1,024 research outputs found
Outflow or galactic wind: The fate of ionized gas in the halos of dwarf galaxies
Context: H\alpha images of star bursting irregular galaxies reveal a large
amount of extended ionized gas structures, in some cases at kpc-distance away
from any place of current star forming activity. A kinematic analysis of
especially the faint structures in the halo of dwarf galaxies allows insights
into the properties and the origin of this gas component. This is important for
the chemical evolution of galaxies, the enrichment of the intergalactic medium,
and for the understanding of the formation of galaxies in the early universe.
Aims: We want to investigate whether the ionized gas detected in two
irregular dwarf galaxies (NGC 2366 and NGC 4861) stays gravitationally bound to
the host galaxy or can escape from it by becoming a freely flowing wind.
Methods: Very deep H\alpha images of NGC 2366 and NGC 4861 were obtained to
detect and catalog both small and large scale ionized gas structures down to
very low surface brightnesses. Subsequently, high-resolution long-slit echelle
spectroscopy of the H\alpha line was performed for a detailed kinematic
analysis of the most prominent filaments and shells. To calculate the escape
velocity of both galaxies and to compare it with the derived expansion
velocities of the detected filaments and shells, we used dark matter halo
models.
Results: We detected a huge amount of both small scale (up to a few hundred
pc) and large scale (about 1-2 kpc of diameter or length) ionized gas
structures on our H\alpha images. Many of the fainter ones are new detections.
The echelle spectra reveal outflows and expanding bubbles/shells with
velocities between 20 and 110 km/s. Several of these structures are in
accordance with filaments in the H\alpha images. A comparison with the escape
velocities of the galaxies derived from the NFW dark matter halo model shows
that all gas features stay gravitationally bound.Comment: 15 pages, 13 figures, accepted for publication in A&
On the Dynamical and Physical State of the `Diffuse Ionized Medium' in Nearby Spiral Galaxies
We have analyzed deep narrow-band H images and high-resolution
long-slit spectra for a sample of the nearest and brightest late-type galaxies
to study the morphology, physical state, and kinematics of the `Diffuse Ionized
Medium' (`DIM'). We find that the DIM covers most of the star-forming disk, and
is morphologically related to the presence of the giant HII regions. In
addition, the DIM and the giant HII regions differ systematically in their
physical and dynamical state. The DIM is characterized by enhanced emission in
the low-ionization forbidden lines ([OI], [NII], and [SII]), and even the
high-ionization [OIII]5007 line is moderately strong in the DIM. We
verify the inference made by Lehnert & Heckman that the DIM contributes
significantly to the global emission-line ratios measured in late-type
galaxies. We also find that the DIM is more disturbed kinematically than the
gas in the giant HII regions. The intrinsic FWHMs of the H and
[NII]6584 lines range from 30 to 100 km s in the DIM compared
to 20-50 km s in HII regions. The high-ionization gas in the DIM is even
more kinematically disturbed than the low-ionization gas: the
[OIII]5007 lines have intrinsic FWHMs of 70-150 km s. The
differing kinematics implies that `the DIM' is not a single monolithic phase of
the ISM. Instead, it may consist of a `quiescent DIM' with a low
ionization-state and small scale-height (few hundred pc) and a `disturbed DIM'
with a high ionization state and moderate scale-height (0.5 to 1 kpc). We argue
that the quiescent DIM is most likely photoionized by radiation leaking out of
giant HII regions, while the disturbed DIM is most likely heated by the
mechanical energy supplied by supernovae and stellar winds.Comment: 37 pages(including 7 tables) and 12 figures. To appear in the Dec 10,
1997 issue of The Astrophysical Journa
High Latitude Radio Emission in a Sample of Edge-On Spiral Galaxies
We have mapped 16 edge-on galaxies at 20 cm using the VLA. For 5 galaxies, we
could form spectral index, energy and magnetic field maps. We find that all but
one galaxy show evidence for non-thermal high latitude radio continuum
emission, suggesting that cosmic ray halos are common in star forming galaxies.
The high latitude emission is seen over a variety of spatial scales and in
discrete and/or smooth features. In general, the discrete features emanate from
the disk, but estimates of CR diffusion lengths suggest that diffusion alone is
insufficient to transport the particles to the high latitudes seen (> 15 kpc in
one case). Thus CRs likely diffuse through low density regions and/or are
assisted by other mechanisms (e.g. winds). We searched for correlations between
the prevalence of high latitude radio emission and a number of other
properties, including the global SFR, supernova input rate per unit star
forming, and do not find clear correlations with any of these properties.Comment: 40 pages of text, 3 figures, 6 tables, and an appendix of 21 jpeg
figures (which is a radio continuum catalogue of 17 galaxies). to appear in
A. J. (around January 1999
K-Band Observations of Boxy Bulges. I. Morphology and Surface Brightness Profiles
Kn-band images, unsharp-masked images, as well as major-axis and vertically-
summed surface brightness profiles are presented for 30 edge-on spiral
galaxies, most with a boxy or peanut-shaped (B/PS) bulge. Such galaxies have
more complex morphologies than galaxies of other bulge types, more often
showing (off-)centered X structures, secondary major-axis maxima and
spiral-like structures. Those features are also observed in N-body simulations
of barred discs and may trace the main bar orbit families. The surface
brightness profiles of galaxies with a B/PS bulge are also more complex, with
typically 3 or more clearly separated regions, including a flat intermediate
region (Freeman Type II profiles). Those radial breaks offer evidence for
bar-driven transfer of angular momentum and radial redistribution of material.
The profiles also suggest a rapid variation of the scaleheight of the disc
material, contrary to conventional wisdom but again as expected from vertical
resonances and instabilities in barred discs. The steep inner region of the
surface brightness profiles is often shorter than the isophotally thick part of
the galaxies, itself always shorter than the flat region of the profiles.
Contrary to the standard `bulge + disc' model, we thus propose that galaxies
with a B/PS bulge are composed of a thin concentrated disc (a disc-like bulge)
contained within a partially thick bar (the B/PS bulge) and a thin outer disc.
The inner disc likely formed secularly through bar-driven processes and is
responsible for the steep inner region of the surface brightness profiles,
while the bar is responsible for the flat region and the thick complex
morphological structures observed. Those components are strongly coupled
dynamically and are formed mostly of the same (disc) material. [Abridged]Comment: 23 pages, 34 figures. Accepted for publication in MNRAS. A version
with full resolution figures is available at
http://www-astro.physics.ox.ac.uk/~bureau/pub_list.htm
Chandra Observations and the Nature of the Anomalous Arms of NGC 4258 (M 106)
This paper presents high resolution X-ray observations with Chandra of NGC
4258 and infers the nature of the so called ``anomalous arms'' in this galaxy.
The anomalous arms dominate the X-ray image; diffuse X-ray emission from the
``plateaux'' regions, seen in radio and H imaging, is also found. X-ray
spectra have been obtained at various locations along the anomalous arms and
are well described by thermal (mekal) models with kT in the range 0.37 - 0.6
keV. The previously known kpc-scale radio jets are surrounded by cocoons of hot
X-ray emitting gas for the first 350 pc of their length. The radio jets, seen
in previous VLBA and VLA observations, propagate perpendicular to the compact
nuclear gas disk (imaged in water vapor maser emission). The angle between the
jets and the rotation axis of the galactic disk is 60. The jets shock
the normal interstellar gas along the first 350 pc of their length, causing the
hot, X-ray emitting cocoons noted above. At a height of z = 175 pc from the
disk plane, the jets exit the normal gas disk and then propagate though the low
density halo until they reach ``hot spots'' (at 870 pc and 1.7 kpc from the
nucleus), which are seen in radio, optical line and X-ray emission. These jets
must drive mass motions into the low density halo gas. This high velocity halo
gas impacts on the dense galactic gas disk and shock heats it along and around
a ``line of damage'', which is the projection of the jets onto the galactic gas
disk as viewed down the galaxy disk rotation axis. However, because NGC 4258 is
highly inclined ( = 64), the ``line of damage'' projects on the
sky in a different direction to the jets themselves. We calculate the expected
p.a. of the ``line of damage'' on the sky and find that it coincides with the
anomalous arms to within 2. (Abstract truncated).Comment: 12 pages plus 9 figures, to be published in the Astrophysical
Journal, v560, nr 1, pt 1 (Oct 10, 2001 issue
Calibrating the relation of low-frequency radio continuum to star formation rate at 1 kpc scale with LOFAR
9 figures, 6 tables and 17 pages. This paper is part of the LOFAR surveys data release 1 and has been accepted for publication in a special edition of A&A that will appear in Feb 2019, volume 622. The catalogues and images from the data release will be publicly available on lofar-surveys.org upon publication of the journal. Reproduced with permission from Astronomy & Astrophysics. © 2018 ESO.Radio continuum (RC) emission in galaxies allows us to measure star formation rates (SFRs) unaffected by extinction due to dust, of which the low-frequency part is uncontaminated from thermal (free-free) emission. We calibrate the conversion from the spatially resolved 140 MHz RC emission to the SFR surface density () at 1 kpc scale. We used recent observations of three galaxies (NGC 3184, 4736, and 5055) from the LOFAR Two-metre Sky Survey (LoTSS), and archival LOw-Frequency ARray (LOFAR) data of NGC 5194. Maps were created with the facet calibration technique and converted to radio maps using the Condon relation. We compared these maps with hybrid maps from a combination of GALEX far-ultraviolet and Spitzer 24 data using plots tracing the relation at -kpc resolution. The RC emission is smoothed with respect to the hybrid owing to the transport of cosmic-ray electrons (CREs). This results in a sublinear relation , where (140 MHz) and (1365 MHz). Both relations have a scatter of . If we restrict ourselves to areas of young CREs (; ), the relation becomes almost linear at both frequencies with and a reduced scatter of . We then simulate the effect of CRE transport by convolving the hybrid maps with a Gaussian kernel until the RC-SFR relation is linearised; CRE transport lengths are -5 kpc. Solving the CRE diffusion equation, we find diffusion coefficients of - at 1 GeV. A RC-SFR relation at GHz can be exploited to measure SFRs at redshift using MHz observations.Peer reviewe
The quest for hot gas in the halo of NGC 1511
XMM-Newton observations of the starburst galaxy NGC 1511 reveal the presence
of a previously unknown extended hot gaseous phase of its ISM, which partly
extends out of the disk plane. The emission distribution is asymmetric, being
brightest in the eastern half of the galaxy, where also radio continuum
observations suggest the highest level of star formation. Spectral analysis of
the integral 0.2-12 keV X-ray emission from NGC 1511 indicates a complex
emission composition. A model comprising a power law plus thermal plasma
component, both absorbed by foreground gas, cannot explain all details of the
observed spectrum, requiring a third spectral component to be added. This
component can be a second thermal plasma, but other spectral models can be
fitted as well. Its X-ray properties characterize NGC 1511 as a starburst
galaxy. The X-ray-to-infrared luminosity ratio is consistent with this result.
Together with the X-ray data, XMM-Newton obtained UV images of NGC 1511,
tracing massive stars heating the ambient gas, which is then seen in H\alpha
emission. UV, H\alpha and near-infrared imagery suggest that NGC 1511 is
disturbed, most likely by its two small companions, NGC 1511a and NGC 1511b.Comment: 7 pages, 7 figures, accepted for publication in A&
The nature of the low-frequency emission of M51: First observations of a nearby galaxy with LOFAR
The grand-design spiral galaxy M51 was observed with the LOFAR High Frequency
Antennas (HBA) and imaged in total intensity and polarisation. This observation
covered the frequencies between 115 MHz and 175 MHz. We produced an image of
total emission of M51 at the mean frequency of 151 MHz with 20 arcsec
resolution and 0.3 mJy rms noise, which is the most sensitive image of a galaxy
at frequencies below 300 MHz so far. The integrated spectrum of total radio
emission is described well by a power law, while flat spectral indices in the
central region indicate thermal absorption. We observe that the disk extends
out to 16 kpc and see a break in the radial profile near the optical radius of
the disk. Our main results, the scale lengths of the inner and outer disks at
151 MHz and 1.4 GHz, arm--interarm contrast, and the break scales of the
radio--far-infrared correlations, can be explained consistently by CRE
diffusion, leading to a longer propagation length of CRE of lower energy. The
distribution of CRE sources drops sharply at about 10 kpc radius, where the
star formation rate also decreases sharply. We find evidence that thermal
absorption is primarily caused by HII regions. The non-detection of
polarisation from M51 at 151 MHz is consistent with the estimates of Faraday
depolarisation. Future searches for polarised emission in this frequency range
should concentrate on regions with low star formation rates.Comment: 20 pages, 18 figures, accepted for publication in A&
A Kinematic Link between Boxy Bulges, Stellar Bars, and Nuclear Activity in NGC 3079 & NGC 4388
We present direct kinematic evidence for bar streaming motions in two active
galaxies with boxy stellar bulges. The Hawaii Imaging Fabry-Perot
Interferometer was used on the Canada-France-Hawaii 3.6-m telescope and the
University of Hawaii 2.2-m telescope to derive the two-dimensional velocity
field of the line-emitting gas in the disks of the Sc galaxy NGC 3079 and the
Sb galaxy NGC 4388. In contrast to previous work based on long-slit data, the
detection of the bar potential from the Fabry-Perot data does not rely on the
existence of inner Lindblad resonances or strong bar-induced shocks. Simple
kinematic models which approximate the intrinsic gas orbits as nonintersecting,
inclined elliptical annuli that conserve angular momentum characterize the
observed velocity fields. Box-shaped bulges in both NGC 3079 and NGC 4388 are
confirmed using new near-infrared images to reduce dust obscuration.
Morphological analysis of starlight in these galaxies is combined with the gas
kinematics derived from the Fabry-Perot spectra to test evolutionary models of
stellar bars that involve transitory boxy bulges, and to quantify the
importance of such bars in fueling active nuclei. Our data support the
evolutionary bar models, but fail to prove convincingly that the stellar bars
in NGC 3079 and NGC 4388 directly trigger or sustain the nuclear activity.
(abridged)Comment: 31 pages, 18 figures, Latex, requires aaspp4.sty. Accepted for the
Astronomical Journal (November issue
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