875 research outputs found
Ram-pressure stripped molecular gas in the Virgo spiral galaxy NGC 4522
IRAM 30m 12CO(1-0) and 12CO(2-1) HERA observations are presented for the
ram-pressure stripped Virgo spiral galaxy NGC 4522. The CO emission is detected
in the galactic disk and the extraplanar gas. The extraplanar CO emission
follows the morphology of the atomic gas closely but is less extended. The CO
maxima do not appear to correspond to regions where there is peak massive star
formation as probed by Halpha emission. The presence of molecular gas is a
necessary but not sufficient condition for star formation. Compared to the disk
gas, the molecular fraction of the extraplanar gas is 30% lower and the star
formation efficiency of the extraplanar gas is about 3 times lower. The
comparison with an existing dynamical model extended by a recipe for
distinguishing between atomic and molecular gas shows that a significant part
of the gas is stripped in the form of overdense arm-like structures. It is
argued that the molecular fraction depends on the square root of the total
large-scale density. Based on the combination of the CO/Halpha and an
analytical model, the total gas density is estimated to be about 4 times lower
than that of the galactic disk. Molecules and stars form within this dense gas
according to the same laws as in the galactic disk, i.e. they mainly depend on
the total large-scale gas density. Star formation proceeds where the local
large-scale gas density is highest. Given the complex 3D morphology this does
not correspond to the peaks in the surface density. In the absence of a
confining gravitational potential, the stripped gas arms will most probably
disperse; i.e. the density of the gas will decrease and star formation will
cease.Comment: 11 pages, 15 figures, A&A accepted for publicatio
Molecular hydrogen beyond the optical edge of an isolated spiral galaxy
We know little about the outermost portions of galaxies because there is
little light coming from them. We do know that in many cases atomic hydrogen
(HI) extends well beyond the optical radius \cite{Casertano91}. In the centers
of galaxies, however, molecular hydrogen (H2) usually dominates by a large
factor, raising the question of whether H2 is abundant also in the outer
regions but hitherto unseen.Here we report the detection of emission from
carbon monoxide (CO), the most abundant tracer of H2, beyond the optical radius
of the nearby galaxy NGC 4414. The molecular clouds probably formed in the
regions of relatively high HI column density and in the absence of spiral
density waves. The relative strength of the lines from the two lowest
rotational levels indicates that both the temperature and density of the H2 are
quite low compared to conditions closer to the center. The inferred surface
density of the molecular material continues the monotonic decrease from the
inner regions. We conclude that while molecular clouds can form in the outer
region of this galaxy, there is little mass associated with them.Comment: 3 Nature page
First Detection of CO in a Low Surface Brightness Galaxy
We report on the first attempts at searching for CO in red low surface
brightness galaxies, and the first detection of molecular gas in a low surface
brightness (mu_B(0)_{obs} > 23 mag arcsec^{-2}) galaxy. Using the IRAM 30m
telescope, CO(1-0) and CO(2-1) lines were searched for in four galaxies --
P06-1, P05-5, C05-3, & C04-2. In three of the galaxies no CO was detected, to
T_{MB} ~ 1.8mK (at the 3 sigma level). In the fourth galaxy, P06-1, both lines
were detected. Comparing our findings with previous studies shows P06-1 to have
a molecular-to-atomic mass ratio considerably lower than is predicted using
theoretical models based on high surface brightness galaxy studies. This
indicates the N(H_2)/(int{T(CO)dv}) conversion factor for low surface
brightness galaxies may currently be consistently underestimated by a factor of
3 - 20.Comment: 8 pages, 2 figures, accepted by the ApJ
The stellar mass to light ratio in the isolated spiral NGC 4414
We present high resolution CO(1-0) interferometric observations and deep HST
B-V-I images of the flocculent isolated Sc type spiral NGC 4414. The goal is to
determine the stellar mass-to-light (M/L) ratio in a galactic disk. The stars
are seen without a dust screen, the central gas mass is very low (undetected),
and we show that the dark matter is negligible in the central regions. We have
developed an axisymmetric analytical gravitational potential model to account
for the central light (mass) profile, the dynamics of the molecular gas in the
highly obscured molecular ring, and the stellar light profile outside the
highly obscured region. The contribution of dark matter is constrained by the
extremely extended HI rotation curve and is small, possibly negligible, at
distances less than 5 -- 7 kpc from the center. Furthermore, the M/L ratios we
derive are low, about 1.5 in I band and 0.5 in K' band. The B and V band M/L
ratios vary greatly due to absorption by dust, reaching 4 in the molecular ring
and decreasing to about 1.6 -- 1.8 at larger radii. This unequivocally shows
that models, like most maximum disk models, assuming constant M/L ratios in an
optical waveband, simply are not appropriate. We illustrate this by making mock
maximum disk models with a constant V band M/L ratio. The key is having the
central light distribution unobscured such that it can be used to trace the
mass. A primitive attempt to determine the intrinsic M/L ratio yields values
close to unity in the B,V, and I bands and slightly below 0.5 in K'.Comment: 12 pages, 10 figures, accepted in A&
The influence of the cluster environment on the star formation efficiency of 12 Virgo spiral galaxies
The influence of the environment on gas surface density and star formation
efficiency of cluster spiral galaxies is investigated. We extend previous work
on radial profiles by a pixel-to pixel analysis looking for asymmetries due to
environmental interactions. The star formation rate is derived from GALEX UV
and Spitzer total infrared data. As in field galaxies, the star formation rate
for most Virgo galaxies is approximately proportional to the molecular gas
mass. Except for NGC 4438, the cluster environment does not affect the star
formation efficiency with respect to the molecular gas. Gas truncation is not
associated with major changes in the total gas surface density distribution of
the inner disk of Virgo spiral galaxies. In three galaxies, possible increases
in the molecular fraction and the star formation efficiency with respect to the
total gas, of factors of 1.5 to 2, are observed on the windward side of the
galactic disk. A significant increase of the star formation efficiency with
respect to the molecular gas content on the windward side of ram
pressure-stripped galaxies is not observed. The ram-pressure stripped
extraplanar gas of 3 highly inclined spiral galaxies shows a depressed star
formation efficiency with respect to the total gas, and one of them (NGC 4438)
shows a depressed rate even with respect to the molecular gas. The
interpretation is that stripped gas loses the gravitational confinement and
associated pressure of the galactic disk, and the gas flow is diverging, so the
gas density decreases and the star formation rate drops. However, the stripped
extraplanar gas in one highly inclined galaxy (NGC 4569) shows a normal star
formation efficiency with respect to the total gas. We propose this galaxy is
different because it is observed long after peak pressure, and its extraplanar
gas is now in a converging flow as it resettles back into the disk.Comment: 34 pages, 24 figures, accepted for publication by A&
Molecular Gas in Tidal Dwarf Galaxies: On-going Galaxy Formation
We investigate the process of galaxy formation as can be observed in the only
currently forming galaxies -- the so-called Tidal Dwarf Galaxies, hereafter
TDGs -- through observations of the molecular gas detected via its CO (Carbon
Monoxide) emission. Molecular gas is a key element in the galaxy formation
process, providing the link between a cloud of gas and a {\it bona fide}
galaxy. We have now detected CO in 9 TDGs with an overall detection rate of
80%, showing that molecular gas is abundant in TDGs, up to a few . The CO emission coincides both spatially and kinematically with the
HI emission, indicating that the molecular gas forms from the atomic hydrogen
where the HI column density is high. A possible trend of more evolved TDGs
having greater molecular gas masses is observed, in accord with the
transformation of HI into H. Although uncertainties are still large for
individual objects as the geometry is unknown, we find that the "dynamical"
masses of TDGs, estimated from the CO line widths, do not seem to be greater
than the "visible" masses (HI + H + a stellar component), i.e., TDGs
require no dark matter. We provide evidence that TDGs are self-gravitating
entities, implying that we are witnessing the ensemble of processes in galaxy
formation: concentration of large amounts of gas in a bound object,
condensation of the gas, which is atomic at this point, to form molecular gas
and the subsequent star formation from the dense molecular component.Comment: 8 pages 4 figures, to be published in: Proceedings of the IAU
Symposium 217: Recycling Intergalactic and Interstellar Matte
Efeito alelopático de Araucaria angustifolia.
EVINCI. Resumo
The Molecular Interstellar Medium of the Local Group Dwarf NGC6822
Do molecular clouds collapse to form stars at the same rate in all
environments? In large spiral galaxies, the rate of transformation of H2 into
stars (hereafter SFE) varies little. However, the SFE in distant objects (z~1)
is much higher than in the large spiral disks that dominate the local universe.
Some small local group galaxies share at least some of the characteristics of
intermediate-redshift objects, such as size or color. Recent work has suggested
that the Star Formation Efficiency (SFE, defined as the SFRate per unit H2) in
local Dwarf galaxies may be as high as in the distant objects. A fundamental
difficulty in these studies is the independent measure of the H2 mass in
metal-deficient environments. At 490 kpc, NGC6822 is an excellent choice for
this study; it has been mapped in the CO(2-1) line using the multibeam receiver
HERA on the 30 meter IRAM telescope, yielding the largest sample of giant
molecular clouds (GMCs) in this galaxy. Despite the much lower metallicity, we
find no clear difference in the properties of the GMCs in NGC 6822 and those in
the Milky Way except lower CO luminosities for a given mass. Several
independent methods indicate that the total H2 mass in NGC 6822 is about 5 x
10^6 Msun in the area we mapped and less than 10^7 Msun in the whole galaxy.
This corresponds to a NH2/ICO ~ 4 x 10^{21} cm^-2 /(Kkm/s) over large scales,
such as would be observed in distant objects, and half that in individual GMCs.
No evidence was found for H2 without CO emission. Our simulations of the
radiative transfer in clouds are entirely compatible with these NH2/ICO values.
The SFE implied is a factor 5 - 10 higher than what is observed in large local
universe spirals.Comment: 16 pages, 13 figures. Accepted for publication in Astronomy and
Astrophysic
Galaxy Evolution and Star Formation Efficiency in the Last Half of the Universe
We present the results of a CO(1-0) emission survey with the IRAM 30m of 30
galaxies at moderate redshift (z ~ 0.2-0.6) to explore galaxy evolution and in
particular the star formation efficiency, in the redshift range filling the gap
between local and very high-z objects. Our detection rate is about 50%. One of
the bright objects was mapped at high resolution with the IRAM interferometer,
and about 50% of the total emission found in the 27 arcsec (97 kpc) single dish
beam is recovered by the interferometer, suggesting the presence of extended
emission. The FIR-to-CO luminosity ratio is enhanced, following the increasing
trend observed between local and high-z ultra-luminous starbursts.Comment: 6 pages, 5 figures, To appear in the proceedings of "SF2A-2007:
Semaine de l'Astrophysique Francaise", (J. Bouvier, A. Chalabaev, and C.
Charbonnel eds
Star Formation in Collision Debris: Insights from the modeling of their Spectral Energy Distribution
During galaxy-galaxy interactions, massive gas clouds can be injected into
the intergalactic medium which in turn become gravitationally bound, collapse
and form stars, star clusters or even dwarf galaxies. The objects resulting
from this process are both "pristine", as they are forming their first
generation of stars, and chemically evolved because the metallicity inherited
from their parent galaxies is high. Such characteristics make them particularly
interesting laboratories to study star formation. After having investigated
their star-forming properties, we use photospheric, nebular and dust modeling
to analyze here their spectral energy distribution (SED) from the
far-ultraviolet to the mid-infrared regime for a sample of 7 star-forming
regions. Our analysis confirms that the intergalactic star forming regions in
Stephan's Quintet, around Arp 105, and NGC 5291, appear devoid of stellar
populations older than 10^9 years. We also find an excess of light in the
near-infrared regime (from 2 to 4.5 microns) which cannot be attributed to
stellar photospheric or nebular contributions. This excess is correlated with
the star formation rate intensity suggesting that it is probably due to
emission by very small grains fluctuating in temperature as well as the
polycyclic aromatic hydrocarbons (PAH) line at 3.3 micron. Comparing the
attenuation via the Balmer decrement to the mid-infrared emission allows us to
check the reliability of the attenuation estimate. It suggests the presence of
embedded star forming regions in NGC 5291 and NGC 7252. Overall the SED of
star-forming regions in collision debris (and Tidal Dwarf Galaxies) resemble
more that of dusty star-forming regions in galactic disks than to that of
typical star-forming dwarf galaxies.Comment: 22 pages, 24 figures, accepted for publication in A
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