Bibcode
Beckman, J. E.; Zaragoza-Cardiel, J.; Font, J.; Amram, P.; Camps-Fariña, A.
Referencia bibliográfica
IAU General Assembly, Meeting #29, #2236571
Fecha de publicación:
8
2015
Número de citas
0
Número de citas referidas
0
Descripción
We have observed a sample of 12 interacting galaxies using the
Fabry-Perot interferometer GHαFaS (Galaxy Hα Fabry-Perot
system) on the 4.2m William Herschel Telescope (WHT) at the Observatorio
del Roque de los Muchachos, La Palma, deriving maps in Hα surface
brightness, velocity and velocity dispersion. We extracted the physical
parameters (Hα luminosities, velocity dispersions, and effective
radii) of 1300 HII regions for the full sample with techniques for which
velocity tagging is an essential step. We found two populations of HII
regions, with a break at a gas mass of 106.5 solar masses.
The mean density of the regions falls with radius for smaller masses,
but rises with radius for larger masses. This is because in the lower
mass range the HII regions are pressure bounded while in the upper range
they are gravitationally bound. This analysis is underscored by using
the turbulent velocity dispersion to show that the virial parameter for
the regions shows values consistent with gravitational equilibrium in
the upper range only. We were able to use ALMA observations of the
molecular clouds in one of our objects, the Antennae galaxies, showing
that for clouds with masses above 106.5 solar masses their
densities increase with mass. The mass functions of the molecular clouds
and HII regions in the Antennae show bimodal distributions, with the
break at 106.5 solar masses clearly in evidence. We draw two
conclusions of interest. Firstly the classical Larson scaling relation
between surface density and mass does not operate in the upper mass
range, implying higher star formation efficiency there. Secondly the
similarity in the mass functions and density radius relations for the
GMC’s and HII regions suggests that, at least in the upper mass
range, the former remain gravitationally bound even after massive star
formation has occurred.