SDSS J2222+2745: A Gravitationally Lensed Sextuple Quasar With a Maximum Image Separation of 15.″1 Discovered in the Sloan Giant Arcs Survey

Dahle, H.; Gladders, Michael D.; Sharon, Keren; Bayliss, M.; Wuyts, Eva; Abramson, Louis E.; Koester, Benjamin P.; Groeneboom, N. E.; Brinckmann, Thejs; Kristensen, Mikkel Theiss; Lindholmer, Mikkel; Nielsen, A. B.; Krogager, J.-K.; Fynbo, J. P. U.

doi:10.1088/0004-637x/773/2/146

Cited by 49 publications

(74 citation statements)

References 37 publications

(37 reference statements)

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“…In some cases, e.g., CSWA159, mass models were already available in the literature (Dahle et al 2013). Depending on the circumstances, three distinct methods were used in constructing new mass models as detailed below.…”

Section: Source Plane Reconstructionmentioning

confidence: 99%

“…Multiple images are then identified from their similar colors and/or spectroscopic redshifts, if available, in conjunction with a preliminary guess for the mass model. In many cases, spectroscopic redshifts are available in the literature (Dahle et al 2013;Stark et al 2013;Brewer et al 2011) and from our OSIRIS observations. In a few cases where redshifts are not available for identified multiple images, we leave the redshift as a free parameter.…”

Section: Source Plane Reconstructionmentioning

confidence: 99%

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A Keck Adaptive Optics Survey of a Representative Sample of Gravitationally Lensed Star-Forming Galaxies: High Spatial Resolution Studies of Kinematics and Metallicity Gradients

Leethochawalit

Jones

Ellis

et al. 2016

ApJ

138

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We discuss spatially resolved emission line spectroscopy secured for a total sample of 15 gravitationally lensed star-forming galaxies at a mean redshift of z 2  based on Keck laser-assisted adaptive optics observations undertaken with the recently improved OSIRIS integral field unit (IFU) spectrograph. By exploiting gravitationally lensed sources drawn primarily from the CASSOWARY survey, we sample these sub-L* galaxies with sourceplane resolutions of a few hundred parsecs ensuring well-sampled 2D velocity data and resolved variations in the gas-phase metallicity. Such high spatial resolution data offer a critical check on the structural properties of larger samples derived with coarser sampling using multiple-IFU instruments. We demonstrate how kinematic complexities essential to understanding the maturity of an early star-forming galaxy can often only be revealed with better sampled data. Although we include four sources from our earlier work, the present study provides a more representative sample unbiased with respect to emission line strength. Contrary to earlier suggestions, our data indicate a more diverse range of kinematic and metal gradient behavior inconsistent with a simple picture of well-ordered rotation developing concurrently with established steep metal gradients in all but merging systems. Comparing our observations with the predictions of hydrodynamical simulations suggests that gas and metals have been mixed by outflows or other strong feedback processes, flattening the metal gradients in early star-forming galaxies.

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Section: Source Plane Reconstructionmentioning

confidence: 99%

Section: Source Plane Reconstructionmentioning

confidence: 99%

A Keck Adaptive Optics Survey of a Representative Sample of Gravitationally Lensed Star-Forming Galaxies: High Spatial Resolution Studies of Kinematics and Metallicity Gradients

Leethochawalit

Jones

Ellis

et al. 2016

ApJ

138

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“…Previous papers described the discovery and initial follow-up (Dahle et al 2013), time delay measurements of the three brightest quasar images (Dahle et al 2015), and detailed strong lens modeling (Sharon et al 2017) of SDSSJ2222+2745. Here, we build on previous studies of this source using the lens model from Sharon et al (2017).…”

Section: Sdssj2222+2745mentioning

confidence: 99%

“…The large separation minimizes the confounding effects of the foreground lens light, and these systems also tend to have high magnifications over a larger area in the source plane, such that the host galaxy is highly magnified out to physical projected radii of several kiloparsecs. Currently, there are only three large separation lensed quasars known: SDSSJ1004 +4112 (Inada et al 2003;Oguri et al 2004;Sharon et al 2005;Fian et al 2016), SDSSJ1029+2623 (Inada et al 2006;Oguri et al 2008Oguri et al , 2013, and SDSSJ2222+2745 (Dahle et al 2013(Dahle et al , 2015Sharon et al 2017). While strong-lensing studies of these systems using HST can provide uniquely high spatial resolution, the technique has been relatively underutilized.…”

Section: Introductionmentioning

confidence: 99%

Spatially Resolved Patchy Lyα Emission within the Central Kiloparsec of a Strongly Lensed Quasar Host Galaxy at z = 2.8

Bayliss¹,

Sharon²,

Acharyya³

et al. 2017

ApJL

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We report the detection of extended Lyα emission from the host galaxy of SDSSJ2222+2745, a strongly lensed quasar at z=2.8. Spectroscopic follow-up clearly reveals extended Lyα in emission between two images of the central active galactic nucleus (AGN). We reconstruct the lensed quasar host galaxy in the source plane by applying a strong lens model to HST imaging and resolve spatial scales as small as ∼200 pc. In the source plane, we recover the host galaxy morphology to within a few hundred parsecs of the central AGN and map the extended Lyα emission to its physical origin on one side of the host galaxy at radii ∼0.5-2 kpc from the central AGN. There are clear morphological differences between the Lyα and rest-frame ultraviolet stellar continuum emission from the quasar host galaxy. Furthermore, the relative velocity profiles of quasar Lyα, host galaxy Lyα, and metal lines in outflowing gas reveal differences in the absorbing material affecting the AGN and host galaxy. These data indicate the presence of patchy local intervening gas in front of the central quasar and its host galaxy. This interpretation is consistent with the central luminous quasar being obscured across a substantial fraction of its surrounding solid angle, resulting in strong anisotropy in the exposure of the host galaxy to ionizing radiation from the AGN. This work demonstrates the power of strong-lensing-assisted studies to probe spatial scales that are currently inaccessible by other means.

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“…Lensing configurations that involve a quasar lensed by a single massive galaxy are more common; however, the lensing magnification of a single galaxy is typically significantly lower than in the Galaxy cluster case. Unique to the cluster-lensed quasar configurations, the multiple images of the lensed quasar have large separations (14 6-22 5; Inada et al 2003Inada et al , 2006Dahle et al 2013) and high magnifications; the lensed active nucleus is point-like, providing accurate positional constraints, and is variableenabling measurements of the time delay between images of the same source. The high tangential magnification stretches the host galaxy of the quasar into a giant arc, thus resolving it from the light of the active nucleus, which usually dominates in a high-redshift quasar.…”

Section: Introductionmentioning

confidence: 99%

Lens Model and Time Delay Predictions for the Sextuply Lensed Quasar SDSS J2222+2745*

Sharon¹,

Bayliss²,

Dahle³

et al. 2017

ApJ

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SDSS J2222+2745 is a galaxy cluster at z=0.49, strongly lensing a quasar at z=2.805 into six widely separated images. In recent Hubble Space Telescope imaging of the field, we identify additional multiply lensed galaxies and confirm the sixth quasar image that was identified by Dahle et al. We used the Gemini-North telescope to measure a spectroscopic redshift of z=4.56 of one of the lensed galaxies. These data are used to refine the lens model of SDSS J2222+2745, compute the time delay and magnifications of the lensed quasar images, and reconstruct the source image of the quasar host and a lensed galaxy at z = 2.3. This galaxy also appears in absorption in our Gemini spectra of the lensed quasar, at a projected distance of 34 kpc. Our model is in agreement with the recent time delay measurements of Dahle et al., who found τ AB =47.7±6.0 days and τ AC =−722±24 days. We use the observed time delays to further constrain the model, and find that the model-predicted time delays of the three faint images of the quasar are τ AD =502±68 days, τ AE =611±75 days, and τ AF =415±72 days. We have initiated a follow-up campaign to measure these time delays with Gemini North. Finally, we present initial results from an X-ray monitoring program with Swift, indicating the presence of hard X-ray emission from the lensed quasar, as well as extended X-ray emission from the cluster itself, which is consistent with the lensing mass measurement and the cluster velocity dispersion.

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SDSS J2222+2745: A Gravitationally Lensed Sextuple Quasar With a Maximum Image Separation of 15.″1 Discovered in the Sloan Giant Arcs Survey

Cited by 49 publications

References 37 publications

A Keck Adaptive Optics Survey of a Representative Sample of Gravitationally Lensed Star-Forming Galaxies: High Spatial Resolution Studies of Kinematics and Metallicity Gradients

A Keck Adaptive Optics Survey of a Representative Sample of Gravitationally Lensed Star-Forming Galaxies: High Spatial Resolution Studies of Kinematics and Metallicity Gradients

Spatially Resolved Patchy Lyα Emission within the Central Kiloparsec of a Strongly Lensed Quasar Host Galaxy at z = 2.8

Lens Model and Time Delay Predictions for the Sextuply Lensed Quasar SDSS J2222+2745*

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