Mid-infrared spectroscopy of<i>Spitzer</i>-selected ultra-luminous starbursts at<i>z</i>  ~ 2

Fiolet, N.; Omont, A.; Lagache, G.; Bertincourt, B.; Fadda, D.; Baker, A. J.; Beelen, A.; Berta, S.; Boulanger, F.; Farrah, D.; Kovács, A.; Lonsdale, C. J.; Owen, F. N.; Polletta, M.; Shupe, D. L.; Yan, Lin

doi:10.1051/0004-6361/201015504

Cited by 27 publications

(38 citation statements)

References 84 publications

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“…It also indicates that the low-redshift SFR calibration based on PAH luminosities is appropriate to use for high-redshift ULIRGs, even if it is not appropriate for low-redshift ULIRGs, consistent with other recent studies that have demonstrated this result (i.e., Rujopakarn et al 2013). However, at even higher total IR luminosities (L L 3 10 IR 12  ), there is evidence that the L PAH /L IR ratio declines for the high-redshift samples (e.g., Fiolet et al 2010). We fit this trend seen in Figure 12 as a broken powerlaw and derive a linear fit above this luminosity using the high-redshift samples of Pope et al (2013) …”

Section: The Validity Of Pah-estimated Sfrs For Very Highsupporting

confidence: 84%

A New Star Formation Rate Calibration From Polycyclic Aromatic Hydrocarbon Emission Features and Application to High-Redshift Galaxies

Shipley

Papovich

Rieke

et al. 2016

ApJ

110

125

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We calibrate the integrated luminosity from the polycyclic aromatic hydrocarbon (PAH) features at 6.2, 7.7, and 11.3 μm in galaxies as a measure of the star formation rate (SFR). These features are strong (containing as much as 5%-10% of the total infrared luminosity) and suffer minimal extinction. Our calibration uses Spitzer Infrared Spectrograph (IRS) measurements of 105 galaxies at 0<z<0.4, infrared (IR) luminosities of 10 9 -10 12 L  , combined with other well-calibrated SFR indicators. The PAH luminosity correlates linearly with the SFR as measured by the extinction-corrected Hα luminosity over the range of luminosities in our calibration sample. The scatter is 0.14 dex, comparable to that between SFRs derived from the Paα and extinction-corrected Hα emission lines, implying that the PAH features may be as accurate an SFR indicator as hydrogen recombination lines. The PAH SFR relation depends on gas-phase metallicity, for which we supply an empirical correction for galaxies with 0.2Z  <Z  0.7 Z  . We present a case study in advance of the James Webb Space Telescope (JWST), which will be capable of measuring SFRs from PAHs in distant galaxies at the peak of the SFR density in the universe (z∼2) with SFRs as low as ∼10M yr 1 - . We use Spitzer/IRS observations of the PAH features and Paα emission plus Hα measurements in lensed star-forming galaxies at 1<z<3 to demonstrate the ability of the PAHs to derive accurate SFRs. We also demonstrate that because the PAH features dominate the mid-IR fluxes, broadband mid-IR photometric measurements from JWST will bothtracethe SFR and provide a way to exclude galaxies dominated by an active galactic nucleus.

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Section: The Validity Of Pah-estimated Sfrs For Very Highsupporting

confidence: 84%

A New Star Formation Rate Calibration From Polycyclic Aromatic Hydrocarbon Emission Features and Application to High-Redshift Galaxies

Shipley

Papovich

Rieke

et al. 2016

ApJ

110

125

View full text Add to dashboard Cite

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“…We note that the predominately radio-quiet Higdon et al (2006) sample of ULIRGs (0.02 < z < 0.93) and the Schweitzer et al (2006) sample of QSOs (z < 0.3) have H 2 -to-PAH luminosity ratios significantly higher than the SINGS star-forming galaxies. Although their H 2 -to-PAH luminosity ratios are compatible with the range of ratios predicted by PDR models, other studies (based on extinction or H 2 -to-CO line ratios) suggest that additional sources of H 2 excitation (other than UV photon heating) are required to explain the H 2 emission (e.g., shocks; see Zakamska 2010;Fiolet et al 2010).…”

Section: Which Dominant Mechanism Powers the H 2 Emission?supporting

confidence: 61%

Strong Molecular Hydrogen Emission and Kinematics of the Multiphase Gas in Radio Galaxies With Fast Jet-Driven Outflows

Guillard

Ogle

Emonts

et al. 2012

ApJ

113

157

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Observations of ionized and neutral gas outflows in radio galaxies (RGs) suggest that active galactic nucleus (AGN) radio jet feedback has a galaxy-scale impact on the host interstellar medium, but it is still unclear how the molecular gas is affected. Thus, it is crucial to determine the physical conditions of the molecular gas in powerful RGs to understand how radio sources may regulate the star formation in their host galaxies. We present deep Spitzer Infrared Spectrograph (IRS) high-resolution spectroscopy of eight nearby RGs that show fast H i outflows. Strikingly, all of these H i-outflow RGs have bright H 2 mid-IR lines that cannot be accounted for by UV or X-ray heating. This strongly suggests that the radio jet, which drives the H i outflow, is also responsible for the shock excitation of the warm H 2 gas. In addition, the warm H 2 gas does not share the kinematics of the ionized/neutral gas. 4C 12.50, 3C 459, and PKS 1549-79. This shows that, contrary to the H i gas, the H 2 gas is inefficiently coupled to the AGN jet-driven outflow of ionized gas. While the dissipation of a small fraction (<10%) of the jet kinetic power can explain the turbulent heating of the molecular gas, our data show that the bulk of the warm molecular gas is not expelled from these galaxies.

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“…Desai et al (2008) and Fiolet et al (2010) addresses the redshift distribution of 24µm-selected sources by confirming a set of >400 sources spectroscopically out of ∼600 targeted. They find that the redshift distribution of 24µm galaxies brighter than 300 µJy peaks at z ∼ 0.3 with a possible second peak at z ∼ 0.9 and a tail of galaxies detected out to z ∼ 4.5.…”

Section: Redshift Distributions Of 24 µM Selected Dsfg Populationsmentioning

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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Mid-infrared spectroscopy ofSpitzer-selected ultra-luminous starbursts atz ~ 2

Cited by 27 publications

References 84 publications

A New Star Formation Rate Calibration From Polycyclic Aromatic Hydrocarbon Emission Features and Application to High-Redshift Galaxies

A New Star Formation Rate Calibration From Polycyclic Aromatic Hydrocarbon Emission Features and Application to High-Redshift Galaxies

Strong Molecular Hydrogen Emission and Kinematics of the Multiphase Gas in Radio Galaxies With Fast Jet-Driven Outflows

Dusty star-forming galaxies at high redshift

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