Resolving the Far-Ir Line Deficit: Photoelectric Heating and Far-Ir Line Cooling in NGC 1097 and NGC 4559

Croxall, K. V.; Smith, J. D.; Wolfire, M. G.; Roussel, H.; Sandström, Karin; Draine, B. T.; Aniano, G.; Dale, Daniel A.; Armus, L.; Beirão, P.; Hélou, G.; Bolatto, Alberto D.; Appleton, P. N.; Brandl, Bernhard R.; Calzetti, Daniela; Crocker, Alison F.; Galametz, M.; Groves, Brent; Hao, Cai-Na; Hunt, L. K.; Johnson, Benjamin D.; Kennicutt, Robert C.; Koda, Jin; Krause, O.; Li, Y.; Meidt, Sharon E.; Murphy, E. J.; Rahman, Nurur; Rix, Hans─Walter; Sauvage, M.; Schinnerer, E.; Walter, Fabian; Wilson, C. D.

doi:10.1088/0004-637x/747/1/81

Cited by 93 publications

(127 citation statements)

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“…The , as well as a decrease with FIR color in star-forming galaxies (Malhotra et al 2001). Several hypotheses to explain the apparent line deficit in galaxies include (1) more dust screening at high ionization parameter (Luhman et al 2003;Abel et al 2009); (2) lower photoelectric efficiency due to charged small dust grains under intense radiation fields (Malhotra et al 2001;Croxall et al 2012); (3) lower photoelectric efficiency due to a decrease in the PAH abundance under hard radiation fields (Madden et al 2006;Rubin et al 2009); and (4) large dust optical depths leading to extinction of the emission lines (Papadopoulos et al 2010;Rangwala et al 2011). The dwarf galaxies extend the relative importance of the gas cooling to high values.…”

Section: Interpretation Of the [C Ii]/l Tir And [O I]/l Tir Trendsmentioning

confidence: 99%

“…From those studies (see Genzel & Cesarsky 2000, for a review), the [C ] line emerges as the brightest cooling line of the ISM in star-forming galaxies and as a good tracer of the star formation activity, accounting for ∼0.1-1% of the FIR luminosity (e.g., Stacey et al 2010;Pierini et al 2003;Boselli et al 2002;De Looze et al 2011, 2014aSargsyan et al 2014). A deficit in the FIR line intensities is, however, found in luminous IR galaxies (e.g., Luhman et al 2003;Graciá-Carpio et al 2011;Croxall et al 2012;Díaz-Santos et al 2013). The origin of the [C ] line has been debated in extragalactic studies as it can arise from molecular, neutral atomic, and ionized gas phases.…”

Section: Introductionmentioning

confidence: 99%

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TheHerschelDwarf Galaxy Survey

Cormier

Madden

Lebouteiller

et al. 2015

A&A

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Context. The far-infrared (FIR) lines are important tracers of the cooling and physical conditions of the interstellar medium (ISM) and are rapidly becoming workhorse diagnostics for galaxies throughout the universe. There are clear indications of a different behavior of these lines at low metallicity that needs to be explored. Aims. Our goal is to explain the main differences and trends observed in the FIR line emission of dwarf galaxies compared to more metal-rich galaxies, and how this translates in ISM properties. ] 57 µm fine-structure cooling lines in a sample of 48 low-metallicity star-forming galaxies of the guaranteed time key program Dwarf Galaxy Survey. We correlate PACS line ratios and line-to-L TIR ratios with L TIR , L TIR /L B , metallicity, and FIR color, and interpret the observed trends in terms of ISM conditions and phase filling factors with Cloudy radiative transfer models. Results. We find that the FIR lines together account for up to 3 percent of L TIR and that star-forming regions dominate the overall emission in dwarf galaxies. Compared to metal-rich galaxies, the ratios of Harboring compact phases of a low filling factor and a large volume filling factor of diffuse gas, the ISM of low-metallicity dwarf galaxies has a more porous structure than that of metal-rich galaxies. Methods

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Section: Interpretation Of the [C Ii]/l Tir And [O I]/l Tir Trendsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

TheHerschelDwarf Galaxy Survey

Cormier

Madden

Lebouteiller

et al. 2015

A&A

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238

399

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“…The model assumes a plane parallel slab geometry illuminated from one direction with a specified 1D UV field and calculates the thermal balance and abundances of the dominant atomic and molecular species as well as their line emission. These models have been used to interpret a variety of observations of molecular and atomic species in a wide range of physical conditions including OH + , H 2 O + , and H 3 O + in diffuse gas (Hollenbach et al 2012), H 2 O and HF in diffuse gas (Sonnentrucker et al 2015), [C i] and CO in low UV field molecular clouds (Burton et al 2014;Lee et al 2014), H 2 in dense PDRs (Sheffer et al 2011) (Kaufman et al 2006;Croxall et al 2012).…”

Section: Numerical Pdr Modelsmentioning

confidence: 99%

HerschelPACS and SPIRE spectroscopy of the photodissociation regions associated with S 106 and IRAS 23133+6050

Stock

Wolfire

Peeters

et al. 2015

A&A

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Context. Photodissociation regions (PDRs) contain a large portion of all of the interstellar matter in galaxies. Classical examples include the boundaries between ionized regions and molecular clouds in regions of massive star-formation, marking the point where all of the photons that are energetic enough to ionize hydrogen have been absorbed. Aims. To determine the physical properties of the PDRs associated with the star-forming regions IRAS 23133+6050 and S 106 and present them in the context of other Galactic PDRs associated with massive star-forming regions. Methods. We employ Herschel PACS and SPIRE spectroscopic observations to construct a full 55-650 μm spectrum of each object from which we measure the PDR cooling lines, other fine-structure lines, CO lines, and the total far-infrared flux. These measurements (and combinations thereof) are then compared to standard PDR models. Subsequently, detailed numerical PDR models are compared to these predictions, yielding additional insight into the dominant thermal processes in the PDRs and their structures. Results. We find that the PDRs of each object are very similar and can be characterized by a two-phase PDR model with a very dense, highly UV irradiated phase (n ∼ 10 6 cm −3 , G 0 ∼ 10 5 ) interspersed within a lower density, weaker radiation field phase (n ∼ 10 4 cm −3 , G 0 ∼ 10 4 ). We employed two different numerical models to investigate the data. We first used RADEX models to fit the peak of the 12 CO ladder, which in conjunction with the properties derived, yielded a temperature of around 300 K. Subsequent numerical modeling with a full PDR model revealed that the dense phase has a filling factor of around 0.6 in both objects. The shape of the 12 CO ladder was consistent with these components, with heating dominated by grain photoelectric heating. An extra excitation component for the hightest-J lines (J > 20) is required for S 106.

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“…However, studies have shown important differences between SMGs and ULIRGs. For example, the spatial extent of the gas and star formation in SMGs appears to be much larger than that typically seen in local ULIRGs (∼few kpc in SMGs compared to just hundreds of pc in local ULIRGs, e.g., Chapman et al 2004;Sakamoto et al 2008;Kennicutt et al 2011;Croxall et al 2012;Ivison et al 2012;Ikarashi et al 2015;Simpson et al 2015a;Hodge et al 2016), and while the intense star formation seen in local ULIRGs appears to be triggered by major mergers (e.g., Clements & Baker 1996;Farrah et al 2001;Surace et al 2001;Veilleux 2002), theoretical predictions have suggested that SMGs at z∼1-5 comprise a heterogeneous mix of star formation occurring in extended disks, pre-coalescence mergers, and late-stage mergers (e.g., Hayward et al 2011;Cowley et al 2017), which may be consistent with Hubble Space Telescope (HST) imaging (Chen et al 2015).…”

Section: Introductionmentioning

confidence: 98%

The Dust and [C ii] Morphologies of Redshift ∼4.5 Sub-millimeter Galaxies at ∼200 pc Resolution: The Absence of Large Clumps in the Interstellar Medium at High-redshift

Gullberg

Swinbank

Smail

et al. 2018

ApJ

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Additional information: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-pro t purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. AbstractWe present deep, high-resolution (0 03, 200 pc) ALMA Band 7 observations covering the dust continuum and [C II] λ157.7 μm emission in four z∼4.4-4.8 sub-millimeter galaxies (SMGs) selected from the ALESS and AS2UDS surveys. The data show that the rest-frame 160 μm (observed 345 GHz) dust emission is consistent with smooth morphologies on kpc scales for three of the sources. One source, UDS 47.0, displays apparent substructure, but this is also consistent with a smooth morphology-as indicated by simulations showing that smooth exponential disks can appear clumpy when observed at the high angular resolution (0 03) and depth of these observations (s~-27 47 345 GHz μJy beam −1 ). The four SMGs are bright [C II] emitters. We extract [C II] spectra from the high-resolution data, and recover ∼20%-100% of the [C II] flux and ∼40%-80% of the dust continuum emission, compared to the previous lower-resolution observations. When tapered to 0 2 resolution, our maps recover ∼80%-100% of the continuum emission, indicating that ∼60% of the emission is resolved out on ∼200 pc scales. We find that the [C II] emission in high-redshift galaxies is more spatially extended than the rest-frame 160 μm dust continuum by a factor of 1.6±0.4. By considering the [ ] L C II /L FIR ratio as a function of the star formation rate surface density (S SFR ), we revisit the [C II] deficit and suggest that the decline in the [ ] L C II /L FIR ratio as a function of S SFR is consistent with local processes. We also explore the physical drivers that may be responsible for these trends and can give rise to the properties found in the densest regions of SMGs.

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Resolving the Far-Ir Line Deficit: Photoelectric Heating and Far-Ir Line Cooling in NGC 1097 and NGC 4559

Cited by 93 publications

References 83 publications

TheHerschelDwarf Galaxy Survey

TheHerschelDwarf Galaxy Survey

HerschelPACS and SPIRE spectroscopy of the photodissociation regions associated with S 106 and IRAS 23133+6050

The Dust and [C ii] Morphologies of Redshift ∼4.5 Sub-millimeter Galaxies at ∼200 pc Resolution: The Absence of Large Clumps in the Interstellar Medium at High-redshift

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