[YDG81] QSO 1115+080 A1 , the SIMBAD biblio

[YDG81] QSO 1115+080 A1 , the SIMBAD biblio (46 results) C.D.S. - SIMBAD4 rel 1.7 - 2021.11.27CET09:44:18


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Title First 3 Authors
2021ApJ...906...26L 47           X         1 3 ~ Impact of Microlensing on observational strategies for gravitational time-delay measurements. LIAO K.
2020MNRAS.492.3047H 18       D               1 45 ~ SHARP - VII. New constraints on the dark matter free-streaming properties and substructure abundance from gravitationally lensed quasars. HSUEH J.-W., ENZI W., VEGETTI S., et al.
2018A&A...616A.183B viz 1 5 5 COSMOGRAIL. XVII. Time delays for the quadruply imaged quasar PG 1115+080. BONVIN V., CHAN J.H.H., MILLON M., et al.
2018MNRAS.481.1115C 145       D     X   F     3 10 ~ Constraining the microlensing effect on time delays with a new time-delay prediction model in H0 measurements. CHEN G.C.-F., CHAN J.H.H., BONVIN V., et al.
2016ApJ...817...56T 181       D     X         5 22 13 HST-COS observations of AGNs. III. Spectral constraints in the Lyman continuum from composite COS/G140L data. TILTON E.M., STEVANS M.L., SHULL J.M., et al.
2016MNRAS.461.3714T 41           X         1 11 3 A simple method to determine time delays in the presence of microlensing: application to HE 0435-1112 and PG 1115+080. TSVETKOVA V.S., SHULGA V.M. and BERDINA L.A.
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.
2015ApJ...799..149J 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.
2014MNRAS.440..870T 56       D     X         2 41 11 Weak lensing by intergalactic ministructures in quadruple lens systems: simulation and detection. TAKAHASHI R. and INOUE K.T.
2013ApJ...764..160G 16       D               3 53 44 Microlensing of quasar broad emission lines: constraints on broad line region size. GUERRAS E., MEDIAVILLA E., JIMENEZ-VICENTE J., et al.
2012A&A...538A..99S 79               F     1 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.
2012MNRAS.426.2978I 39           X         1 31 21 Weak lensing by line-of-sight haloes as the origin of flux-ratio anomalies in quadruply lensed QSOs. INOUE K.T. and TAKAHASHI R.
2011A&A...536A..44E 195           X C       4 22 22 Time delays for eleven gravitationally lensed quasars revisited. EULAERS E. and MAGAIN P.
2011ApJ...729...34B 1 55 113 Sizes and temperature profiles of quasar accretion disks from chromatic microlensing. BLACKBURNE J.A., POOLEY D., RAPPAPORT S., et al.
2010ARA&A..48...87T 80               F     4 25 170 Strong lensing by galaxies. TREU T.
2010ApJ...709..552C 944       D     X   F     24 105 10 Identifying anomalies in gravitational lens time delays. CONGDON A.B., KEETON C.R. and NORDGREN C.E.
2010MNRAS.406.2764T 2476 T   A D S   X   F     62 8 10 PG1115+080: variations of the A2/
A1 flux ratio and new values of the time delays.
TSVETKOVA V.S., VAKULIK V.G., SHULGA V.M., et al.
2009ApJ...697.1892P 208       D S   X C F     3 11 36 The dark-matter fraction in the elliptical galaxy lensing the quasar PG 1115+080. POOLEY D., RAPPAPORT S., BLACKBURNE J., et al.
2009ApJ...699.1720K 785       D     X C F     19 11 61 A new channel for detecting dark matter substructure in galaxies: gravitational lens time delays. KEETON C.R. and MOUSTAKAS L.A.
2009ApJ...706.1451M 207       D     X   F     5 70 41 Microlensing-based estimate of the mass fraction in compact objects in lens galaxies. MEDIAVILLA E., MUNOZ J.A., FALCO E., et al.
2009MNRAS.400L..90V 269           X C       6 7 5 Time delays in PG 1115+080: new estimates. VAKULIK V.G., SHULGA V.M., SCHILD R.E., et al.
2009RMxAC..35..195F 39 0 Cosmology with gravitational lenses. FALCO E.E.
2008A&A...478...95Y 108 21 Origin of chromatic features in multiple quasars. Variability, dust, or microlensing. YONEHARA A., HIRASHITA H. and RICHTER P.
2008ApJ...689..755M 971       D     X C       25 13 76 X-ray and optical microlensing in the lensed quasar PG 1115+080. MORGAN C.W., KOCHANEK C.S., DAI X., et al.
2006ApJ...648...67P 1 12 34 A strong X-ray flux ratio anomaly in the quadruply lensed quasar PG 1115+080. POOLEY D., BLACKBURNE J.A., RAPPAPORT S., et al.
2006ApJS..166..443E 45 43 Extinction curves of lensing galaxies out to z = 1. ELIASDOTTIR A., HJORTH J., TOFT S., et al.
2005ApJ...626...51Y 2 4 20 The lens galaxy in PG 1115+080 is an ellipse. YOO J., KOCHANEK C.S., FALCO E.E., et al.
2005ApJ...627...53C 2 14 67 Subaru mid-infrared imaging of the quadruple lenses PG 1115+080 and B1422+231: limits on substructure lensing. CHIBA M., MINEZAKI T., KASHIKAWA N., et al.
2005MNRAS.357..135P 15 17 The influence of gravitational lensing on the spectra of lensed quasi-stellar objects. POPOVIC L.C. and CHARTAS G.
2004MNRAS.354..343T 13 11 Lens modelling and estimate of H0in quadruply lensed systems. TORTORA C., PIEDIPALUMBO E. and CARDONE V.F.
2003ApJ...584..664K 1 12 65 Analytic cross sections for substructure lensing. KEETON C.R.
2003MNRAS.345.1351E 27 65 Fitting gravitational lenses: truth or delusion. EVANS N.W. and WITT H.J.
2002ApJ...565...17C 4 13 156 Probing dark matter substructure in lens galaxies. CHIBA M.
2002ApJ...571..654D 167 15 A uniform analysis of the Lyα forest at z = 0-5. IV. The clustering and evolution of clouds at z ≤ 1.7. DOBRZYCKI A., BECHTOLD J., SCOTT J., et al.
2002MNRAS.337L...6T 3 9 91 The internal structure of the lens PG1115+080: breaking degeneracies in the value of the Hubble constant. TREU T. and KOOPMANS L.V.E.
2001ApJ...547...50K 1 24 92 The importance of EINSTEIN rings. KOCHANEK C.S., KEETON C.R. and McLEOD B.A.
2000PASJ...52...25I 6 10 Infrared imaging of the gravitational lens PG 1115+080 with the Subaru Telescope. IWAMURO F., MOTOHARA K., MAIHARA T., et al.
1998AJ....115....1T 1 22 104 Redshifts of the gravitational lenses B1422+231 and PG 1115+080. TONRY J.L.
1998ApJ...509..551I 1 26 113 An infrared EINSTEIN ring in the gravitational lens PG 1115+080. IMPEY C.D., FALCO E.E., KOCHANEK C.S., et al.
1997ApJ...475L..85S 6 10 195 The quadruple gravitational lens PG 1115+080: time delays and models. SCHECHTER P.L., BAILYN C.D., BARR R., et al.
1997ApJ...482..604K 4 16 216 Shear and ellipticity in gravitational lenses. KEETON C.R., KOCHANEK C.S. and SELJAK U.
1997ApJ...487...42K 3 9 106 Determining the Hubble constant from the gravitational lens PG 1115+080. KEETON C.R. and KOCHANEK C.S.
1986A&A...158L...5V 14 23 La variabilite du mirage gravitationnel P.G. 1115+080. VANDERRIEST C., WLERICK G., LELIEVRE G., et al.
1986Natur.321..139H 9 24 High-resolution imaging from Mauna Kea : the triple quasar in 0.3-arcs seeing. HENRY J.P. and HEASLEY J.N.
1981ApJ...244..723Y 1 10 72 The triple quasar Q1115+080A, B, C: a quintuple gravitational lens image. YOUNG P., DEVERILL R.S., GUNN J.E., et al.

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2021.11.27-09:44:18

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