Your search keyword '"Rémy-Ruyer, Aurélie"' showing total 2 results

1. High-resolution, 3D radiative transfer modeling I. The grand-design spiral galaxy M51.

Author

Fritz, Jacopo, Baes, Maarten, Camps, Peter, De Geyter, Gert, Hughes, Thomas M., Viaene, Sebastien, De Looze, Ilse, Jones, Anthony P., Rémy-Ruyer, Aurélie, Karczewski, Oskar Ł., Lebouteiller, Vianney, Madden, Suzanne C., Nanyao Lu, Luigi Spinoglio, Wilson, Christine D., Boquien, Médéric, Bendo, George J., Cortese, Luca, Boselli, Alessandro, and Cooray, Asantha

Subjects

*STELLAR radiation, *SPIRAL galaxies, *THERMODYNAMIC equilibrium, *SPECTRAL energy distribution, *ATTENUATION (Physics)

Abstract

Context. Dust reprocesses about half of the stellar radiation in galaxies. The thermal re-emission by dust of absorbed energy is considered to be driven merely by young stars so is often applied to tracing the star formation rate in galaxies. Recent studies have argued that the old stellar population might be responsible for a non-negligible fraction of the radiative dust heating. Aims. In this work, we aim to analyze the contribution of young (≲100 Myr) and old (~10 Gyr) stellar populations to radiative dust heating processes in the nearby grand-design spiral galaxy M51 using radiative transfer modeling. High-resolution 3D radiative transfer (RT) models are required to describe the complex morphologies of asymmetric spiral arms and clumpy star-forming regions and to model the propagation of light through a dusty medium. Methods. In this paper, we present a new technique developed to model the radiative transfer effects in nearby face-on galaxies. We construct a high-resolution 3D radiative transfer model with the Monte-Carlo code SKIRT to account for the absorption, scattering, and non-local thermal equilibrium (NLTE) emission of dust in M51. The 3D distribution of stars is derived from the 2D morphology observed in the IRAC 3.6 μm, GALEX FUV, Hμα and MIPS 24 μm wavebands, assuming an exponential vertical distribution with an appropriate scale height. The dust geometry is constrained through the far-ultraviolet (FUV) attenuation, which is derived from the observed total-infrared-to-far-ultraviolet luminosity ratio. The stellar luminosity, star formation rate, and dust mass have been scaled to reproduce the observed stellar spectral energy distribution (SED), FUV attenuation, and infrared SED. Results. The dust emission derived from RT calculations is consistent with far-infrared and submillimeter observations of M51, implying that the absorbed stellar energy is balanced by the thermal re-emission of dust. The young stars provide 63% of the energy for heating the dust responsible for the total infrared emission (8-1000 μm), while 37% of the dust emission is governed through heating by the evolved stellar population. In individual wavebands, the contribution from young stars to the dust heating dominates at all infrared wavebands but gradually decreases towards longer infrared and submillimeter wavebands for which the old stellar population becomes a non-negligible source of heating. Upon extrapolation of the results for M51, we present prescriptions for estimating the contribution of young stars to the global dust heating based on a tight correlation between the dust heating fraction and specific star formation rate. [ABSTRACT FROM AUTHOR]

Published

2014

2. HERSCHEL-SPIRE FOURIER TRANSFORM SPECTROMETER OBSERVATIONS OF EXCITED CO AND [C I] IN THE ANTENNAE (NGC 4038/39): WARM AND COLD MOLECULAR GAS Herschel is an ESA space observatory with science instruments provided by European-led Principal Investigator consortia and with important participation from NASA.

Author

Schirm, Maximilien R. P., Wilson, Christine D., Parkin, Tara J., Kamenetzky, Julia, Glenn, Jason, Rangwala, Naseem, Spinoglio, Luigi, Pereira-Santaella, Miguel, Baes, Maarten, Barlow, Michael J., Clements, Dave L., Cooray, Asantha, Looze, Ilse De, Karczewski, Oskar Ł., Madden, Suzanne C., Rémy-Ruyer, Aurélie, and Wu, Ronin

Subjects

*FOURIER transform spectroscopy, *PHOTODETECTORS, *THERMODYNAMIC equilibrium, *SPIRAL galaxies, *RADIATIVE transfer, *CARBON monoxide spectra, *GALAXY mergers, *MOLECULAR clouds

Abstract

We present Herschel Spectral and Photometric Imaging Receiver (SPIRE) Fourier Transform Spectrometer (FTS) observations of the Antennae (NGC 4038/39), a well-studied, nearby (22 Mpc), ongoing merger between two gas-rich spiral galaxies. The SPIRE-FTS is a low spatial ( FWHM ∼ 19″-43″) and spectral (∼1.2 GHz) resolution mapping spectrometer covering a large spectral range (194-671 μm, 450-1545 GHz). We detect five CO transitions (J = 4-3 to J = 8-7), both [C I] transitions, and the [N II] 205 μm transition across the entire system, which we supplement with ground-based observations of the CO J = 1-0, J = 2-1, and J = 3-2 transitions and Herschel Photodetecting Array Camera and Spectrometer (PACS) observations of [C II] and [O I] 63 μm. Using the CO and [C I] transitions, we perform both a local thermodynamic equilibrium (LTE) analysis of [C I] and a non-LTE radiative transfer analysis of CO and [C I] using the radiative transfer code RADEX along with a Bayesian likelihood analysis. We find that there are two components to the molecular gas: a cold (Tkin ∼ 10-30 K) and a warm (Tkin ≳ 100 K) component. By comparing the warm gas mass to previously observed values, we determine a CO abundance in the warm gas of xCO ∼ 5 × 10–5. If the CO abundance is the same in the warm and cold gas phases, this abundance corresponds to a CO J = 1-0 luminosity-to-mass conversion factor of αCO ∼ 7 M☼ pc–2 (K km s–1)–1 in the cold component, similar to the value for normal spiral galaxies. We estimate the cooling from H2, [C II], CO, and [O I] 63 μm to be ∼0.01 L☼/M☼. We compare photon-dominated region models to the ratio of the flux of various CO transitions, along with the ratio of the CO flux to the far-infrared flux in NGC 4038, NGC 4039, and the overlap region. We find that the densities recovered from our non-LTE analysis are consistent with a background far-ultraviolet field of strength G0 ∼ 1000. Finally, we find that a combination of turbulent heating, due to the ongoing merger, and supernova and stellar winds are sufficient to heat the molecular gas. [ABSTRACT FROM AUTHOR]

Published

2014