Quasar Elemental Abundances at High Redshifts

Dietrich, M.; Hamann, Fred; Shields, J. C.; Constantin, Anca; Heidt, J.; Jäger, Klaus; Vestergaard, M.; Wagner, S. J.

doi:10.1086/374662

Cited by 117 publications

(151 citation statements)

References 102 publications

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“…Similar conclusions were drawn from different lines of argument by Kronberg et al (2001) and Furlanetto & Loeb (2001). These radio sources born during the quasar era could also have contributed toward metal enhancement of their environments (GKW03b; GWB04), since observations (e.g., Dietrich et al 2003;Schaye et al 2003;Aguirre et al 2004;Shapley et al 2004;Pieri et al 2006;Prochaska et al 2006;Tripp et al 2006) require an efficient mechanism for spreading metals widely at early cosmic epochs.…”

Section: Introductionsupporting

confidence: 61%

Testing Models of Radio Galaxy Evolution and the Cosmological Impact of FR II Radio Galaxies

Barai

Wiita

2007

ApJ

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We investigate aspects of the cosmological evolution of FR II radio galaxies, focusing first on the abilities of models to match data for linear sizes, radio powers, redshifts, and spectral indices. Here we consider modifications to the theoretical models we had treated earlier, primarily by accounting for the growth of the radius of hot spots with source size. Better fits to the distributions of most of the data in three low-frequency surveys can be found with sensible choices of model parameters, but no model yet considered gives a good match to all of the survey data simultaneously, nor does any do a good job of producing the spectral index distributions. The observational data sets are too small to completely discriminate among the models. We calculate the volume fraction of the ''relevant universe'' cumulatively occupied by the expanding radio galaxy lobes over the quasar era, when these powerful radio galaxies were much more common, and when they have been argued to play an important role in triggering galaxy formation and spreading magnetic fields and metals. We found the cumulative relevant volume filling factor of radio galaxies to be $5%, so we conclude that these impacts are smaller than previously estimated but that they are still significant.

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Section: Introductionsupporting

confidence: 61%

Testing Models of Radio Galaxy Evolution and the Cosmological Impact of FR II Radio Galaxies

Barai

Wiita

2007

ApJ

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“…Smaller velocity shifts and broader lines are more likely to be associated directly with the quasar as outflows, but we see no strong trend in metallicity with velocity shift or line width. We find a broad range in AAL metallicity, from only ∼ 0.01 solar up to ∼ 10 times solar, consistent with previous supersolar results ( Nagao et al 2006;Dietrich et al 2003). One z ∼ 3.5 quasar has AALs that are supersolar in seven out of nine systems (see Simon & Hamann 2010).…”

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confidence: 90%

Tracing Outflows in High-Redshift Quasars

Simon

Hamann

2009

Proc. IAU

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Abstract. We present preliminary results from the largest-ever survey of high-resolution associated absorption line (AAL) region metallicities and physical properties in a sample of high redshift (z > 3) quasars.Keywords. techniques: spectroscopic, (galaxies:) quasars: absorption lines, galaxies: evolution High-redshift quasars are thought to represent an early stage of galaxy evolution, in which models by, e.g., Di Matteo et al. (2008) and Hopkins et al. (2008) predict that major mergers trigger violent star formation and the rapid growth of a central supermassive black hole. We investigate the details of this relationship using the largest-ever survey (others include Savaglio et al. 1994;Wampler et al. 1996) of narrow associated absorption line (AAL, v width < 500 km s −1 , forming within 12,000 km s −1 of the quasar emission velocity) metallicities and physical properties in a sample of high-redshift (z > 3) quasars with Keck high-resolution spectra in a range of near-quasar environments, including quasar outflows and host galaxy halos. We measure C iv and H i optical depths, covering fractions, widths, and column densities. We obtain good ionization constraints and determine well-constrained metallicities for five AAL systems in one z > 3 and two z > 4 quasars. We determine lower limits for metallicities for AALs in four other z ∼ 4 quasars.We distinguish AALs in outflows from AALs with other origins by their broad, smooth profile shapes, covering fractions, and velocity shifts. The outflow fraction for AALs in the z > 4 quasars is 30% < f O < 50%, and when combined with the larger z > 2 sample is 50% < f O < 60%. Smaller velocity shifts and broader lines are more likely to be associated directly with the quasar as outflows, but we see no strong trend in metallicity with velocity shift or line width. We find a broad range in AAL metallicity, from only ∼ 0.01 solar up to ∼ 10 times solar, consistent with previous supersolar results ( Nagao et al. 2006;Dietrich et al. 2003). One z ∼ 3.5 quasar has AALs that are supersolar in seven out of nine systems (see Simon & Hamann 2010). The AALs with covering fraction less than one are more likely to be metal rich. These results are consistent with evolutionary models in which luminous quasars appear in host galaxies after significant star formation.

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“…These are low enough compared to the estimated TDE rate for evolved stars in Kochanek (2015) that there seems no difficulty in creating the nitrogen rich quasars using the very long lived TDE's associated with the larger evolved stars. A more general puzzle about abundances inferred from quasar BLRs is that they appear to require very high metallicities, Z > ∼ 5Z⊙ (e.g., Dietrich et al 2003, Nagao et al 2006. It is somewhat challenging to reach these metallicities with global star formation models (e.g., Hamann & Ferland 1993, Friaca & Terlevich 1998, Romano et al 2002, leading to an alternative picture of star formation associated with the outer, self-gravitating parts of the accretion flow (e.g., Collin & Zahn 1999, Wang et al 2011.…”

Section: Nitrogen Rich Quasars and Tdesmentioning

confidence: 99%

Abundance anomalies in tidal disruption events

Kochanek

2016

Mon. Not. R. Astron. Soc.

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The ∼ 10% of tidal disruption events (TDEs) due to stars more massive than M * > ∼ M ⊙ should show abundance anomalies due to stellar evolution in helium, carbon and nitrogen, but not oxygen. Helium is always enhanced, but only by up to ∼ 25% on average because it becomes inaccessible once it is sequestered in the high density core as the star leaves the main sequence. However, portions of the debris associated with the disrupted core of a main sequence star can be enhanced in helium by factors of 2-3 for debris at a common orbital period. These helium abundance variations may be a contributor to the observed diversity of hydrogen and helium line strengths in TDEs. A still more striking anomaly is the rapid enhancement of nitrogen and the depletion of carbon due to the CNO cycle -stars with M * > ∼ M ⊙ quickly show an increase in their average N/C ratio by factors of 3-10. Because low mass stars evolve slowly and high mass stars are rare, TDEs showing high N/C will almost all be due to 1-2M ⊙ stars disrupted on the main sequence. Like helium, portions of the debris will show still larger changes in C and N, and the anomalies decline as the star leaves the main sequence. The enhanced [N/C] abundance ratio of these TDEs provides the first natural explanation for the rare, nitrogen rich quasars and also explains the strong nitrogen emission seen in ultraviolet spectra of ASASSN-14li.

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Quasar Elemental Abundances at High Redshifts

Cited by 117 publications

References 102 publications

Testing Models of Radio Galaxy Evolution and the Cosmological Impact of FR II Radio Galaxies

Testing Models of Radio Galaxy Evolution and the Cosmological Impact of FR II Radio Galaxies

Tracing Outflows in High-Redshift Quasars

Abundance anomalies in tidal disruption events

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