The Survey of Lines in M31 (Slim): Investigating the Origins of [C Ii] Emission

Kapala, Maria; Sandström, Karin; Groves, Brent; Croxall, K. V.; Kreckel, Kathryn; Dalcanton, Julianne J.; Leroy, Adam K.; Schinnerer, E.; Walter, Fabian; Fouesneau, M.

doi:10.1088/0004-637x/798/1/24

Cited by 35 publications

(71 citation statements)

References 93 publications

(142 reference statements)

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“…Since the ionization potential of O + is 35.1 eV, [O III] is seen in hot diffuse ionized gas (e.g., Hii regions or the hot ionized medium), where the transition is easily excited (n cr ∼ 5.1 × 10 2 cm −3 and E u /k B ∼ 163 K). Although they trace different ISM phases, all three fine-structure lines have been proposed as tracers of the star formation rate (SFR) of galaxies (Kapala et al 2015;Herrera-Camus et al 2015). For example, De Looze et al (2014) found the line emissions to correlate with the SFRs for a sample of local and high-z starburst galaxies.…”

Section: Introductionmentioning

confidence: 99%

SÍGAME Simulations of the , , and Line Emission from Star-forming Galaxies at

Olsen

Greve

Narayanan

et al. 2017

ApJ

103

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Of the almost 40 star forming galaxies at z > ∼ 5 (not counting QSOs) observed in [C II] to date, nearly half are either very faint in [C II], or not detected at all, and fall well below expectations based on locally derived relations between star formation rate and [C II] luminosity. This has raised questions as to how reliable [C II] is as a tracer of star formation activity at these epochs and how factors such as metallicity might affect the [C II] emission. Combining cosmological zoom simulations of galaxies with SÍGAME (SImulator of GAlaxy Millimeter/submillimeter Emission) we have modeled the multi-phased interstellar medium ( We find that the [C II] emission is dominated by the diffuse ionized gas phase and molecular clouds, which on average contribute ∼ 66% and ∼ 27%, respectively. The molecular gas, which constitutes only ∼ 10% of the total gas mass is thus a more efficient emitter of [C II] than the ionized gas, which makes up ∼ 85% of the total gas mass. A principal component analysis shows that the [C II] luminosity correlates with the star formation activity of a galaxy as well as its average metallicity. The low metallicities of our simulations together with their low molecular gas mass fractions can account for their [C II]-faintness, and we suggest these factors may also be responsible for the [C II]-faint normal galaxies observed at these early epochs.

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Section: Introductionmentioning

confidence: 99%

SÍGAME Simulations of the , , and Line Emission from Star-forming Galaxies at

Olsen

Greve

Narayanan

et al. 2017

ApJ

103

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“…Maps of luminous infrared galaxies resolved at 24 μm from GOALS (Armus et al 2009) were convolved to match the 160 μm resolution using the convolution kernel methodology of Aniano et al (2011). To minimize any possible effects of starlight contamination at shorter wavelengths (see, e.g., Kapala et al 2015), the calibration of total infrared (TIR, 3-1100 μm) luminosity was performed utilizing 70, 100, and 160 μm photometry, which closely tracks full-SED integrated TIR luminosity (Galametz et al 2013). …”

Section: Ancillary Datamentioning

confidence: 99%

The Spatially Resolved Cooling Line Deficit in Galaxies

Smith

Croxall

Draine

et al. 2016

ApJ

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We present [C II] 158 μm measurements from over 15,000 resolved regions within 54 nearby galaxies of the KINGFISH program to investigate the so-called [C II] "line-cooling deficit" long known to occur in galaxies with different luminosities. The [C II]/TIR ratio ranges from above 1% to below 0.1% in the sample, with a mean value of 0.48±0.21%. We find that the surface density of 24 μm emission dominates this trend, with [C II]/TIR dropping as n m n I 24 m ( )increases. Deviations from this overall decline are correlated with changes in the gas-phase metal abundance, with higher metallicity associated with deeper deficits at a fixed surface brightness. We supplement the local sample with resolved [C II] measurements from nearby luminous infrared galaxies and highredshift sources from z=1.8-6.4, and find that star formation rate density drives a continuous trend of deepening [C II] deficit across six orders of magnitude in S SFR . The tightness of this correlation suggests that an approximate S SFR can be estimated directly from global measurements of [C II]/TIR, and a relation is provided to do so. Several low-luminosity active galactic nucleus (AGN) hosts in the sample show additional and significant central suppression of [C II]/TIR, but these deficit enhancements occur not in those AGNs with the highest X-ray luminosities, but instead those with the highest central starlight intensities. Taken together, these results demonstrate that the [C II] line-cooling line deficit in galaxies likely arises from local physical phenomena in interstellar gas.

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“…The fields and data are also used by Kapala et al (2015) to trace the origin of [CII] line emission, as part of the Survey of Lines in M31 (SLIM, PI Sandstrom K.). The positions of the five fields are shown in Fig.…”

Section: Datamentioning

confidence: 99%

Attenuation Modified by DIG and Dust as Seen in M31

Tomičić

Kreckel

Groves

et al. 2017

ApJ

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The spatial distribution of dust in galaxies affects the global attenuation, and hence inferred properties, of galaxies. We trace the spatial distribution of dust in five fields (at 0.6-0.9 kpc scale) of M31 by comparing optical attenuation with the total dust mass distribution. We measure the attenuation from the Balmer decrement using Integral Field Spectroscopy and the dust mass from Herschel far-IR observations. Our results show that M31's dust attenuation closely follows a foreground screen model, contrary to what was previously found in other nearby galaxies. By smoothing the M31 data we find that spatial resolution is not the cause for this difference. Based on the emission line ratios and two simple models, we conclude that previous models of dust/gas geometry need to include a weakly or non-attenuated diffuse ionized gas (DIG) component. Due to the variation of dust and DIG scale heights with galactic radius, we conclude that different locations in galaxies will have different vertical distributions of gas and dust and therefore different measured attenuation. The difference between our result in M31 with that found in other nearby galaxies can be explained by our fields in M31 lying at larger galactic radii than the previous studies that focused on the centers of galaxies.

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The Survey of Lines in M31 (Slim): Investigating the Origins of [C Ii] Emission

Cited by 35 publications

References 93 publications

SÍGAME Simulations of the , , and Line Emission from Star-forming Galaxies at

SÍGAME Simulations of the , , and Line Emission from Star-forming Galaxies at

The Spatially Resolved Cooling Line Deficit in Galaxies

Attenuation Modified by DIG and Dust as Seen in M31

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