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QSO B1520+530 , the SIMBAD biblio

QSO B1520+530 , the SIMBAD biblio (119 results) C.D.S. - SIMBAD4 rel 1.8 - 2022.08.16CEST06:32:31

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Keywords 		in a table in teXt, Caption, ... Nb occurence Nb objects in ref Citations
(from ADS) 		Title First 3 Authors
1997A&A...318L..67C 109 T K                 8 32 SBS 1520+530: a new gravitationally lensed system at z=1.855. CHAVUSHYAN V.H., VLASYUK V.V., STEPANIAN J.A., et al.
1998AJ....115.1383C 109 T K                 9 10 Detection of the galaxy lensing the doubly imaged quasar
SBS 1520+530. 		CRAMPTON D., SCHECHTER P.L. and BEUZIT J.-L.
1998BCFHT..38...14C 17 0 Extragalactic observations with adaptive optics. CRAMPTON D.
1998BSAO...46...18V 72 T                   2 1 Photometric investigation of the field around gravitational lens SBS 1520+530 with the 6m telescope. VLASYUK V.V. and CHAVUSHYAN V.H.
1999ApJ...523..617F 2 27 205 Dust and extinction curves in galaxies with z>0: the interstellar medium of gravitational lens galaxies. FALCO E.E., IMPEY C.D., KOCHANEK C.S., et al.
1999Ap&SS.263...51M 31 ~ The CASTLES project. MUNOZ J.A., FALCO E.E., KOCHANEK C.S., et al.
1999JRASC..93..168C 6 0 Exploring the frontiers of the Universe with new eyes. CRAMPTON D.
2000A&AS..147..169B viz 2737 21 Accurate optical positions for 2978 objects from the Second Byurakan Survey (SBS) with the Digitized Sky Survey. BICAY M.D., STEPANIAN J.A., CHAVUSHYAN V.H., et al.
2000ApJ...531...81C 28 38 X-ray observations of gravitationally lensed quasars: evidence for a hidden quasar population. CHARTAS G.
2000ApJ...543..131K 56 152 The fundamental plane of gravitational lens galaxies and the evolution of early-type galaxies in low-density environments. KOCHANEK C.S., FALCO E.E., IMPEY C.D., et al.
2000PASP..112..320B 8 12 Microlensing of broad absorption line quasars: polarization variability. BELLE K.E. and LEWIS G.F.
2000PASJ...52...99A 4 4 Usability of the NFW galaxy profiles as a cosmological tool estimated from 2-image gravitatinal lens systems. ASANO K.
2001AJ....121...21B 151 47 The distribution of redshifts in new samples of quasi-stellar objects. BURBIDGE G. and NAPIER W.M.
2001AJ....121.2843B viz 6250 74 Quasars in the 2MASS second incremental data release. BARKHOUSE W.A. and HALL P.B.
2002A&A...386...69F 111 T K                 9 22 The lensing system towards the doubly imaged quasar
SBS 1520+530. 		FAURE C., COURBIN F., KNEIB J.P., et al.
2002A&A...391..481B viz 135 T K A   O           10 74 Time delay and lens redshift for the doubly imaged BAL quasar
SBS 1520+530. 		BURUD I., HJORTH J., COURBIN F., et al.
2002ApJ...571..712B 46 44 A submillimeter survey of gravitationally lensed quasars. BARVAINIS R. and IVISON R.
2002ApJ...572L..11H 1 9 53 The time delay of the quadruple quasar RX J0911.4+0551. HJORTH J., BURUD I., JAUNSEN A.O., et al.
2002ApJ...577..615W 7 20 Measuring the size of quasar broad-line clouds through time-delay light-curve anomalies of gravitational lenses. WYITHE J.S.B. and LOEB A.
2002ApJ...578...25K 4 8 116 What do gravitational lens time delays measure? KOCHANEK C.S.
2002ApJ...581..823F 1 28 87 A determination of H0with the CLASS gravitational lens B1608+656. III. A significant improvement in the of the time delay measurements. FASSNACHT C.D., XANTHOPOULOS E., KOOPMANS L.V.E., et al.
2002A&ARv..10..263C 59 26 Gravitational lensing in quasar samples. CLAESKENS J.-F. and SURDEJ J.
2003A&A...402.1157N viz 56 8 A catalog of secondary photometric standard stars around gravitational lenses. NAKOS T., OFEK E.O., BOUMIS P., et al.
2003A&A...412...35B 10 5 152 An alternative to the cosmological ``concordance model''. BLANCHARD A., DOUSPIS M., ROWAN-ROBINSON M., et al.
2003A&A...412..399V 72 145 A catalogue of quasars and active nuclei: 11th edition. VERON-CETTY M.-P. and VERON P.
2003AJ....125.2325P 11 23 Determining the lensing fraction of SDSS quasars: methods and results from the early data release. PINDOR B., TURNER E.L., LUPTON R.H., et al.
2003ApJ...583...49K 1 11 43 Gravitational lens time delays in cold dark matter. KOCHANEK C.S.
2003ApJ...587..143R 62 118 The evolution of a mass-selected sample of early-type field galaxies. RUSIN D., KOCHANEK C.S., FALCO E.E., et al.
2003ApJ...592..710A 26 14 Lens or binary? Chandra observations of the wide-separation broad absorption line quasar pair UM 425. ALDCROFT T.L. and GREEN P.J.
2003ApJ...594..101O 21 48 Time-delay measurement of the lensed quasar HE 1104-1805. OFEK E.O. and MAOZ D.
2003ApJ...595...29R 45 118 Self-similar models for the mass profiles of early-type lens galaxies. RUSIN D., KOCHANEK C.S. and KEETON C.R.
2003ApJ...596L..43C 9 10 Strong gravitational lensing and the structure of quasar outflows. CHELOUCHE D.
2003MNRAS.343..639O 78 60 The redshift distribution of gravitational lenses revisited: constraints on galaxy mass evolution. OFEK E.O., RIX H.-W. and MAOZ D.
2003ARep...47..717Z 74 T                   6 2 Optical observations of the gravitational lens
SBS 1520+530 at the Maidanak Observatory. 		ZHELEZNYAK A.P., SERGEEV A.V. and BURKHONOV O.A.
2004A&A...414..425S 9 9 Time-delay quasars: Scales and orders of magnitudes. SAHA P.
2004A&A...428..741F 24 26 A search for clusters and groups of galaxies on the line of sight towards 8 lensed quasars. FAURE C., ALLOIN D., KNEIB J.P., et al.
2004AJ....127.2604S 4 7 58 A portable modeler of lensed quasars. SAHA P. and WILLIAMS L.L.R.
2005A&A...431..103J 1 12 36 An optical time delay for the double gravitational lens system FBQ 0951+2635. JAKOBSSON P., HJORTH J., BURUD I., et al.
2005A&A...436...25E 1         O           14 34 COSMOGRAIL: The COSmological MOnitoring of GRAvItational Lenses. I. How to sample the light curves of gravitationally lensed quasars to measure accurate time delays. EIGENBROD A., COURBIN F., VUISSOZ C., et al.
2005A&A...440...53G viz 113 T K                 8 18 Microlensing in the double quasar
SBS1520+530. 		GAYNULLINA E.R., SCHMIDT R.W., AKHUNOV T., et al.
2005ApJ...623L...5F 42 66 Stellar and total mass in early-type lensing galaxies. FERRERAS I., SAHA P. and WILLIAMS L.L.R.
2005ApJ...624..118M 48 16 Measuring extinction curves of lensing galaxies. McGOUGH C., CLAYTON G.C., GORDON K.D., et al.
2005ApJ...630..142G 36 5 Discovery of a galaxy cluster in the foreground of the wide-separation quasar pair UM 425. GREEN P.J., INFANTE L., LOPEZ S., et al.
2005ApJ...631..145V 1 42 150 Mass-to-Light ratios of field early-type galaxies at z ∼ 1 from ultradeep spectroscopy: evidence for mass-dependent evolution. VAN DER WEL A., FRANX M., VAN DOKKUM P.G., et al.
2005MNRAS.356..323K 15 17 Image reconstruction technique and optical monitoring of the QSO2237+0305 from Maidanak Observatory in 2002-2003. KOPTELOVA E., SHIMANOVSKAYA E., ARTAMONOV B., et al.
2005MNRAS.357..124Y 1 18 50 The Hubble constant from the gravitational lens CLASS B0218+357 using the Advanced Camera for Surveys. YORK T., JACKSON N., BROWNE I.W.A., et al.
2006A&A...450..461S 28 16 COSMOGRAIL: the COSmological MOnitoring of GRAvItational Lenses. IV. Models of prospective time-delay lenses. SAHA P., COURBIN F., SLUSE D., et al.
2006A&A...452...25U 23 16 Time delay of SBS 0909+532. ULLAN A., GOICOECHEA L.J., ZHELEZNYAK A.P., et al.
2006A&A...455L...1P viz 2 7 29 Microlensing variability in time-delay quasars. PARAFICZ D., HJORTH J., BURUD I., et al.
2006A&A...455..773V viz 108222 545 A catalogue of quasars and active nuclei: 12th edition. VERON-CETTY M.-P. and VERON P.
2006ApJ...640...47K 1 26 100 The time delays of gravitational lens HE 0435-1223: an early-type galaxy with a rising rotation curve. KOCHANEK C.S., MORGAN N.D., FALCO E.E., et al.
2006ApJ...644..733G 28 20 Lens-Aided Multi-Angle Spectroscopy (LAMAS) reveals small-scale outflow structure in quasars. GREEN P.J.
2006ApJ...649..616P 2 60 245 Probing the coevolution of supermassive black holes and galaxies using gravitationally lensed quasar hosts. PENG C.Y., IMPEY C.D., RIX H.-W., et al.
2006MNRAS.368..171Z 1 25 79 Testing Bekenstein's relativistic Modified Newtonian Dynamics with lensing data. ZHAO H., BACON D.J., TAYLOR A.N., et al.
2006ApJ...650L..17S 1 24 51 The Hubble time inferred from 10 time delay lenses. SAHA P., COLES J., MACCIO A.V., et al.
2006AstL...32..514K 77 T                   2 8 Analysis of optical light curves for the components of the gravitationally lensed quasar
SBS 1520+530 based on observations with the 1.5-m RTT-150 telescope in 2001-2005. 		KHAMITOV I.M., BIKMAEV I.F., ASLAN Z., et al.
2006A&A...460..647D         O           21 16 A simple analysis of halo density profiles using gravitational lensing time delays. DOBKE B.M. and KING L.J.
2006ApJ...653..936S 1 9 26 Gravitational lensing model degeneracies: is steepness all-important? SAHA P. and WILLIAMS L.L.R.
2007ApJ...660....1O 1 46 101 Gravitational lens time delays: a statistical assessment of lens model dependences and implications for the global Hubble constant. OGURI M.
2007MNRAS.377.1503D 115           X         3 4 15 Steepened inner density profiles of group galaxies via interactions: an N-body analysis. DOBKE B.M., KING L.J. and FELLHAUER M.
2007ApJ...667..645R 1 10 24 Radial density profiles of time-delay lensing galaxies. READ J.I., SAHA P. and MACCIO A.V.
2008A&A...478...95Y 244       D     X         7 108 21 Origin of chromatic features in multiple quasars. Variability, dust, or microlensing. YONEHARA A., HIRASHITA H. and RICHTER P.
2008MNRAS.384..843M 15       D               1 13 9 Validity of strong lensing statistics for constraints on the galaxy evolution model. MATSUMOTO A. and FUTAMASE T.
2008ApJ...673..778A 175 T K A     X         4 37 28 Lens galaxy properties of
SBS 1520+530: insights from Keck spectroscopy and AO imaging. 		AUGER M.W., FASSNACHT C.D., WONG K.C., et al.
2008A&A...480..647E 38           X         1 24 32 Microlensing variability in the gravitationally lensed quasar. QSO 2237+0305 = the Einstein Cross. I. Spectrophotometric monitoring with the VLT. EIGENBROD A., COURBIN F., SLUSE D., et al.
2008ApJ...679...17C 1 11 36 A new estimate of the Hubble time with improved modeling of gravitational lenses. COLES J.
2008MNRAS.387..803C 38           X         1 4 3 The Hubble constant from galaxy lenses: impacts of triaxiality and model degeneracies. CORLESS V.L., DOBKE B.M. and KING L.J.
2008A&A...492L..39S 38           X         1 7 13 A sharp look at the gravitationally lensed quasar SDSS J0806+2006 with laser guide star adaptive optics at the VLT. SLUSE D., COURBIN F., EIGENBROD A., et al.
2009A&A...499..395P viz 38           X         1 30 10 Results of optical monitoring of 5 SDSS double QSOs with the Nordic Optical Telescope. PARAFICZ D., HJORTH J. and ELIASDOTTIR A.
2009RMxAC..35..195F 38           X         1 39 0 Cosmology with gravitational lenses. FALCO E.E.
2009MNRAS.397.1982S 38           X         1 7 8 Microlensing variability in FBQ 0951+2635: short-time-scale events or a long-time-scale fluctuation ? SHALYAPIN V.N., GOICOECHEA L.J., KOPTELOVA E., et al.
2009ApJ...706.1451M 131       D     X   F     3 70 41 Microlensing-based estimate of the mass fraction in compact objects in lens galaxies. MEDIAVILLA E., MUNOZ J.A., FALCO E., et al.
2009NewAR..53..202Z 38           X         1 12 9 Gravitational lensing: From micro to nano. ZAKHAROV A.F.
2010ApJ...711..246F 156             C F     1 15 45 Improved constraints on the gravitational lens Q0957+561. II. Strong lensing. FADELY R., KEETON C.R., NAKAJIMA R., et al.
2008A&ARv..15..289T viz 38           X         1 299 41 The expansion field: the value of H0. TAMMANN G.A., SANDAGE A. and REINDL B.
2010ApJ...712.1129M 61       D     X         2 12 170 The quasar accretion disk size-black hole mass relation. MORGAN C.W., KOCHANEK C.S., MORGAN N.D., et al.
2010ApJ...712.1378P 133       D     X   F     3 20 42 The Hubble constant inferred from 18 time-delay lenses. PARAFICZ D. and HJORTH J.
2010MmSAI..81..138K 310     A D     X C       8 20 3 Multiwavelengths observations of lensed quasars: interband time delays. KOPTELOVA E., OKNYANSKIJ V., ARTAMONOV B., et al.
2010A&A...518A..10V viz 15       D               2 168912 373 A catalogue of quasars and active nuclei: 13th edition. VERON-CETTY M.-P. and VERON P.
2010ApJ...724..400C 39           X         1 9 11 Gravitational nanolensing from subsolar mass dark matter halos. CHEN J. and KOUSHIAPPAS S.M.
2011ApJ...726...84W 79             C       1 14 52 The effect of environment on shear in strong gravitational lenses. WONG K.C., KEETON C.R., WILLIAMS K.A., et al.
2011MNRAS.413.2121M 16       D               1 43 1 Cusped mass density profiles and magnification ratios of double-image gravitational lenses. MUTKA P.T.
2011ApJ...738...96M 16       D               1 90 67 The microlensing properties of a sample of 87 lensed quasars. MOSQUERA A.M. and KOCHANEK C.S.
2011ApJ...740...97L 117           X C       2 27 23 Resolving the baryon-fraction profile in lensing galaxies. LEIER D., FERRERAS I., SAHA P., et al.
2011ApJ...742...67M 468     A D S   X C       11 29 26 A study of gravitational lens chromaticity with the Hubble space telescope. MUNOZ J.A., MEDIAVILLA E., KOCHANEK C.S., et al.
2011A&A...536A..44E 429     A D     X C F     10 22 22 Time delays for eleven gravitationally lensed quasars revisited. EULAERS E. and MAGAIN P.
2012ApJ...744...90B 16       D               1 27 8 A graphics processing unit-enabled, high-resolution cosmological microlensing parameter survey. BATE N.F. and FLUKE C.J.
2012A&A...538A..99S 629     A D     X C       16 72 45 COSMOGRAIL: the COSmological MOnitoring of GRAvItational lenses. X. Modeling based on high-precision astrometry of a sample of 25 lensed quasars: consequences for ellipticity, shear, and astrometric anomalies. SLUSE D., CHANTRY V., MAGAIN P., et al.
2012ApJ...751..106J 16       D               1 24 43 A robust determination of the size of quasar accretion disks using gravitational microlensing. JIMENEZ-VICENTE J., MEDIAVILLA E., MUNOZ J.A., et al.
2012MNRAS.423..676A 1220   K A D S   X C       30 10 13 Resolving the inner structure of QSO discs through fold-caustic-crossing events. ABOLMASOV P. and SHAKURA N.I.
2012ApJ...755...31C viz 16       D               2 311 26 Testing the dark energy with gravitational lensing statistics. CAO S., COVONE G. and ZHU Z.-H.
2012ApJ...756...52M viz 43           X         1 8 67 Further evidence that quasar X-ray emitting regions are compact: X-ray and optical microlensing in the lensed quasar Q J0158-4325. MORGAN C.W., HAINLINE L.J., CHEN B., et al.
2013ApJ...762..122C 40           X         1 7 7 Inclination-dependent active galactic nucleus flux profiles from strong lensing of the Kerr spacetime. CHEN B., DAI X. and BARON E.
2012MNRAS.427.1867A 291       D     X   F     7 21 10 Microlensing evidence for super-Eddington disc accretion in quasars. ABOLMASOV P. and SHAKURA N.I.
2013ApJ...764..160G 16       D               2 53 44 Microlensing of quasar broad emission lines: constraints on broad line region size. GUERRAS E., MEDIAVILLA E., JIMENEZ-VICENTE J., et al.
2013MNRAS.431.1528B 199     A D     X         6 22 4 Bayesian approach to gravitational lens model selection: constraining H0 with a selected sample of strong lenses. BALMES I. and CORASANITI P.S.
2013ApJ...769...53M 82               F     12 82 The structure of the X-ray and optical emitting regions of the lensed quasar Q 2237+0305. MOSQUERA A.M., KOCHANEK C.S., CHEN B., et al.
2014MNRAS.437..600S 16       D               2 40 30 Hubble constant and dark energy inferred from free-form determined time delay distances. SERENO M. and PARAFICZ D.
2014ApJ...788..190W 57       D     X         2 23 24 A comparison of cosmological models using time delay lenses. WEI J.-J., WU X.-F. and MELIA F.
2015ApJ...799...48B 16       D               1 20 5 Strongly lensed jets, time delays, and the value of H0. BARNACKA A., GELLER M.J., DELL'ANTONIO I.P., et al.
2015ApJ...799..149J 16       D               1 64 23 Dark matter mass fraction in lens galaxies: new estimates from microlensing. JIMENEZ-VICENTE J., MEDIAVILLA E., KOCHANEK C.S., et al.
2015ApJ...806..251J 16       D               1 74 17 Probing the dark matter radial profile in lens galaxies and the size of X-ray emitting region in quasars with microlensing. JIMENEZ-VICENTE J., MEDIAVILLA E., KOCHANEK C.S., et al.
2015ARep...59...12S 12 2 Determining the time delays in the gravitational lens PG 1115+080. SHIMANOVSKAYA E.V., OKNYANSKII V.L. and ARTAMONOV B.P.
2015ApJS..219...29M viz 57       D     X         2 10653 13 A spectroscopic survey of the fields of 28 strong gravitational lenses. MOMCHEVA I.G., WILLIAMS K.A., COOL R.J., et al.
2015A&A...580A..38R 179       D     X C       4 50 19 H0 from ten well-measured time delay lenses. RATHNA KUMAR S., STALIN C.S. and PRABHU T.P.
2015MNRAS.452.2423Y 16       D               1 126 10 Cosmological test using strong gravitational lensing systems. YUAN C.C. and WANG F.Y.
2017A&A...597A..49G 42           X         1 11 3 MiNDSTEp differential photometry of the gravitationally lensed quasars WFI 2033-4723 and HE 0047-1756: microlensing and a new time delay. GIANNINI E., SCHMIDT R.W., WAMBSGANSS J., et al.
2017A&A...600A..79A 12 2 Apparent quasar disc sizes in the "bird's nest" paradigm. ABOLMASOV P.
2017AJ....154..114O viz 17       D               3 298 12 The second data release of the KODIAQ survey. O'MEARA J.M., LEHNER N., HOWK J.C., et al.
2017ApJ...850...94W viz 17       D               1 27 7 A spectroscopic survey of the fields of 28 strong gravitational lenses: implications for H0. WILSON M.L., ZABLUDOFF A.I., KEETON C.R., et al.
2017MNRAS.472...90D 17       D               1 146 9 H0LiCOW VII: cosmic evolution of the correlation between black hole mass and host galaxy luminosity. DING X., TREU T., SUYU S.H., et al.
2018ApJ...859...50F 17       D               1 76 2 Microlensing and intrinsic variability of the broad emission lines of lensed quasars. FIAN C., GUERRAS E., MEDIAVILLA E., et al.
2018MNRAS.479.5060L 85             C       1 62 6 Gravitationally lensed quasars in Gaia - II. Discovery of 24 lensed quasars. LEMON C.A., AUGER M.W., McMAHON R.G., et al.
2019MNRAS.483.2275L 17       D               1 16 ~ Reconciling the quasar microlensing disc size problem with a wind model of active galactic nucleus. LI Y.-P., YUAN F. and DAI X.
2019A&A...622A..18S 853     A S   X C       18 4 ~ LoTSS/HETDEX: Disentangling star formation and AGN activity in gravitationally lensed radio-quiet quasars. STACEY H.R., McKEAN J.P., JACKSON N.J., et al.
2020ApJ...895...93C 18       D               1 16 ~ Quasar microlensing variability studies favor shallow accretion disk temperature profiles. CORNACHIONE M.A. and MORGAN C.W.
2020A&A...640A.105M viz 18       D               1 44 ~ COSMOGRAIL. XIX. Time delays in 18 strongly lensed quasars from 15 years of optical monitoring. MILLON M., COURBIN F., BONVIN V., et al.
2020MNRAS.498.2871H 18       D               1 27 ~ A 4 per cent measurement of H0 using the cumulative distribution of strong lensing time delays in doubly imaged quasars. HARVEY D.
2021A&A...653A.109F 112       D     X         3 78 ~ Microlensing of the broad emission lines in 27 gravitationally lensed quasars. Broad line region structure and kinematics. FIAN C., MEDIAVILLA E., MOTTA V., et al.

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