Bibcode
DOI
Colina, Luis; Arribas, Santiago; Monreal-Ibero, A.
Referencia bibliográfica
The Astrophysical Journal, Volume 621, Issue 2, pp. 725-737.
Fecha de publicación:
3
2005
Revista
Número de citas
82
Número de citas referidas
77
Descripción
The kinematic properties of the gaseous and stellar components of 11
ultraluminous infrared galaxies (ULIRGs; 14 nuclei) are investigated by
means of integral field spectroscopy (IFS) with the INTEGRAL system and
available IR and CO millimeter spectroscopy. The sample of ULIRGs cover
different phases of the merging process and span all levels of activity
from pure starbursts to Seyfert nuclei. The IFS data show that the
ionized gas has a complex velocity structure with peak-to-peak velocity
differences of a few to several hundred km s-1, detected in
tidal tails or extranuclear star-forming regions. The velocity field of
the ionized gas on scales of a few to several kiloparsecs is dominated
by tidally induced flows and does not, in general, correspond to
rotationally supported systems with a privileged orientation along the
major rotating axis. The central velocity amplitude of the ionized gas
and stars shows discrepancies in some galaxies but has, on average, a
similar value (ratio of 0.92+/-0.37) , while the velocity amplitude of
the molecular gas is a factor of 2 larger (ratio of 1.9+/-0.6) than that
of the stars and ionized gas. The central velocity amplitude measured
using different kinematic tracers should therefore not be used in ULIRGs
as a reliable tracer of mass, in general. The IFS data also show that
the velocity dispersion of the ionized gas maps the large-scale motions
associated with tidal tails and extranuclear regions, with often the
highest velocity dispersion not being associated with the nucleus
galaxies. There is, however, a good agreement between the central
ionized gas and stellar velocity dispersions (ratio of 1.01+/-0.13),
while the cold molecular gas velocity dispersion has lower values
(average of about 0.8 that of the stellar and ionized gas). The central
ionized gas velocity dispersion is therefore a robust and homogeneous
observable and a good tracer of the dynamical mass in these systems. The
IFS-based central ionized gas velocity dispersion measurements confirm
that ULIRGs' hosts are moderate-mass (<=m*) galaxies, as
previously concluded by Tacconi and coworkers. In general, velocity
amplitudes should not be used to estimate the dynamical mass in high-z
star-forming systems, such as Lyman break and in particular
submillimeter galaxies, since they show irregular stellar and gaseous
structures similar to those present in low-z merging systems such as
ULIRGs, the subject of this study. A more reliable method is to measure
the central velocity dispersion using the strong, high equivalent width,
rest-frame optical emission lines, provided the location of the nucleus
is independently established by high angular resolution red or near-IR
rest-frame imaging. The kinematics derived from the millimeter CO line
suggest that the cold gas in ULIRGs does not share the velocity field of
the stars and ionized gas and seems to be more rotationally supported.
This result needs to be investigated in more detail with a larger sample
of low-z ULIRGs before using the millimeter CO line widths as a
dynamical mass tracer in high-z submillimeter galaxies.
Based on observations with the William Herschel Telescope operated on
the island of La Palma by the ING in the Spanish Observatorio del Roque
de los Muchachos of the Instituto de Astrofísica de Canarias.
Based also on observations with the NASA/ESA Hubble Space Telescope,
obtained at the Space Telescope Science Institute, which is operated by
the Association of Universities for Research in Astronomy, Inc., under
NASA contract NAS5-26555.