Bibcode
Rodríguez-Zaurín, J.; Arribas, S.; Monreal-Ibero, A.; Colina, L.; Alonso-Herrero, A.; Alfonso-Garzón, J.
Referencia bibliográfica
Astronomy and Astrophysics, Volume 527, id.A60
Fecha de publicación:
3
2011
Revista
Número de citas
51
Número de citas referidas
48
Descripción
Context. Luminous and ultraluminous infrared galaxies (LIRGs and ULIRGs)
are much more numerous at higher redshifts than locally, dominating the
star-formation rate density at redshifts ~1-2. Therefore, they are
important objects in order to understand how galaxies form and evolve
through cosmic time. Local samples provide a unique opportunity to study
these objects in detail. Aims: We aim to characterize the
morphologies of the stellar continuum and the ionized gas (Hα)
emissions from local sources, and investigate how they relate with the
dynamical status and IR-luminosity of the sources. Methods: We
use optical (5250-7450 Å) integral field spectroscopic (IFS) data
for a representative sample of 38 sources (31 LIRGs and 7 ULIRGs), taken
with the VIMOS instrument on the VLT. Results: We present an
atlas of IFS images of continuum emission, Hα emission, and
Hα equivalent widths for the sample. The morphologies of the
Hα emission are substantially different from those of the stellar
continuum. The Hα images frequently reveal extended structures
that are not visible in the continuum, such as HII regions in spiral
arms, tidal tails, rings, bridges, of up to few kpc from the nuclear
regions. The morphologies of the continuum and Hα images are
studied on the basis of the C2 kpc parameter, which measures
the concentration of the emission within the central 2 kpc. The C2
kpc values found for the Hα images are higher than those of
the continuum for the majority (85%) of the objects in our sample. On
the other hand, most of the objects in our sample (~62%) have more than
half of their Hα emission outside the central 2 kpc. No clear
trends are found between the values of C2 kpc and the
IR-luminosity of the sources. On the other hand, our results suggest
that the star formation in advance mergers and early-stage interactions
is more concentrated than in isolated objects. Finally, we compared the
Hα and infrared emissions as tracers of the star-formation
activity. We find that the star-formation rates derived using the
Hα luminosities generally underpredict those derived using the IR
luminosities, even after accounting for reddening effects.