SDSS J160253.98+422824.8 , the SIMBAD biblio

SDSS J160253.98+422824.8 , the SIMBAD biblio (67 results) C.D.S. - SIMBAD4 rel 1.8 - 2024.04.18CEST11:07:04

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Bibcode/DOI Score in Title|Abstract|
Keywords 		in a table in teXt, Caption, ... Nb occurence Nb objects in ref Citations
(from ADS) 		Title First 3 Authors
2004AJ....128..515F 359       D     X C       9 9 348 A survey of z>5.7 quasars in the Sloan Digital Sky Survey. III. Discovery of five additional quasars. FAN X., HENNAWI J.F., RICHARDS G.T., et al.
2005ApJ...628..575W 2 7 59 Improved constraints on the neutral intergalactic hydrogen surrounding quasars at redshifts z > 6. WYITHE J.S.B., LOEB A. and CARILLI C.
2005ApJ...634..715W 2 7 53 Prospects for redshifted 21 cm observations of quasar H II regions. WYITHE J.S.B., LOEB A. and BARNES D.G.
2006A&A...455..773V viz 108224 628 A catalogue of quasars and active nuclei: 12th edition. VERON-CETTY M.-P. and VERON P.
2006AJ....132..117F 31 19 1180 Constraining the evolution of the ionizing background and the epoch of reionization with z∼6 quasars. II. A sample of 19 quasars. FAN X., STRAUSS M.A., BECKER R.H., et al.
2006ApJ...644...86S 1 30 87 Chandra observations of the highest redshift quasars from the Sloan Digital Sky Survey. SHEMMER O., BRANDT W.N., SCHNEIDER D.P., et al.
2006ARA&A..44..415F 88             C       1 23 675 Observational constraints on cosmic reionization. FAN X., CARILLI C.L. and KEATING B.
2006MmSAI..77..635F 18 4 Evolution of high-redshift quasars. FAN X.
2006AJ....132.2127J 4 14 114 Probing the evolution of infrared properties of z∼6 quasars: Spitzer observations. JIANG L., FAN X., HINES D.C., et al.
2006NewAR..50..665F 3 19 128 Evolution of high-redshift quasars. FAN X.-H.
2007AJ....134..617W 1 19 70 Millimeter and radio observations of z ∼ 6 quasars. WANG R., CARILLI C.L., BEELEN A., et al.
2008ApJ...687..848W 17       D               1 35 143 Thermal emission from warm dust in the most distant quasars. WANG R., CARILLI C.L., WAGG J., et al.
2009A&A...494L..25J 16       D               1 30 92 The metallicity of the most distant quasars. JUAREZ Y., MAIOLINO R., MUJICA R., et al.
2009MNRAS.395.1476R 247       D S     C F     5 13 105 A downturn in intergalactic C IV as redshift 6 is approached. RYAN-WEBER E.V., PETTINI M., MADAU P., et al.
2009MNRAS.395.1925M 167       D     X   F     4 15 17 Interpreting the transmission windows of distant quasars. MASELLI A., FERRARA A. and GALLERANI S.
2010ApJ...714..834C 16       D               1 27 74 Ionization near zones associated with quasars at z ∼ 6. CARILLI C.L., WANG R., FAN X., et al.
2010A&A...518A..10V viz 15       D               1 168913 597 A catalogue of quasars and active nuclei: 13th edition. VERON-CETTY M.-P. and VERON P.
2010A&A...523A..85G 16       D               2 39 127 The extinction law at high redshift and its implications. GALLERANI S., MAIOLINO R., JUAREZ Y., et al.
2012RAA....12..865F 33 14 Observations of the first light and the epoch of reionization. FAN X.
2013MNRAS.428..226P viz 16       D               1 23 10 Finding new high-redshift quasars by asking the neighbours. POLSTERER K.L., ZINN P.-C. and GIESEKE F.
2013ApJ...768..173H 156             C F     2 29 14 On inferring extinction laws in z ∼ 6 quasars as signatures of supernova dust. HJORTH J., VREESWIJK P.M., GALL C., et al.
2013ApJ...778..113B 133       D     X C       3 18 17 WISE detections of known QSOs at redshifts greater than six. BLAIN A.W., ASSEF R., STERN D., et al.
2014MNRAS.438.2765C 16       D               1 60 42 The dust content of QSO hosts at high redshift. CALURA F., GILLI R., VIGNALI C., et al.
2014ApJ...785..154L 370       D     X C       9 69 108 Spectral energy distributions of QSOs at z > 5: common active galactic nucleus-heated dust and occasionally strong star-formation. LEIPSKI C., MEISENHEIMER K., WALTER F., et al.
2014AJ....148...14B 17       D               2 44 128 Discovery of eight z ∼ 6 quasars from Pan-STARRS1. BANADOS E., VENEMANS B.P., MORGANSON E., et al.
2015ApJ...804..118B 16       D               1 56 88 Constraining the radio-loud fraction of quasars at z > 5.5. BANADOS E., VENEMANS B.P., MORGANSON E., et al.
2015ApJ...806..109J viz 16       D               1 154 68 Rest-frame optical spectra and black hole masses of 3 <z<6 quasars. JUN H.D., IM M., LEE H.M., et al.
2015ApJ...815...33R viz 16       D               1 814 170 A Hubble diagram for quasars. RISALITI G. and LUSSO E.
2016ApJ...816...85L 56       D     X         2 136 22 The contribution of host galaxies to the infrared energy output of z≳5.0 quasars. LYU J., RIEKE G.H. and ALBERTS S.
2016ApJ...819...24W viz 16       D               1 796 79 A survey of luminous high-redshift quasars with SDSS and WISE. I. Target selection and optical spectroscopy. WANG F., WU X.-B., FAN X., et al.
2016ARA&A..54..313M 89             C       1 25 230 The evolution of the intergalactic medium. McQUINN M.
2016ApJ...833..222J 20       D               1 52 233 The final SDSS high-redshift quasar sample of 52 quasars at z>5.7. JIANG L., McGREER I.D., FAN X., et al.
2017ApJ...840...24E 19       D               3 35 121 Implications of z ∼ 6 quasar proximity zones for the epoch of reionization and quasar lifetimes. EILERS A.-C., DAVIES F.B., HENNAWI J.F., et al.
2017A&A...603A.128N 99       D     X         3 30 74 The X-ray properties of z ∼ 6 luminous quasars. NANNI R., VIGNALI C., GILLI R., et al.
2018ApJS..237....5M 58       D     X         2 93 82 Subaru High-z Exploration of Low-Luminosity Quasars (SHELLQs). IV. Discovery of 41 quasars and luminous galaxies at 5.7 <= z <= 6.9. MATSUOKA Y., IWASAWA K., ONOUE M., et al.
2018ApJ...864...53E 18       D               3 49 104 The opacity of the intergalactic medium measured along quasar sightlines at z ∼ 6. EILERS A.-C., DAVIES F.B. and HENNAWI J.F.
2018MNRAS.479.1055B 101       D         F     2 60 137 New constraints on Lyman-α opacity with a sample of 62 quasars at z > 5.7. BOSMAN S.E.I., FAN X., JIANG L., et al.
2018ApJ...866..159V 16       D               1 98 72 Dust emission in an accretion-rate-limited sample of z >= 6 quasars. VENEMANS B.P., DECARLI R., WALTER F., et al.
2018ApJ...869..150M 17       D               1 111 151 Subaru High-z Exploration of Low-Luminosity Quasars (SHELLQs). V. Quasar luminosity function and contribution to cosmic reionization at z = 6. MATSUOKA Y., STRAUSS M.A., KASHIKAWA N., et al.
2019MNRAS.483...19M 18       D               1 26 32 The role of galaxies and AGNs in reionizing the IGM - II. Metal-tracing the faint sources of reionization at 5 <= z <= 6. MEYER R.A., BOSMAN S.E.I., KAKIICHI K., et al.
2019ApJ...873...35S viz 19       D               1 50 118 Gemini GNIRS near-infrared spectroscopy of 50 quasars at z >= 5.7. SHEN Y., WU J., JIANG L., et al.
2019ApJ...879..117K 17       D               1 52 ~ High star formation rates of low Eddington ratio quasars at z >= 6. KIM Y. and IM M.
2019ApJ...881...23E 17       D               2 19 ~ Anomaly in the opacity of the post-reionization intergalactic medium in the Lyα and Lyβ forest. EILERS A.-C., HENNAWI J.F., DAVIES F.B., et al.
2019ApJ...883..163B viz 17       D               1 199 41 The evolution of O I over 3.2 < z < 6.5: reionization of the circumgalactic medium. BECKER G.D., PETTINI M., RAFELSKI M., et al.
2019A&A...630A.118V 61       D     X         2 28 69 The X-ray properties of z > 6 quasars: no evident evolution of accretion physics in the first Gyr of the Universe. VITO F., BRANDT W.N., BAUER F.E., et al.
2019A&A...631A.120S 84             C       1 53 ~ Quasars as standard candles II. The non-linear relation between UV and X-ray emission at high redshifts. SALVESTRINI F., RISALITI G., BISOGNI S., et al.
2019MNRAS.490.2542P viz 17       D               1 2245 ~ Unveiling the weak radio quasar population at z≥4. PERGER K., FREY S., GABANYI K.E., et al.
2020MNRAS.494..789R viz 17       D               1 489 25 The near and mid-infrared photometric properties of known redshift z >= 5 quasars. ROSS N.P. and CROSS N.J.G.
2020A&A...642A.150L viz 17       D               1 2429 92 Quasars as standard candles. III. Validation of a new sample for cosmological studies. LUSSO E., RISALITI G., NARDINI E., et al.
2020ApJ...903...60I 17       D               1 39 13 Subaru High-z Exploration of Low-Luminosity Quasars (SHELLQs). XI. Proximity zone analysis for faint quasar spectra at z ∼ 6. ISHIMOTO R., KASHIKAWA N., ONOUE M., et al.
2021AJ....161...45O viz 17       D               2 727 ~ The third data release of the KODIAQ survey. O'MEARA J.M., LEHNER N., HOWK J.C., et al.
2021ApJ...906...32Z 104       D       C       2 31 9 Strong Mg II and Fe II absorbers at 2.2 < z < 6.0. ZOU S., JIANG L., SHEN Y., et al.
2021MNRAS.503.2349D 17       D               1 39 20 Infrared emission of z ∼ 6 galaxies: AGN imprints. DI MASCIA F., GALLERANI S., BEHRENS C., et al.
2021MNRAS.506.3946D 17       D               1 41 13 The dust attenuation law in z ∼ 6 quasars. DI MASCIA F., GALLERANI S., FERRARA A., et al.
2021MNRAS.508.1853B 17       D               1 83 68 The mean free path of ionizing photons at 5 < z < 6: evidence for rapid evolution near reionization. BECKER G.D., D'ALOISIO A., CHRISTENSON H.M., et al.
2021A&A...656A.137G viz 17       D               1 493 12 Low frequency radio properties of the z > 5 quasar population. GLOUDEMANS A.J., DUNCAN K.J., ROTTGERING H.J.A., et al.
2021ApJ...923..223Z viz 17       D               2 56 35 Chasing the tail of cosmic reionization with dark gap statistics in the Lyα forest over 5 < z < 6. ZHU Y., BECKER G.D., BOSMAN S.E.I., et al.
2022ApJ...925..121W 108       D     X         3 34 13 Metallicity in Quasar Broad-line Regions at Redshift ∼ 6. WANG S., JIANG L., SHEN Y., et al.
2022MNRAS.514...55B 19       D               1 67 95 Hydrogen reionization ends by z = 5.3: Lyman-α optical depth measured by the XQR-30 sample. BOSMAN S.E.I., DAVIES F.B., BECKER G.D., et al.
2022MNRAS.514.2855P 18       D               2 23 1 Lensing in the darkness: a Bayesian analysis of 22 Chandra sources at z >= 6 shows no evidence of lensing. PACUCCI F., FOORD A., GORDON L., et al.
2022MNRAS.515.5914I 2420     A D     X C F     53 5 5 The physical origin for spatially large scatter of IGM opacity at the end of reionization: The IGM Lyα opacity-galaxy density relation. ISHIMOTO R., KASHIKAWA N., KASHINO D., et al.
2022MNRAS.517.2659W 18       D               1 37 4 Demographics of z ∼ 6 quasars in the black hole mass-luminosity plane. WU J., SHEN Y., JIANG L., et al.
2023A&A...676A.115P 19       D               1 44 ~ Unraveling the formation histories of the first supermassive black holes with the Square Kilometre Array's pulsar timing array. PADMANABHAN H. and LOEB A.
2023ApJ...954..210A 19       D               1 14 ~ Subaru High-z Exploration of Low-luminosity Quasars (SHELLQs). XVIII. The Dark Matter Halo Mass of Quasars at z ∼ 6. ARITA J., KASHIKAWA N., MATSUOKA Y., et al.
2023MNRAS.525.4093G 93               F     1 66 ~ Measuring the photoionization rate, neutral fraction, and mean free path of H I ionizing photons at 4.9 ≤ z ≤ 6.0 from a large sample of XShooter and ESI spectra. GAIKWAD P., HAEHNELT M.G., DAVIES F.B., et al.
2023ApJ...955..115Z 19       D               1 99 ~ Probing Ultralate Reionization: Direct Measurements of the Mean Free Path over 5 < z < 6. ZHU Y., BECKER G.D., CHRISTENSON H.M., et al.
2023ApJ...955..138C 345       D     X C       7 7 ~ The Relationship between IGM Lyα Opacity and Galaxy Density near the End of Reionization. CHRISTENSON H.M., BECKER G.D., D'ALOISIO A., et al.

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