Andromeda's Dust
B.T. Draine, G. Aniano, Oliver Krause, Brent Groves, Karin Sandstrom,, Robert Braun, Adam Leroy, Ulrich Klaas, Hendrik Linz, Hans-Walter Rix, Eva, Schinnerer, Anika Schmiedeke, Fabian Walter
TL;DR
This study uses infrared observations and a dust model to map dust properties across M31, revealing variations in dust mass, composition, and heating, and highlighting discrepancies in dust opacity at certain radii.
Contribution
It provides detailed spatial maps of dust characteristics in M31 using combined observational data and physical modeling, improving understanding of galactic dust distribution and properties.
Findings
Dust mass is 5.4x10^7 solar masses.
Dust-to-gas ratio varies from 0.026 at center to 0.0027 at 25kpc.
PAH abundance peaks at 11.2kpc.
Abstract
Spitzer Space Telescope and Herschel Space Observatory imaging of M31 is used, with a physical dust model, to construct maps of dust surface density, dust-to-gas ratio, starlight heating intensity, and PAH abundance, out to R=25kpc. The global dust mass is M_d=5.4x10^7Msol, the global dust/H mass ratio is M_d/M_H=0.0081, and the global PAH abundance is <q_PAH>=0.039. The dust surface density has an inner ring at R=5.6kpc, a maximum at R=11.2kpc, and an outer ring at R=15.1kpc. The dust/gas ratio varies from M_d/M_H=0.026 at the center to ~0.0027 at R=25kpc. From the dust/gas ratio, we estimate the ISM metallicity to vary by a factor ~10, from Z/Zsol=3 at R=0 to ~0.3 at R=25kpc. The dust heating rate parameter <U> peaks at the center, with <U> approx 35, declining to <U> approx 0.25 at R=20kpc. Within the central kpc, the starlight heating intensity inferred from the dust modeling is…
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