102 research outputs found
Spitzer characterisation of dust in an anomalous emission region: the Perseus cloud
Anomalous microwave emission is known to exist in the Perseus cloud. One of
the most promising candidates to explain this excess of emission is electric
dipole radiation from rapidly rotating very small dust grains, commonly
referred to as spinning dust. Photometric data obtained with the Spitzer Space
Telescope have been reprocessed and used in conjunction with the dust emission
model DUSTEM to characterise the properties of the dust within the cloud. This
analysis has allowed us to constrain spatial variations in the strength of the
interstellar radiation field (), the mass abundances of the
PAHs and VSGs relative to the BGs (Y and Y), the
column density of hydrogen (N) and the equilibrium dust
temperature (T). The parameter maps of Y,
Y and are the first of their kind to be
produced for the Perseus cloud, and we used these maps to investigate the
physical conditions in which anomalous emission is observed. We find that in
regions of anomalous emission the strength of the ISRF, and consequently the
equilibrium temperature of the dust, is enhanced while there is no significant
variation in the abundances of the PAHs and the VSGs or the column density of
hydrogen. We interpret these results as an indication that the enhancement in
might be affecting the properties of the small
stochastically heated dust grains resulting in an increase in the spinning dust
emission observed at 33 GHz. This is the first time that such an investigation
has been performed, and we believe that this type of analysis creates a new
perspective in the field of anomalous emission studies, and represents a
powerful new tool for constraining spinning dust models.Comment: 13 pages, 9 figures, accepted for publication in MNRA
Radiative transfer on hierarchial grids
We present new methods for radiative transfer on hierarchial grids. We
develop a new method for calculating the scattered flux that employs the grid
structure to speed up the computation. We describe a novel subiteration
algorithm that can be used to accelerate calculations with strong dust
temperature self-coupling. We compute two test models, a molecular cloud and a
circumstellar disc, and compare the accuracy and speed of the new algorithms
against existing methods. An adaptive model of the molecular cloud with less
than 8 % of the cells in the uniform grid produced results in good agreement
with the full resolution model. The relative RMS error of the surface
brightness <4 % at all wavelengths, and in regions of high column density the
relative RMS error was only 10^{-4}. Computation with the adaptive model was
faster by a factor of ~5. The new method for calculating the scattered flux is
faster by a factor of ~4 in large models with a deep hierarchy structure, when
images of the scattered light are computed towards several observing
directions. The efficiency of the subiteration algorithm is highly dependent on
the details of the model. In the circumstellar disc test the speed-up was a
factor of two, but much larger gains are possible. The algorithm is expected to
be most beneficial in models where a large number of small, dense regions are
embedded in an environment with a lower mean density.Comment: Accepted to A&A; 13 pages, 8 figures; (v2: minor typos corrected
90GHz and 150GHz observations of the Orion M42 region. A sub-millimeter to radio analysis
We have used the new 90GHz MUSTANG camera on the Robert C. Byrd Green Bank
Telescope (GBT) to map the bright Huygens region of the star-forming region M42
with a resolution of 9" and a sensitivity of 2.8mJy/beam. 90GHz is an
interesting transition frequency, as MUSTANG detects both the free-free
emission characteristic of the HII region created by the Trapezium stars,
normally seen at lower frequencies, and thermal dust emission from the
background OMC1 molecular cloud, normally mapped at higher frequencies. We also
present similar data from the 150GHz GISMO camera taken on the IRAM telescope.
This map has 15" resolution. By combining the MUSTANG data with 1.4, 8, and
21GHz radio data from the VLA and GBT, we derive a new estimate of the emission
measure (EM) averaged electron temperature of Te = 11376K by an original method
relating free-free emission intensities at optically thin and optically thick
frequencies. Combining ISO-LWS data with our data, we derive a new estimate of
the dust temperature and spectral emissivity index within the 80" ISO-LWS beam
toward OrionKL/BN, Td = 42K and Beta=1.3. We show that both Td and Beta
decrease when going from the HII region and excited OMC1 interface to the
denser UV shielded part of OMC1 (OrionKL/BN, Orion S). With a model consisting
of only free-free and thermal dust emission we are able to fit data taken at
frequencies from 1.5GHz to 854GHz.Comment: 18 pages, 8 figures, submitted to the Astrophysical Journa
Satellite Radiation Products for Ocean Biology and Biogeochemistry: Needs, State-of-the-Art, Gaps, Development Priorities, and Opportunities
Knowing the spatial and temporal distribution of the underwater light field, i.e., the spectral and angular structure of the radiant intensity at any point in the water column, is essential to understanding the biogeochemical processes that control the composition and evolution of aquatic ecosystems and their impact on climate and reaction to climate change. At present, only a few properties are reliably retrieved from space, either directly or via water-leaving radiance. Existing satellite products are limited to planar photosynthetically available radiation (PAR) and ultraviolet (UV) irradiance above the surface and diffuse attenuation coefficient. Examples of operational products are provided, and their advantages and drawbacks are examined. The usefulness and convenience of these products notwithstanding, there is a need, as expressed by the user community, for other products, i.e., sub-surface planar and scalar fluxes, average cosine, spectral fluxes (UV to visible), diurnal fluxes, absorbed fraction of PAR by live algae (APAR), surface albedo, vertical attenuation, and heating rate, and for associating uncertainties to any product on a pixel-by-pixel basis. Methodologies to obtain the new products are qualitatively discussed in view of most recent scientific knowledge and current and future satellite missions, and specific algorithms are presented for some new products, namely sub-surface fluxes and average cosine. A strategy and roadmap (short, medium, and long term) for usage and development priorities is provided, taking into account needs and readiness level. Combining observations from satellites overpassing at different times and geostationary satellites should be pursued to improve the quality of daily-integrated radiation fields, and products should be generated without gaps to provide boundary conditions for general circulation and biogeochemical models. Examples of new products, i.e., daily scalar PAR below the surface, daily average cosine for PAR, and sub-surface spectral scalar fluxes are presented. A procedure to estimate algorithm uncertainties in the total uncertainty budget for above-surface daily PAR, based on radiative simulations for expected situations, is described. In the future, space-borne lidars with ocean profiling capability offer the best hope for improving our knowledge of sub-surface fields. To maximize temporal coverage, space agencies should consider placing ocean-color instruments in L1 orbit, where the sunlit part of the Earth can be frequently observed
Modelling the spinning dust emission from dense interstellar clouds
Electric dipole emission arising from PAHs is often invoked to explain the
anomalous microwave emission (AME). This assignation is based on an observed
tight correlation between the mid-IR emission of PAHs and the AME; and a good
agreement between models of spinning dust and the broadband AME spectrum. So
far often detected at large scale in the diffuse interstellar medium, the AME
has recently been studied in detail in well-known dense molecular clouds with
the help of Planck data. While much attention has been given to the physics of
spinning dust emission, the impact of varying local physical conditions has not
yet been considered in detail. Our aim is to study the emerging spinning dust
emission from interstellar clouds with realistic physical conditions and
radiative transfer. We use the DustEM code from Compiegne et al. to describe
the extinction and IR emission of all dust populations. The spinning dust
emission is obtained with SpDust, as described by Silsbee et al., that we have
coupled to DustEM. We carry out full radiative transfer simulations and
carefully estimate the local gas state as a function of position within
interstellar clouds. We show that the spinning dust emission is sensitive to
the abundances of the major ions and we propose a simple scheme to estimate
these abundances. We also investigate the effect of changing the cosmic-ray
rate. In dense media, where radiative transfer is mandatory, we show that the
relationship between the spinning and mid-IR emissivities of PAHs is no longer
linear and that the spinning dust emission may actually be strong at the centre
of clouds where the mid-IR PAH emission is weak. These results provide new ways
to trace grain growth from diffuse to dense medium and will be useful for the
analysis of AME at the scale of interstellar clouds.Comment: 7 pages, 10 figures, accepted by A&
Dust processing in photodissociation regions - Mid-IR emission modelling
Mid-infrared spectroscopy of dense illuminated ridges (or photodissociation
regions, PDRs) suggests dust evolution. Such evolution must be reflected in the
gas physical properties through processes like photo-electric heating or H_2
formation. With Spitzer Infrared Spectrograph (IRS) and ISOCAM data, we study
the mid-IR emission of closeby, well known PDRs. Focusing on the band and
continuum dust emissions, we follow their relative contributions and analyze
their variations in terms of abundance of dust populations. In order to
disentangle dust evolution and excitation effects, we use a dust emission model
that we couple to radiative transfer. Our dust model reproduces extinction and
emission of the standard interstellar medium that we represent with diffuse
high galactic latitude clouds called Cirrus. We take the properties of dust in
Cirrus as a reference to which we compare the dust emission from more excited
regions, namely the Horsehead and the reflection nebula NGC 2023 North. We show
that in both regions, radiative transfer effects cannot account for the
observed spectral variations. We interpret these variations in term of changes
of the relative abundance between polycyclic aromatic hydrocarbons (PAHs,
mid-IR band carriers) and very small grains (VSGs, mid-IR continuum carriers).
We conclude that the PAH/VSG abundance ratio is 2.4 times smaller at the peak
emission of the Horsehead nebula than in the Cirrus case. For NGC2023 North
where spectral evolution is observed across the northern PDR, we conclude that
this ratio is ~5 times lower in the dense, cold zones of the PDR than in its
diffuse illuminated part where dust properties seem to be the same as in
Cirrus. We conclude that dust in PDRs seems to evolve from "dense" to "diffuse"
properties at the small spatial scale of the dense illuminated ridge.Comment: 11 pages, 11 figures, accepted for publication in A&
The global dust SED: Tracing the nature and evolution of dust with DustEM
The Planck and Herschel missions are currently measuring the farIR-mm
emission of dust, which combined with existing IR data, will for the first time
provide the full SED of the galactic ISM dust emission with an unprecedented
sensitivity and angular resolution. It will allow a systematic study of the
dust evolution processes that affect the SED. Here we present a versatile
numerical tool, DustEM, that predicts the emission and extinction of dust given
their size distribution and their optical and thermal properties. In order to
model dust evolution, DustEM has been designed to deal with a variety of grain
types, structures and size distributions and to be able to easily include new
dust physics. We use DustEM to model the dust SED and extinction in the diffuse
interstellar medium at high-galactic latitude (DHGL), a natural reference SED.
We present a coherent set of observations for the DHGL SED. The dust components
in our DHGL model are (i) PAHs, (ii) amorphous carbon and (iii) amorphous
silicates. We use amorphous carbon dust, rather than graphite, because it
better explains the observed high abundances of gas-phase carbon in shocked
regions of the interstellar medium. Using the DustEM model, we illustrate how,
in the optically thin limit, the IRAS/Planck HFI (and likewise Spitzer/Herschel
for smaller spatial scales) photometric band ratios of the dust SED can
disentangle the influence of the exciting radiation field intensity and
constrain the abundance of small grains relative to the larger grains. We also
discuss the contributions of the different grain populations to the IRAS,
Planck and Herschel channels. Such information is required to enable a study of
the evolution of dust as well as to systematically extract the dust thermal
emission from CMB data and to analyze the emission in the Planck polarized
channels. The DustEM code described in this paper is publically available.Comment: accepted for publication in A&
Excitation of H in photodissociation regions as seen by Spitzer
We present spectroscopic observations obtained with the infrared Spitzer
Space Telescope, which provide insight into the H physics and gas
energetics in photodissociation Regions (PDRs) of low to moderate
far-ultraviolet (FUV) fields and densities. We analyze data on six well known
Galactic PDRs (L1721, California, N7023E, Horsehead, rho Oph, N2023N), sampling
a poorly explored range of excitation conditions (), relevant
to the bulk of molecular clouds in galaxies. Spitzer observations of H
rotational lines are complemented with H data, including ro-vibrational
line measurements, obtained with ground-based telescopes and ISO, to constrain
the relative contributions of ultraviolet pumping and collisions to the H
excitation. The data analysis is supported by model calculations with the
Meudon PDR code. The observed column densities of rotationally excited H
are observed to be much higher than PDR model predictions. In the lowest
excitation PDRs, the discrepancy between the model and the data is about one
order of magnitude for rotational levels 3. We discuss whether an
enhancement in the H formation rate or a local increase in photoelectric
heating, as proposed for brighter PDRs in former ISO studies, may improve the
data-model comparison. We find that an enhancement in the H formation rates
reduces the discrepancy, but the models still fall short of the data. This
large disagreement suggests that our understanding of the formation and
excitation of H and/or of PDRs energetics is still incomplete. We discuss
several explanations, which could be further tested using the Herschel Space
TelescopeComment: A&A in pres
UV-driven chemistry in simulations of the interstellar medium. I. Post-processed chemistry with the Meudon PDR code
Our main purpose is to estimate the effect of assuming uniform density on the
line-of-sight in PDR chemistry models, compared to a more realistic
distribution for which total gas densities may well vary by several orders of
magnitude. A secondary goal of this paper is to estimate the amount of
molecular hydrogen which is not properly traced by the CO (J = 1 -> 0) line,
the so-called "dark molecular gas". We use results from a magnetohydrodynamical
(MHD) simulation as a model for the density structures found in a turbulent
diffuse ISM with no star-formation activity. The Meudon PDR code is then
applied to a number of lines of sight through this model, to derive their
chemical structures. It is found that, compared to the uniform density
assumption, maximal chemical abundances for H2, CO, CH and CN are increased by
a factor 2 to 4 when taking into account density fluctuations on the line of
sight. The correlations between column densities of CO, CH and CN with respect
to those of H2 are also found to be in better overall agreement with
observations. For instance, at N(H2) > 2.10^{20} cm-2, while observations
suggest that d[log N(CO)]=d[log N(H2)] = 3.07 +/- 0.73, we find d[log
N(CO)]=d[log N(H2)] =14 when assuming uniform density, and d[log N(CO)]=d[log
N(H2)] = 5.2 when including density fluctuations.Comment: 14 pages, 16 figures, accepted for publication in Astronomy &
Astrophysic
Physical structure of the photodissociation regions in NGC 7023: Observations of gas and dust emission with <i>Herschel</i>
The determination of the physical conditions in molecular clouds is a key step towards our understanding of their formation and evolution of associated star formation. We investigate the density, temperature, and column density of both dust and gas in the photodissociation regions (PDRs) located at the interface between the atomic and cold molecular gas of the NGC 7023 reflection nebula. We study how young stars affect the gas and dust in their environment. Our approach combining both dust and gas delivers strong constraints on the physical conditions of the PDRs. We find dense and warm molecular gas of high column density in the PDRs
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