE effects are
fully taken into account in the three-dimensional model of the solar
photosphere, we obtain the meteoritic iron abundance value
(AFe=7.50). However, if the abundance analysis is done
assuming LTE, we find AFe=7.43, in close agreement with the
recent LTE analysis of Asplund and collaborators. Our results do
indicate that NLTE effects are significant but not above the 0.1 dex
level in the Sun. We consider our NLTE result for the iron abundance as
an additional hint of the realism of such three-dimensional hydrodynamic
simulations. We conclude that the success of the LTE fitting approach is
no proof that NLTE effects are negligible because the existing NLTE
effects are compensated for in the LTE analysis by a change in the
derived iron abundance. The paper ends emphasizing the great importance
of a full three-dimensional NLTE approach in order to be able to lead to
new advances in the field of quantitative stellar spectroscopy and, in
particular, for a correct derivation of elemental abundance ratios in
the atmospheres of metal-poor stars.