Bibcode
DOI
Belluzzi, Luca; Trujillo Bueno, Javier; Landi Degl'Innocenti, Egidio
Bibliographical reference
The Astrophysical Journal, Volume 666, Issue 1, pp. 588-608.
Advertised on:
9
2007
Journal
Citations
35
Refereed citations
20
Description
The physical interpretation of the spectral line polarization produced
by the joint action of the Hanle and Zeeman effects offers a unique
opportunity to obtain empirical information about hidden aspects of
solar and stellar magnetism. To this end, it is important to achieve a
complete understanding of the sensitivity of the emergent spectral line
polarization to the presence of a magnetic field. Here we present a
detailed theoretical investigation on the role of resonance scattering
and magnetic fields on the polarization signals of the Ba II D1 and D2
lines of the Fraunhofer spectrum at 4934 and 4554 Å, respectively.
We adopt a three-level model of Ba II, and we take into account the
hyperfine structure that is shown by the 135Ba and
137Ba isotopes. Despite their relatively small abundance
(18%), the contribution coming from these two isotopes is indeed
fundamental for the interpretation of the polarization signals observed
in these lines. We consider an optically thin slab model, through which
we can investigate in a rigorous way the essential physical mechanisms
involved (resonance polarization, Zeeman, Paschen-Back, and Hanle
effects), avoiding complications due to radiative transfer effects. We
assume the slab to be illuminated from below by the photospheric solar
continuum radiation field, and we investigate the radiation scattered at
90°, both in the absence and in the presence of magnetic fields,
deterministic and microturbulent. We show in particular the existence of
a differential magnetic sensitivity of the three-peak Q/I profile that
is observed in the D2 line in quiet regions close to the solar limb,
which is of great interest for magnetic field diagnostics.