Far‐Infrared Spectroscopy of Normal Galaxies: Physical Conditions in the Interstellar Medium

Malhotra, Sangeeta; Kaufman, Michael J.; Hollenbach, D. J.; Hélou, G.; Rubin, R. H.; Brauher, J.; Dale, Daniel A.; Lu, N.; Lord, S. D.; Stacey, G. J.; Contursi, A.; Hunter, Deidre A.; Dinerstein, H. L.

doi:10.1086/323046

Cited by 397 publications

(836 citation statements)

References 65 publications

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“…The theoretical model of varying a CO by Wolfire et al (2010), assuming H 2 column density of 10 22 cm −2 in a molecular cloud, agrees well with observational results based on dust-mass at low metallicity (Leroy et al 2011;Sandstrom et al 2013). Adopting a solar metallicity value of 8.66 and heating rate/H atom ( ) G n log 0 = −0.3 (from the L L OI FIR studies of Malhotra et al 2001), the Wolfire et al (2010) model also agrees well with our H 2 rotational emission modeled masses.…”

Section: Molecular Gas Mass Using Our Modelsupporting

confidence: 80%

LIGHTING THE DARK MOLECULAR GAS: H₂ AS A DIRECT TRACER

Togi

Smith

2016

ApJ

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Robust knowledge of molecular gas mass is critical for understanding star formation in galaxies. The H 2 molecule does not emit efficiently in the cold interstellar medium, hence the molecular gas content of galaxies is typically inferred using indirect tracers. At low metallicity and in other extreme environments, these tracers can be subject to substantial biases. We present a new method of estimating total molecular gas mass in galaxies directly from pure mid-infrared rotational H 2 emission. By assuming a power-law distribution of H 2 rotational temperatures, we can accurately model H 2 excitation and reliably obtain warm (T100 K) H 2 gas masses by varying only the power law's slope. With sensitivities typical of Spitzer/IRS, we are able to directly probe the H 2 content via rotational emission down to ∼80 K, accounting for ∼15% of the total molecular gas mass in a galaxy. By extrapolating the fitted power-law temperature distributions to a calibrated single lower cutoff temperature, the model also recovers the total molecular content within a factor of ∼2.2 in a diverse sample of galaxies, and a subset of broken powerlaw models performs similarly well. In ULIRGs, the fraction of warm H 2 gas rises with dust temperature, with some dependency on α CO . In a sample of five low-metallicity galaxies ranging down to [ ] + = 12 log O H 7.8, the model yields molecular masses up to ∼100×larger than implied by CO, in good agreement with other methods based on dust mass and star formation depletion timescale. This technique offers real promise for assessing molecular content in the early universe where CO and dust-based methods may fail.

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Section: Molecular Gas Mass Using Our Modelsupporting

confidence: 80%

LIGHTING THE DARK MOLECULAR GAS: H₂ AS A DIRECT TRACER

Togi

Smith

2016

ApJ

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“…Results were calculated by integrating to A V = 7, and with a cosmic ray flux rate 100 times that of the Milky Way. For reference, the approximate values for Main Sequence galaxies (Malhotra et al 2001), local starbursts (Stacey et al 1991), and local ULIRGs (Davies et al 2003) are shown. The average density for the four DSFGs without a constraint on G 0 is shown at the bottom.…”

Section: Pdr Modelling Resultsmentioning

confidence: 99%

ALMA observations of atomic carbon inz ∼ 4 dusty star-forming galaxies

Bothwell

Aguirre

Aravena

et al. 2016

Mon. Not. R. Astron. Soc.

134

180

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We present ALMA [Ci](1−0) (rest frequency 492 GHz) observations for a sample of 13 strongly-lensed dusty star-forming galaxies originally discovered at 1.4mm in a blankfield survey by the South Pole Telescope. We compare these new data with available [Ci] observations from the literature, allowing a study of the ISM properties of ∼ 30 extreme dusty star-forming galaxies spanning a redshift range 2 < z < 5. Using the [Ci] line as a tracer of the molecular ISM, we find a mean molecular gas mass for SPTDSFGs of 6.6 × 10 10 M . This is in tension with gas masses derived via low-J 12 CO and dust masses; bringing the estimates into accordance requires either (a) an elevated CO-to-H 2 conversion factor for our sample of α CO ∼ 2.5 and a gas-to-dust ratio ∼ 200, or (b) an high carbon abundance X CI ∼ 7 × 10 −5 . Using observations of a range of additional atomic and molecular lines (including [Ci], [Cii], and multiple transitions of CO), we use a modern Photodissociation Region code (3d-pdr) to assess the physical conditions (including the density, UV radiation field strength, and gas temperature) within the ISM of the DSFGs in our sample. We find that the ISM within our DSFGs is characterised by dense gas permeated by strong UV fields. We note that previous efforts to characterise PDR regions in DSFGs may have significantly under-estimated the density of the ISM. Combined, our analysis suggests that the ISM of extreme dusty starbursts at high redshift consists of dense, carbon-rich gas not directly comparable to the ISM of starbursts in the local Universe.

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“…Graciá-Carpio et al, 2011) at high-redshift have all been detected in [CII]. The line is thought to be an important coolant in the ISM, and can make up as much as 1% of the far infrared luminosity of a galaxy (Nikola et al, 1998;Malhotra et al, 2001;Stacey et al, 2010). However, the sites of origin of [CII] emission can be diverse, and thus its power as a diagnostic for the physical conditions in the ISM of early Universe galaxies is still debated.…”

Section: Atomic Linesmentioning

confidence: 99%

“…However, present-epoch ULIRGs emit roughly ∼ 10% of the expected [CII] flux, given their far infrared luminosities (e.g. Malhotra et al, 1997Malhotra et al, , 2001Luhman et al, 1998Luhman et al, , 2003. A variety of possible explanations have been posited for the apparent deficit.…”

Section: The [Cii]-fir Deficit In Galaxiesmentioning

confidence: 99%

Dusty star-forming galaxies at high redshift

2014

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Far-infrared and submillimeter wavelength surveys have now established the important role of dusty, star-forming galaxies (DSFGs) in the assembly of stellar mass and the evolution of massive galaxies in the Universe. The brightest of these galaxies have infrared luminosities in excess of 10 13 L with implied star-formation rates of thousands of solar masses per year. They represent the most intense starbursts in the Universe, yet many are completely optically obscured. Their easy detection at submm wavelengths is due to dust heated by ultraviolet radiation of newly forming stars. When summed up, all of the dusty, star-forming galaxies in the Universe produce an infrared radiation field that has an equal energy density as the direct starlight emission from all galaxies visible at ultraviolet and optical wavelengths. The bulk of this infrared extragalactic background light emanates from galaxies as diverse as gas-rich disks to mergers of intense starbursting galaxies. Major advances in far-infrared instrumentation in recent years, both spacebased and ground-based, has led to the detection of nearly a million DSFGs, yet our understanding of the underlying astrophysics that govern the start and end of the dusty starburst phase is still in nascent stage. This review is aimed at summarizing the current status of DSFG studies, focusing especially on the detailed characterization of the bestunderstood subset (submillimeter galaxies, who were summarized in the last review of this field over a decade ago, Blain et al. 2002), but also the selection and characterization of more recently discovered DSFG populations. We review DSFG population statistics, their physical properties including dust, gas and stellar contents, their environments, and current theoretical models related to the formation and evolution of these galaxies.

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Far‐Infrared Spectroscopy of Normal Galaxies: Physical Conditions in the Interstellar Medium

Cited by 397 publications

References 65 publications

LIGHTING THE DARK MOLECULAR GAS: H₂ AS A DIRECT TRACER

LIGHTING THE DARK MOLECULAR GAS: H₂ AS A DIRECT TRACER

ALMA observations of atomic carbon inz ∼ 4 dusty star-forming galaxies

Dusty star-forming galaxies at high redshift

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Far‐Infrared Spectroscopy of Normal Galaxies: Physical Conditions in the Interstellar Medium

Cited by 397 publications

References 65 publications

LIGHTING THE DARK MOLECULAR GAS: H2 AS A DIRECT TRACER

LIGHTING THE DARK MOLECULAR GAS: H2 AS A DIRECT TRACER

ALMA observations of atomic carbon inz ∼ 4 dusty star-forming galaxies

Dusty star-forming galaxies at high redshift

Contact Info

Product

Resources

About

LIGHTING THE DARK MOLECULAR GAS: H₂ AS A DIRECT TRACER

LIGHTING THE DARK MOLECULAR GAS: H₂ AS A DIRECT TRACER