TY - JOUR
T1 - The Survey of Lines in M31 (SLIM)
T2 - The Drivers of the [C II]/TIR Variation
AU - Kapala, Maria J.
AU - Groves, Brent
AU - Sandstrom, Karin
AU - Jarrett, Thomas
AU - Cunha, Elisabete Da
AU - Croxall, Kevin
AU - Dalcanton, Julianne
AU - Draine, Bruce
AU - Glover, Simon
AU - Schinnerer, Eva
N1 - Publisher Copyright:
© 2017. The American Astronomical Society. All rights reserved..
PY - 2017/6/20
Y1 - 2017/6/20
N2 - The ratio of the [C ii] emission line over the total infrared emission (TIR) is often used as a proxy for the photoelectric (PE) heating efficiency (ϵPE) of the far-ultraviolet (FUV) photons absorbed by dust in the interstellar medium. In the nearby galaxy M31, we measure a strong radial variation of [C ii]/TIR that we rule out as being due to an intrinsic variation in ϵPE. [C ii]/TIR fails as a proxy for ϵPE, because the TIR measures all dust heating, not just the contribution from FUV photons capable of ejecting electrons from dust grains. Using extensive multi-wavelength coverage from the FUV to far-infrared, we infer the attenuated FUV emission (UVatt), and the total attenuated flux (TOTatt). We find [C ii]/TIR to be strongly correlated with /, indicating that, in M31 at least, one of the dominant drivers for [C ii]/TIR variation is the relative hardness of the absorbed stellar radiation field. We define ϵPE UV, [C ii]/UVatt which should be more closely related to the actual PE efficiency, which we find to be essentially constant () in all explored fields in M31. This suggests that part of the observed variation of [C ii]/TIR in other galaxies is likely due to a change in the relative hardness of the absorbed stellar radiation field, caused by a combination of variations in the stellar population, dust opacity, and galaxy metallicity, though PE efficiency may also vary across a wider range of environments.
AB - The ratio of the [C ii] emission line over the total infrared emission (TIR) is often used as a proxy for the photoelectric (PE) heating efficiency (ϵPE) of the far-ultraviolet (FUV) photons absorbed by dust in the interstellar medium. In the nearby galaxy M31, we measure a strong radial variation of [C ii]/TIR that we rule out as being due to an intrinsic variation in ϵPE. [C ii]/TIR fails as a proxy for ϵPE, because the TIR measures all dust heating, not just the contribution from FUV photons capable of ejecting electrons from dust grains. Using extensive multi-wavelength coverage from the FUV to far-infrared, we infer the attenuated FUV emission (UVatt), and the total attenuated flux (TOTatt). We find [C ii]/TIR to be strongly correlated with /, indicating that, in M31 at least, one of the dominant drivers for [C ii]/TIR variation is the relative hardness of the absorbed stellar radiation field. We define ϵPE UV, [C ii]/UVatt which should be more closely related to the actual PE efficiency, which we find to be essentially constant () in all explored fields in M31. This suggests that part of the observed variation of [C ii]/TIR in other galaxies is likely due to a change in the relative hardness of the absorbed stellar radiation field, caused by a combination of variations in the stellar population, dust opacity, and galaxy metallicity, though PE efficiency may also vary across a wider range of environments.
KW - ISM: lines and bands
KW - dust, extinction
KW - galaxies: ISM
KW - galaxies: photometry
KW - methods: data Analysis
KW - techniques: imaging spectroscopy
UR - http://www.scopus.com/inward/record.url?scp=85021340272&partnerID=8YFLogxK
U2 - 10.3847/1538-4357/aa7265
DO - 10.3847/1538-4357/aa7265
M3 - Article
SN - 0004-637X
VL - 842
JO - Astrophysical Journal
JF - Astrophysical Journal
IS - 2
M1 - 128
ER -