On-axis spectroscopy of the<i>z</i>$\mathsf{=0.144}$ radio-loud quasar HE 1434–1600: an elliptical host with a highly ionized ISM

Letawe, Géraldine; Courbin, F.; Magain, Pierre; Hilker, M.; Jablonka, P.; Jahnke, K.; Wisotzki, L.

doi:10.1051/0004-6361:20040481

Cited by 20 publications

(29 citation statements)

References 40 publications

(42 reference statements)

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“…This was tested even for complex diffraction limited PSFs, such as those of space telescopes (HST, JWST) or giant ground-based telescopes operating with AO (the E-ELT and TMT). The MCS algorithm has been applied to a broad range of applications in the past (e.g., Eigenbrod et al 2008;Gillon et al 2006;Magain et al 2005;Meylan et al 2005;Letawe et al 2004). The improved version presented here has been used to obtain accurate light curves of the blended images of gravitationally lensed quasars monitored by the COSMOGRAIL program (e.g., Tewes et al 2013;Rathna Kumar et al 2013).…”

Section: Resultsmentioning

confidence: 99%

Firedec: a two-channel finite-resolution image deconvolution algorithm

Cantale

Courbin

Tewes

et al. 2016

A&A

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We present a two-channel deconvolution method that decomposes images into a parametric point-source channel and a pixelized extended-source channel. Based on the central idea of the deconvolution algorithm proposed by Magain et al. (1998, ApJ, 494, 472), the method aims at improving the resolution of the data rather than at completely removing the point spread function (PSF). Improvements over the original method include a better regularization of the pixel channel of the image, based on wavelet filtering and multiscale analysis, and a better controlled separation of the point source vs. the extended source. In addition, the method is able to simultaneously deconvolve many individual frames of the same object taken with different instruments under different PSF conditions. For this purpose, we introduce a general geometric transformation between individual images. This transformation allows the combination of the images without having to interpolate them. We illustrate the capability of our algorithm using real and simulated images with complex diffraction-limited PSF.

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Section: Resultsmentioning

confidence: 99%

Firedec: a two-channel finite-resolution image deconvolution algorithm

Cantale

Courbin

Tewes

et al. 2016

A&A

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“…The FORS2/MXU spectra of HE 0450-2958 are all deconvolved using the MCS algorithm for slit spectra (Magain et al 1998;Courbin et al 2000), allowing a separation of the QSO light from the underlying extended objects. This method has been used successfully on many occasions, either on data of QSO host galaxies (Courbin et al 2002;Letawe et al 2004;M05;Letawe et al 2007) or on data of gravitationally lensed QSOs (e.g., Eigenbrod et al 2006Eigenbrod et al , 2007.…”

Section: Slit Spectroscopymentioning

confidence: 99%

Slit and integral-field optical spectroscopy of the enigmatic quasar HE 0450–2958

Letawe¹,

Magain²,

Courbin

2008

A&A

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Context. Interest in the quasar HE 0450-2958 arose following the publication of the non-detection of its expected massive host, leading to various interpretations. Aims. This article investigates the gaseous and stellar contents of the system through additional VLT/FORS slit spectra and integral field spectroscopy from VLT/VIMOS. Methods. We apply our MCS deconvolution algorithm on slit spectra for the separation of the QSO and diffuse components, and develop a new method to remove the point sources in Integral Field Spectra, allowing extraction of velocity maps, narrow-line images, spatially resolved spectra or ionization diagrams of the surroundings of HE 0450-2958. Results. The whole system is embedded in gas, mostly ionized by the QSO radiation field and shocks associated with radio jets. The observed gas and star dynamics are unrelated, revealing a strongly perturbed system. Despite longer spectroscopic observations, the host galaxy remains undetected.

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“…Because the lensing QSOs are at low redshift (z < 0.4), the range of follow-up applications is very rich, as their Hβ, Hα, [O iii] emission lines are clearly measurable in the SDSS spectra. In addition, the angular size and luminosity of their host galaxies make it possible to carry out direct spectroscopy of the host (e.g., Lewate et al 2007;A&A 516, L12 (2010) Letawe et al 2004;Courbin et al 2002). Our sample will therefore allow us to test directly the scaling laws established between the properties of QSO emission lines, the mass of the central black hole, and the total mass of the host galaxies (e.g., Kaspi et al 2005;Bonning et al 2005;Shen et al 2008).…”

Section: Introductionmentioning

confidence: 99%

First case of strong gravitational lensing by a QSO: SDSS J0013+1523 atz= 0.120

Courbin¹,

Tewes²,

Djorgovski

et al. 2010

A&A

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We present the first case of strong gravitational lensing by a QSO: SDSS J0013+1523 at z = 0.120. The discovery is the result of a systematic search for emission lines redshifted behind QSOs, among 22 298 spectra of the SDSS data release 7. Apart from the z = 0.120 spectral features of the foreground QSO, the spectrum of SDSS J0013+1523 also displays the [O ii] and Hβ emission lines and the [O iii] doublet, all at the same redshift, z = 0.640. Using sharp Keck adaptive optics K-band images obtained using laser guide stars, we unveil two objects within a radius of 2 from the QSO. Deep Keck optical spectroscopy clearly confirms one of these objects at z = 0.640 and shows traces of the [O iii] emission line of the second object, also at z = 0.640. Lens modeling suggests that they represent two images of the same z = 0.640 emission-line galaxy. Our Keck spectra also allow us to measure the redshift of an intervening galaxy at z = 0.394, located 3.2 away from the line of sight to the QSO. If the z = 0.120 QSO host galaxy is modeled as a singular isothermal sphere, its mass within the Einstein radius is M E (r < 1 h −1 kpc) = 2.16 × 10 10 h −1 M and its velocity dispersion is σ SIS = 169 km s −1 . This is about 1-σ away from the velocity dispersion estimated from the width of the QSO Hβ emission line, σ * (M BH ) = 124 ± 47 km s −1 . Deep optical HST imaging will be necessary to constrain the total radial mass profile of the QSO host galaxy using the detailed shape of the lensed source. This first case of a QSO acting as a strong lens on a more distant object opens new directions in the study of QSO host galaxies.

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On-axis spectroscopy of thez$\mathsf{=0.144}$ radio-loud quasar HE 1434–1600: an elliptical host with a highly ionized ISM

Cited by 20 publications

References 40 publications

Firedec: a two-channel finite-resolution image deconvolution algorithm

Firedec: a two-channel finite-resolution image deconvolution algorithm

Slit and integral-field optical spectroscopy of the enigmatic quasar HE 0450–2958

First case of strong gravitational lensing by a QSO: SDSS J0013+1523 atz= 0.120

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