94 research outputs found
The EGNoG Survey: Gas Excitation in Normal Galaxies at z~0.3
As observations of molecular gas in galaxies are pushed to lower star
formation rate galaxies at higher redshifts, it is becoming increasingly
important to understand the conditions of the gas in these systems to properly
infer their molecular gas content. The rotational transitions of the carbon
monoxide (CO) molecule provide an excellent probe of the gas excitation
conditions in these galaxies. In this paper we present the results from the gas
excitation sample of the Evolution of molecular Gas in Normal Galaxies (EGNoG)
survey at the Combined Array for Research in Millimeter-wave Astronomy (CARMA).
This subset of the full EGNoG sample consists of four galaxies at z~0.3 with
star formation rates of 40-65 M_Sun yr^-1 and stellar masses of ~2x10^11 M_Sun.
Using the 3 mm and 1 mm bands at CARMA, we observe both the CO(1-0) and CO(3-2)
transitions in these four galaxies in order to probe the excitation of the
molecular gas. We report robust detections of both lines in three galaxies (and
an upper limit on the fourth), with an average line ratio, r_31 = L'_CO(3-2) /
L'_CO(1-0), of 0.46 \pm 0.07 (with systematic errors \lesssim 40%), which
implies sub-thermal excitation of the CO(3-2) line. We conclude that the
excitation of the gas in these massive, highly star-forming galaxies is
consistent with normal star-forming galaxies such as local spirals, not
starbursting systems like local ultra-luminous infrared galaxies. Since the
EGNoG gas excitation sample galaxies are selected from the main sequence of
star-forming galaxies, we suggest that this result is applicable to studies of
main sequence galaxies at intermediate and high redshifts, supporting the
assumptions made in studies that find molecular gas fractions in star forming
galaxies at z~1-2 to be an order of magnitude larger than what is observed
locally.Comment: Accepted for publication in the Astrophysical Journal, to appear
January 2013; 18 pages, 10 figures, 6 table
The Mass Inflow Rate in the Barred Galaxy NGC 1530
Mass inflow in barred galaxies has been invoked to account for a wide variety
of phenomena, but until now direct evidence for inflow has been lacking. We
present Fabry-Perot H-alpha observations of the barred spiral galaxy NGC 1530
from which we determine velocities of the ionized gas for the entire region
swept by the bar. We compare the velocity field to models of gas flow in barred
spirals and show that it is well reproduced by ideal gas hydrodynamic models.
Inspection of the models and observations reveals that gas entering the bar
dust lanes streams directly down the dust lanes toward the 2 kpc radius nuclear
ring. The models predict that approximately 20% of the gas flowing down the
dust lane enters the nuclear ring; the remaining gas sprays around the ring to
the other bar dust lane. The fraction of the gas entering the ring is
relatively insensitive to the shape or size of the bar. Our observations of the
velocity field and dust optical depth yield a mass inflow rate into the nuclear
ring of 1 solar mass per year.Comment: 13 pages, 3 figures, aastex 4.0, accepted for publication in Ap J
Letter
Morphology and Kinematics of Filaments in the Serpens and Perseus Molecular Clouds
We present H13CO+ (J=1-0) and HNC (J=1-0) maps of regions in Serpens South,
Serpens Main and NGC 1333 containing filaments. We also observe the Serpens
regions using H13CN (J=1-0). These dense gas tracer molecular line observations
carried out with CARMA have an angular resolution of ~7", a spectral resolution
of ~0.16 km/s and a sensitivity of 50-100 mJy/beam. Although the large scale
structure compares well with the Herschel dust continuum maps, we resolve finer
structure within the filaments identified by Herschel. The H13CO+ emission
distribution agrees with the existing CARMA N2H+ (J=1-0) maps; so they trace
the same morphology and kinematics of the filaments. The H13CO+ maps
additionally reveal that many regions have multiple structures partially
overlapping in the line-of-sight. In two regions, the velocity differences are
as high as 1.4 m/s. We identify 8 filamentary structures having typical widths
of 0.03-0.08 pc in these tracers. At least 50% of the filamentary structures
have distinct velocity gradients perpendicular to their major axis with average
values in the range 4-10 km/s/pc. These findings are in support of the
theoretical models of filament formation by 2-D inflow in the shock layer
created by colliding turbulent cells. We also find evidence of velocity
gradients along the length of two filamentary structures; the gradients suggest
that these filaments are inflowing towards the cloud core.Comment: 30 pages, 16 figure
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