215 research outputs found
Automatic Detection of Expanding HI Shells Using Artificial Neural Networks
The identification of expanding HI shells is difficult because of their
variable morphological characteristics. The detection of HI bubbles on a global
scale therefore never has been attempted. In this paper, an automatic detector
for expanding HI shells is presented. The detection is based on the more stable
dynamical characteristics of expanding shells and is performed in two stages.
The first one is the recognition of the dynamical signature of an expanding
bubble in the velocity spectra, based on the classification of an artificial
neural network. The pixels associated with these recognized spectra are
identified on each velocity channel. The second stage consists in looking for
concentrations of those pixels that were firstly pointed out, and to decide if
they are potential detections by morphological and 21-cm emission variation
considerations. Two test bubbles are correctly detected and a potentially new
case of shell that is visually very convincing is discovered. About 0.6% of the
surveyed pixels are identified as part of a bubble. These may be false
detections, but still constitute regions of space with high probability of
finding an expanding shell. The subsequent search field is thus significantly
reduced. We intend to conduct in the near future a large scale HI shells
detection over the Perseus Arm using our detector.Comment: 39 pages, 11 figures, accepted by PAS
The SNR G106.3+2.7 and its Pulsar Wind Nebula: relics of triggered star formation in a complex environment
We propose that the pulsar nebula associated with the pulsar J2229+6114 and
the supernova remnant (SNR) G106.3+2.7 are the result of the same supernova
explosion. The whole structure is located at the edge of an HI bubble with
extended regions of molecular gas inside. The radial velocities of both the
atomic hydrogen and the molecular material suggest a distance of 800 pc. At
this distance the SNR is 14 pc long and 6 pc wide. Apparently the bubble was
created by the stellar wind and supernova explosions of a group of stars in its
center which also triggered the formation of the progenitor star of G106.3+2.7.
The progenitor star exploded at or close to the current position of the pulsar,
which is at one end of the SNR rather than at its center. The expanding shock
wave of the supernova explosion created a comet shaped supernova remnant by
running into dense material and then breaking out into the inner part of the HI
bubble. A synchrotron nebula with a shell-like structure (the ``Boomerang'') of
length 0.8 pc was created by the pulsar wind interacting with the dense ambient
medium. The expanding shock wave created an HI shell of mass 0.4 Msun around
this nebula by ionizing the atomic hydrogen in its vicinity.Comment: 10 pages, Latex, with aastex and emulateapj5, 5 figures. ApJ,
accepted, scheduled for the v560 n1 p1 Oct 10, 2001 issu
GHIGLS: HI mapping at intermediate Galactic latitude using the Green Bank Telescope
This paper introduces the data cubes from GHIGLS, deep Green Bank Telescope
surveys of the 21-cm line emission of HI in 37 targeted fields at intermediate
Galactic latitude. The GHIGLS fields together cover over 1000 square degrees at
9.55' spatial resolution. The HI spectra have an effective velocity resolution
about 1.0 km/s and cover at least -450 < v < +250 km/s. GHIGLS highlights that
even at intermediate Galactic latitude the interstellar medium is very complex.
Spatial structure of the HI is quantified through power spectra of maps of the
column density, NHI. For our featured representative field, centered on the
North Ecliptic Pole, the scaling exponents in power-law representations of the
power spectra of NHI maps for low, intermediate, and high velocity gas
components (LVC, IVC, and HVC) are -2.86 +/- 0.04, -2.69 +/- 0.04, and -2.59
+/- 0.07, respectively. After Gaussian decomposition of the line profiles, NHI
maps were also made corresponding to the narrow-line and broad-line components
in the LVC range; for the narrow-line map the exponent is -1.9 +/- 0.1,
reflecting more small scale structure in the cold neutral medium (CNM). There
is evidence that filamentary structure in the HI CNM is oriented parallel to
the Galactic magnetic field. The power spectrum analysis also offers insight
into the various contributions to uncertainty in the data. The effect of 21-cm
line opacity on the GHIGLS NHI maps is estimated.Comment: Accepted for publication in The Astrophysical Journal, 2015 July 16.
32 pages, 21 figures (Fig. 10 new). Minor revisions from review, particularly
Section 8 and Appendix C; results unchanged. Additional surveys added and
made available; new Appendix B. Added descriptions of available FITS files
and links to four illustrative movies on enhanced GHIGLS archive
(www.cita.utoronto.ca/GHIGLS/
Structure formation in a colliding flow: The Herschel view of the Draco nebula
The Draco nebula is a high Galactic latitude interstellar cloud likely to
have been formed by the collision of a Galactic halo cloud entering the disk of
the Milky Way. Such conditions are ideal to study the formation of cold and
dense gas in colliding flows of warm gas. We present Herschel-SPIRE
observations that reveal the fragmented structure of the interface between the
infalling cloud and the Galactic layer. This front is characterized by a
Rayleigh-Taylor instability structure. From the determination of the typical
length of the periodic structure (2.2 pc) we estimated the gas kinematic
viscosity and the turbulence dissipation scale (0.1 pc) that is compatible with
that expected if ambipolar diffusion is the main mechanism of energy
dissipation in the WNM. The small-scale structures of the nebula are typical of
that seen in some molecular clouds. The gas density has a log-normal
distribution with an average value of cm. The size of the
structures is 0.1-0.2 pc but this estimate is limited by the resolution of the
observations. The mass ranges from 0.2 to 20 M and the distribution
of the more massive clumps follows a power law . We
identify a mass-size relation with the same exponent as that found in GMCs
() but only 15% of the mass of the cloud is in gravitationally
bound structures. We conclude that the increase of pressure in the collision is
strong enough to trigger the WNM-CNM transition caused by the interplay between
turbulence and thermal instability as self-gravity is not dominating the
dynamics.Comment: 16 pages, A&A, in pres
ISOCAM observations of the Ursa Major cirrus: Evidence for large abundance variations of small dust grains
We present mid-IR imaging observations of a high Galactic latitude cirrus
obtained with the ISO camera ISOCAM at 6" angular resolution. The observations
were done with two filters LW2 (5-8.5 microns) and LW3 (12-18 microns) that
measure respectively the aromatic carbon bands and the underlying continuum
emission from small dust particles. Three 0.05 square degree images sample
atomic and molecular sections in the Ursa Major cirrus. These images are
compared with Hi, CO and IRAS observations. In such a cloud transparent to
stellar light (Av < 0.5) the mid-infrared to 100 microns and the mid-IR
emissivity per hydrogen are related to the abundance and the optical properties
of small dust particles independently of any modelling of the penetration of
the radiation. Within the atomic section of the cloud, the comparison between
ISOCAM images and 21 cm interferometric data highlights an enhancement of the
mid-IR emitters abundance by a factor ~5 in an Hi filament characterized by a
large transverse velocity gradient suggestive of rotation. Furthermore, a drop
in the abundance of the same mid-IR emitters is observed at the interface
between the atomic and molecular cirrus sections. We propose that these
abundance variations of the mid-IR emitters are related to the production of
small dust particles by grain shattering in energetic grain-grain collisions
generated by turbulent motions within the cirrus and inversely by their
disappearance due to coagulation on large grains. At the atomic-molecular
interface we also observe a decrease of the Lw2/Lw3 ratio by a factor 2 in the
molecular region. This could result from a modification of the dust size
distribution or of the intrinsic optical properties of the small dust
particles.Comment: 11 pages, 13 figures, better resolution figures to be found in
published versio
Distribution and characteristics of Infrared Dark Clouds using genetic forward modelling
Infrared Dark Clouds (IRDCs) are dark clouds seen in silhouette in
mid-infrared surveys. They are thought to be the birthplace of massive stars,
yet remarkably little information exists on the properties of the population as
a whole (e.g. mass spectrum, spatial distribution). Genetic forward modelling
is used along with the Two Micron All Sky Survey and the Besancon Galactic
model to deduce the three dimensional distribution of interstellar extinction
towards previously identified IRDC candidates. This derived dust distribution
can then be used to determine the distance and mass of IRDCs, independently of
kinematic models of the Milky Way. Along a line of sight that crosses an IRDC,
the extinction is seen to rise sharply at the distance of the cloud. Assuming a
dust to gas ratio, the total mass of the cloud can be estimated. The method has
been successfully applied to 1259 IRDCs, including over 1000 for which no
distance or mass estimate currently exists. The IRDCs are seen to lie
preferentially along the spiral arms and in the molecular ring of the Milky
Way, reinforcing the idea that they are the birthplace of massive stars. Also,
their mass spectrum is seen to follow a power law with an index of -1.75 +/-
0.06, steeper than giant molecular clouds in the inner Galaxy, but comparable
to clumps in GMCs. This slope suggests that the IRDCs detected using the
present method are not gravitationally bound, but are rather the result of
density fluctuations induced by turbulence.Comment: 15 pages, 9 figures, accepted for publication in Ap
Science results from the imaging Fourier transform spectrometer SpIOMM
SpIOMM is an imaging Fourier transform spectrometer designed to obtain the
visible range (350 to 850 nm) spectrum of every light source in a circular
field of view of 12 arcminutes in diameter. It is attached to the 1.6-m
telescope of the Observatoire du Mont Megantic in southern Quebec. We present
here some results of three successful observing runs in 2007, which highlight
SpIOMMs capabilities to map emission line objects over a very wide field of
view and a broad spectral range. In particular, we discuss data cubes from the
planetary nebula M27, the supernova remnants NGC 6992 and M1, the barred spiral
galaxy NGC7479, as well as Stephans quintet, an interacting group of galaxies.Comment: 10 pages, 7 figures, to appear in "Ground-based and Airborne
Instrumentation for Astronomy II", SPIE conference, Marseille, 23-28 June
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