14 research outputs found
Infrared view of the multiphase ISM in NGC 253 II. Modelling the ionised and neutral atomic gas
Context. Multi-wavelength studies of galaxies and galactic nuclei allow us to
build a relatively more complete picture of the interstellar medium (ISM),
especially in the dusty regions of starburst galaxies. An understanding of the
physical processes in nearby galaxies can assist in the study of more distant
sources at higher redshifts, which cannot be resolved. Aims. We aimed to use
observations presented in the first part of this series of papers to model the
physical conditions of the ISM in the nuclear region of NGC 253, in order to
obtain primary parameters such as gas densities and metallicities. From the
created model we further calculated secondary parameters such as gas masses of
the different phases, and estimated the fraction of [C II] 158 um from the
different phases, which allowed us to probe the nuclear star-formation rate.
Methods. To compare theory with our observations we used MULTIGRIS, a
probabilistic tool that determines probabilities for certain ISM parameters
from a grid of Cloudy models together with a set of spectroscopic lines.
Results. We find that the hypothetical active galactic nucleus within NGC 253
has only a minor impact compared to the starburst on the heating of the ISM as
probed by the observed lines. We characterise the ISM and obtain parameters
such as a solar metallicity, a mean density of ~230cm-3 , an ionisation
parameter of log U = -3, and an age of the nuclear cluster of ~2 Myr.
Furthermore, we estimate the masses of the ionised (3.8 x 10^6 M_sol ), neutral
atomic (9.1 x 10^6 M_sol ), and molecular (2.0 x 10^8 M_sol ) gas phases as
well as the dust mass (1.8 x 10^6 M_sol ) in the nucleus of NGC 253.Comment: Accepted for publication in A&A; 15 pages, 10 Figures, 6 Table
APEX-CHAMP+ high-J CO observations of low-mass young stellar objects: IV. Mechanical and radiative feedback
During the embedded stage of star formation, bipolar molecular outflows and
UV radiation from the protostar are important feedback processes. Our aim is to
quantify the feedback, mechanical and radiative, for a large sample of low-mass
sources. The outflow activity is compared to radiative feedback in the form of
UV heating by the accreting protostar to search for correlations and
evolutionary trends. Large-scale maps of 26 young stellar objects, which are
part of the Herschel WISH key program are obtained using the CHAMP+ instrument
on the APEX (12CO and 13CO 6-5), and the HARP-B instrument on the JCMT (12CO
and 13CO 3-2). Maps are used to determine outflow parameters and envelope
models are used to quantify the amount of UV-heated gas and its temperature
from 13CO 6-5 observations. All sources in our sample show outflow activity and
the outflow force, F_CO, is larger for Class 0 sources than for Class I
sources, even if their luminosities are comparable. The outflowing gas
typically extends to much greater distances than the power-law envelope and
therefore influences the surrounding cloud material directly. Comparison of the
CO 6-5 results with Herschel-HIFI H2O and PACS high-J CO lines, both tracing
currently shocked gas, shows that the two components are linked, even though
the transitions do not probe the same gas. The link does not extend down to CO
3-2. The conclusion is that CO 6-5 depends on the shock characteristics
(density and velocity), whereas CO 3-2 is more sensitive to conditions in the
surrounding environment (density). The radiative feedback is responsible for
increasing the gas temperature by a factor of two, up to 30-50 K, on scales of
a few thousand AU, particularly along the direction of the outflow. The mass of
the UV heated gas exceeds the mass contained in the entrained outflow in the
inner ~3000 AU and is therefore at least as important on small scales.Comment: 30 pages with Appendix, Accepted by Astronomy & Astrophysic
First Sagittarius A* Event Horizon Telescope results. II. EHT and multiwavelength observations, data processing, and calibration
We present Event Horizon Telescope (EHT) 1.3 mm measurements of the radio source located at the position of the supermassive black hole Sagittarius A* (Sgr A*), collected during the 2017 April 5–11 campaign. The observations were carried out with eight facilities at six locations across the globe. Novel calibration methods are employed to account for Sgr A*'s flux variability. The majority of the 1.3 mm emission arises from horizon scales, where intrinsic structural source variability is detected on timescales of minutes to hours. The effects of interstellar scattering on the image and its variability are found to be subdominant to intrinsic source structure. The calibrated visibility amplitudes, particularly the locations of the visibility minima, are broadly consistent with a blurred ring with a diameter of ∼50 μas, as determined in later works in this series. Contemporaneous multiwavelength monitoring of Sgr A* was performed at 22, 43, and 86 GHz and at near-infrared and X-ray wavelengths. Several X-ray flares from Sgr A* are detected by Chandra, one at low significance jointly with Swift on 2017 April 7 and the other at higher significance jointly with NuSTAR on 2017 April 11. The brighter April 11 flare is not observed simultaneously by the EHT but is followed by a significant increase in millimeter flux variability immediately after the X-ray outburst, indicating a likely connection in the emission physics near the event horizon. We compare Sgr A*'s broadband flux during the EHT campaign to its historical spectral energy distribution and find that both the quiescent emission and flare emission are consistent with its long-term behavior.http://iopscience.iop.org/2041-8205Physic
First Sagittarius A* Event Horizon Telescope Results. II. EHT and Multiwavelength Observations, Data Processing, and Calibration
We present Event Horizon Telescope (EHT) 1.3 mm measurements of the radio source located at the position of the supermassive black hole Sagittarius A* (Sgr A*), collected during the 2017 April 5–11 campaign. The observations were carried out with eight facilities at six locations across the globe. Novel calibration methods are employed to account for Sgr A*'s flux variability. The majority of the 1.3 mm emission arises from horizon scales, where intrinsic structural source variability is detected on timescales of minutes to hours. The effects of interstellar scattering on the image and its variability are found to be subdominant to intrinsic source structure. The calibrated visibility amplitudes, particularly the locations of the visibility minima, are broadly consistent with a blurred ring with a diameter of ∼50 μas, as determined in later works in this series. Contemporaneous multiwavelength monitoring of Sgr A* was performed at 22, 43, and 86 GHz and at near-infrared and X-ray wavelengths. Several X-ray flares from Sgr A* are detected by Chandra, one at low significance jointly with Swift on 2017 April 7 and the other at higher significance jointly with NuSTAR on 2017 April 11. The brighter April 11 flare is not observed simultaneously by the EHT but is followed by a significant increase in millimeter flux variability immediately after the X-ray outburst, indicating a likely connection in the emission physics near the event horizon. We compare Sgr A*’s broadband flux during the EHT campaign to its historical spectral energy distribution and find that both the quiescent emission and flare emission are consistent with its long-term behavior
Chemical fingerprints of star forming regions and active galaxies
This thesis is devoted to the study of the physical conditions of the interstellar medium (ISM) in active galactic nuclei (AGNs) and Galactic star-forming regions, using mostly single-dish millimeter observations.
I first study the excitation conditions of dense gas in a group of Seyfert galaxies using radiative transfer models (Chapter 2). I then study the galaxy NGC 1068, and try to distinguish signatures of the contributions from the AGN and the starburst ring by incorporating observations of high-J transitions of dense gas tracers (Chapter 3).
Later, I venture into the mid-infrared spectral region to study different aspects of the AGN and starburst components in the galaxy NGC 4945 (Chapter 4). In Chapter 5 I delve into theoretical aspects of the dynamical evolution of gas in an AGN torus. I use a 3D hydrodynamic simulation with chemical abundances driven by X-rays. The aim is to understand the effects of X-ray irradiation by the AGN on the temperature, formation and destruction of the molecular gas. I finally explore a Galactic star-forming region, the Omega Nebula, with high resolution single dish observations, to study the properties of the warm gas and to constrain chemical models (Chapters 6 and 7).
Infrared view of the multiphase ISM in NGC 253: I. Observations and fundamental parameters of the ionised gas
12 pages, 10 Figures, 6 Tables. Accepted for publication in A&AInternational audienceContext. Massive star-formation leads to enrichment with heavy elements of the interstellar medium. On the other hand, the abundance of heavy elements is a key parameter to study the star-formation history of galaxies. Furthermore, the total molecular hydrogen mass, usually determined by converting CO or [C ii] 158 m luminosities, depends on the metallicity as well. The excitation of metallicity-sensitive emission lines, however, depends on the gas density of H ii regions, where they arise. Aims. We used spectroscopic observations from SOFIA, Herschel, and Spitzer of the nuclear region of the starburst galaxy NGC 253, as well as photometric observations from GALEX, 2MASS, Spitzer, and Herschel in order to derive physical properties such as the optical depth to correct for extinction, as well as the gas density and metallicity of the central region. Methods. Ratios of the integrated line fluxes of several species were utilised to derive the gas density and metallicity. The [O iii] along with the [S iii] and [N ii] line flux ratios for example, are sensitive to the gas density but nearly independent of the local temperature. As these line ratios trace different gas densities and ionisation states, we examined if these lines may originate from different regions within the observing beam. The ([Ne ii] 13 m + [Ne iii] 16 m)/Hu line flux ratio on the other hand, is independent of the depletion onto dust grains but sensitive to the Ne/H abundance ratio and will be used as a tracer for metallicity of the gas. Results. We derived values for gas phase abundances of the most important species, as well as estimates for the optical depth and the gas density of the ionised gas in the nuclear region of NGC 253. We obtained densities of at least two different ionised components cm and cm and a metallicity of solar value
Infrared view of the multiphase ISM in NGC 253: I. Observations and fundamental parameters of the ionised gas
12 pages, 10 Figures, 6 Tables. Accepted for publication in A&AInternational audienceContext. Massive star-formation leads to enrichment with heavy elements of the interstellar medium. On the other hand, the abundance of heavy elements is a key parameter to study the star-formation history of galaxies. Furthermore, the total molecular hydrogen mass, usually determined by converting CO or [C ii] 158 m luminosities, depends on the metallicity as well. The excitation of metallicity-sensitive emission lines, however, depends on the gas density of H ii regions, where they arise. Aims. We used spectroscopic observations from SOFIA, Herschel, and Spitzer of the nuclear region of the starburst galaxy NGC 253, as well as photometric observations from GALEX, 2MASS, Spitzer, and Herschel in order to derive physical properties such as the optical depth to correct for extinction, as well as the gas density and metallicity of the central region. Methods. Ratios of the integrated line fluxes of several species were utilised to derive the gas density and metallicity. The [O iii] along with the [S iii] and [N ii] line flux ratios for example, are sensitive to the gas density but nearly independent of the local temperature. As these line ratios trace different gas densities and ionisation states, we examined if these lines may originate from different regions within the observing beam. The ([Ne ii] 13 m + [Ne iii] 16 m)/Hu line flux ratio on the other hand, is independent of the depletion onto dust grains but sensitive to the Ne/H abundance ratio and will be used as a tracer for metallicity of the gas. Results. We derived values for gas phase abundances of the most important species, as well as estimates for the optical depth and the gas density of the ionised gas in the nuclear region of NGC 253. We obtained densities of at least two different ionised components cm and cm and a metallicity of solar value
Infrared view of the multiphase ISM in NGC 253 II. Modelling the ionised and neutral atomic gas
International audienceContext. Multi-wavelength studies of galaxies and galactic nuclei allow us to build a relatively more complete picture of the interstellar medium (ISM), especially in the dusty regions of starburst galaxies. An understanding of the physical processes in nearby galaxies can assist in the study of more distant sources at higher redshifts, which cannot be resolved. Aims. We aimed to use observations presented in the first part of this series of papers to model the physical conditions of the ISM in the nuclear region of NGC 253, in order to obtain primary parameters such as gas densities and metallicities. From the created model we further calculated secondary parameters such as gas masses of the different phases, and estimated the fraction of [C II] 158 um from the different phases, which allowed us to probe the nuclear star-formation rate. Methods. To compare theory with our observations we used MULTIGRIS, a probabilistic tool that determines probabilities for certain ISM parameters from a grid of Cloudy models together with a set of spectroscopic lines. Results. We find that the hypothetical active galactic nucleus within NGC 253 has only a minor impact compared to the starburst on the heating of the ISM as probed by the observed lines. We characterise the ISM and obtain parameters such as a solar metallicity, a mean density of ~230cm-3 , an ionisation parameter of log U = -3, and an age of the nuclear cluster of ~2 Myr. Furthermore, we estimate the masses of the ionised (3.8 x 10^6 M_sol ), neutral atomic (9.1 x 10^6 M_sol ), and molecular (2.0 x 10^8 M_sol ) gas phases as well as the dust mass (1.8 x 10^6 M_sol ) in the nucleus of NGC 253