Bibcode
Villar-Martín, M.; Cerviño, M.; González Delgado, R. M.
Bibliographical reference
Monthly Notices of the Royal Astronomical Society, Volume 355, Issue 4, pp. 1132-1142.
Advertised on:
12
2004
Citations
48
Refereed citations
46
Description
We have characterized the physical properties (electron temperature,
density and metallicity) of the ionized gas and the ionizing population
(age, metallicity and presence of Wolf-Rayet stars) in the Lynx arc, an
HII galaxy at z= 3.36. The ultraviolet doublets (i.e. CIII], SiIII] and
NIV) imply the existence of a density gradient in this object, with a
high-density region (0.1-1.0 × 105cm-3) and
a lower density region (<3200cm-3). The
temperature-sensitive ratio [OIII]λλ1661,1666/λ5007
implies an electron temperature Te=
17300+500-700 K, in agreement within the errors
with photoionization model predictions. Nebular abundance determination
using standard techniques and the results from photoionization models
imply a nebular metallicity of O/H ~ 10 +/- 3percent
(O/H)solar, in good agreement with recent results from
Fosbury et al. Both methods suggest that nitrogen is overabundant
relative to other elements, with [N/O]~ 2.0-3.0
×[N/O]solar. We do not find evidence for Si
overabundance, as Fosbury et al. did.
Photoionization models imply that the ionizing stellar population in the
Lynx arc has an age of <~5 Myr. If He+ is ionized by
Wolf-Rayet (WR) stars, then the ionizing stars in the Lynx arc have
metallicities Zstar > 5percent Zsolar and ages
~2.8-3.4 Myr (depending on Zstar), when WR stars appear and
are responsible for the He2+ emission. However, alternative
excitation mechanisms for this species are not discarded. Since the
emission lines trace the properties of the present burst only, nothing
can be said about the possible presence of an underlying old stellar
population.
The Lynx arc is a low-metallicity HII galaxy that is undergoing a burst
of star formation of <~5 Myr age. One possible scenario that explains
the emission-line spectrum of the Lynx arc, the large strength of the
nitrogen lines and the He2+ emission is that the object has
experienced a merger event that has triggered a burst of star formation.
WR stars have formed that contribute to a fast enrichment of the
interstellar medium.
Like Fosbury et al., we find a factor of >~10 discrepancy between the
mass of the instantaneous burst required to power the luminosity of the
Hβ line and the mass implied by the continuum level measured for
the Lynx arc. We discuss several possible solutions to this problem. The
most likely explanation is that gas and stars have different spatial
distributions, so that the emission lines and the stellar continuum
suffer different gravitational amplifications by the intervening
cluster.