Kepler-177c , the SIMBAD biblio

Kepler-177c , the SIMBAD biblio (39 results) C.D.S. - SIMBAD4 rel 1.8 - 2024.04.23CEST20:03:14

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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
2012ApJ...756..185F viz 15       D               1 1856 44 Transit timing observations from Kepler. V. Transit timing variation candidates in the first sixteen months from polynomial models. FORD E.B., RAGOZZINE D., ROWE J.F., et al.
2011PASP..123..412W viz 15       D               1 2897 398 The Exoplanet Orbit Database. WRIGHT J.T., KAKHOURI O., MARCY G.W., et al.
2013ApJS..204...24B viz 16       D               1 3274 922 Planetary candidates observed by Kepler. III. Analysis of the first 16 months of data. BATALHA N.M., ROWE J.F., BRYSON S.T., et al.
2013ApJ...771..107E viz 16       D               1 756 47 Spectroscopy of faint Kepler mission exoplanet candidate host stars. EVERETT M.E., HOWELL S.B., SILVA D.R., et al.
2014ApJS..210...19B viz 16       D               1 5860 211 Planetary candidates observed by Kepler IV: planet sample from Q1-Q8 (22 months). BURKE C.J., BRYSON S.T., MULLALLY F., et al.
2014ApJ...784...45R viz 16       D               1 1691 388 Validation of Kepler's multiple planet candidates. III. Light curve analysis and announcement of hundreds of new multi-planet systems. ROWE J.F., BRYSON S.T., MARCY G.W., et al.
2014ApJ...790..146F viz 16       D               1 918 579 Architecture of Kepler's multi-transiting systems. II. New investigations with twice as many candidates. FABRYCKY D.C., LISSAUER J.J., RAGOZZINE D., et al.
2014ApJ...791...35L viz 16       D               1 800 137 Robotic laser adaptive optics imaging of 715 Kepler exoplanet candidates using Robo-AO. LAW N.M., MORTON T., BARANEC C., et al.
2015ApJS..217...16R viz 16       D               1 8625 149 Planetary candidates observed by Kepler. V. Planet sample from Q1-Q12 (36 months). ROWE J.F., COUGHLIN J.L., ANTOCI V., et al.
2015ApJ...809....8B viz 16       D               1 112329 282 Terrestrial planet occurrence rates for the Kepler GK dwarf sample. BURKE C.J., CHRISTIANSEN J.L., MULLALLY F., et al.
2016ApJ...820...39J 362     A D     X         10 107 126 Secure mass measurements from transit timing: 10 Kepler exoplanets between 3 and 8 M with diverse densities and incident fluxes. JONTOF-HUTTER D., FORD E.B., ROWE J.F., et al.
2016AJ....152..158T viz 16       D               1 4387 37 Detection of potential transit signals in 17 quarters of Kepler data: results of the final Kepler mission transiting planet search (DR25). TWICKEN J.D., JENKINS J.M., SEADER S.E., et al.
2016AJ....152..181H viz 16       D               1 9279 22 SETI observations of exoplanets with the Allen Telescope Array. HARP G.R., RICHARDS J., TARTER J.C., et al.
2017MNRAS.466.1868C viz 16       D               2 176 21 An overabundance of low-density Neptune-like planets. CUBILLOS P., ERKAEV N.V., JUVAN I., et al.
2017AJ....154....5H viz 41           X         1 231 145 Kepler planet masses and eccentricities from TTV analysis. HADDEN S. and LITHWICK Y.
2017AJ....154..108J viz 16       D               1 3237 137 The California-Kepler Survey. II. Precise physical properties of 2025 Kepler planets and their host stars. JOHNSON J.A., PETIGURA E.A., FULTON B.J., et al.
2018ApJS..234....9O viz 41           X         1 436 14 A spectral approach to transit timing variations. OFIR A., XIE J.-W., JIANG C.-F., et al.
2018ApJ...860...16L 181       D     X C       4 9 3 Modal decomposition of TTV: inferring planet masses and eccentricities. LINIAL I., GILBAUM S. and SARI R.
2018A&A...615A..79V viz 83 9 Kepler Object of Interest Network. I. First results combining ground- and space-based observations of Kepler systems with transit timing variations. VON ESSEN C., OFIR A., DREIZLER S., et al.
2018ApJ...866...99B viz 16       D               1 7129 233 Revised radii of Kepler stars and planet's using Gaia Data Release 2. BERGER T.A., HUBER D., GAIDOS E., et al.
2018AJ....156..264F viz 16       D               1 1909 365 The California-Kepler Survey. VII. Precise planet radii leveraging Gaia DR2 reveal the stellar mass dependence of the Planet radius gap. FULTON B.J. and PETIGURA E.A.
2019ApJ...875...29M viz 17       D               1 2918 72 A spectroscopic analysis of the California-Kepler Survey sample. I. Stellar parameters, planetary radii, and a slope in the radius gap. MARTINEZ C.F., CUNHA K., GHEZZI L., et al.
2019AJ....157..171K viz 17       D               1 4069 2 Visual analysis and demographics of Kepler transit timing variations. KANE M., RAGOZZINE D., FLOWERS X., et al.
2019AJ....157..235C viz 17       D               1 415 7 Observations of the Kepler field with TESS: predictions for planet yield and observable features. CHRIST C.N., MONTET B.T. and FABRYCKY D.C.
2020AJ....159...41T viz 17       D               1 564 ~ Estimating planetary mass with deep learning. TASKER E.J., LANEUVILLE M. and GUTTENBERG N.
2020ApJ...890...93G 61       D     X         2 21 41 Deflating super-puffs: impact of photochemical hazes on the observed mass-radius relationship of low-mass planets. GAO P. and ZHANG X.
2020AJ....159..108V 1491     A D     X C       35 21 41 Diffuser-assisted infrared transit photometry for four dynamically interacting Kepler systems. VISSAPRAGADA S., JONTOF-HUTTER D., SHPORER A., et al.
2020AJ....159..131P 682     A D S   X C       15 14 26 Exploring whether super-puffs can be explained as ringed exoplanets. PIRO A.L. and VISSAPRAGADA S.
2020AJ....160..108B viz 17       D               1 6855 109 The Gaia-Kepler stellar properties catalog. II. Planet radius demographics as a function of stellar mass and age. BERGER T.A., HUBER D., GAIDOS E., et al.
2020AJ....160..201C viz 17       D               1 31 22 A featureless infrared transmission spectrum for the super-puff planet Kepler-79d. CHACHAN Y., JONTOF-HUTTER D., KNUTSON H.A., et al.
2021AJ....161..246J viz 17       D               11 204 12 Following up the Kepler field: masses of targets for transit timing and atmospheric characterization. JONTOF-HUTTER D., WOLFGANG A., FORD E.B., et al.
2021ApJ...921...24S viz 17       D               1 328 1 The occurrence-weighted median planets discovered by transit surveys orbiting solar-type stars and their implications for planet formation and evolution. SCHLAUFMAN K.C. and HALPERN N.D.
2021ApJ...921..142C 17       D               1 15 4 On the importance of wave-planet interactions for the migration of two super-Earths embedded in a protoplanetary disk. CUI Z., PAPALOIZOU J.C.B. and SZUSZKIEWICZ E.
2022AJ....163...91J 242       D     X         6 248 ~ Physical properties and impact parameter variations of Kepler planets from analytic light-curve modeling. JUDKOVSKY Y., OFIR A. and AHARONSON O.
2022AJ....163..128W viz 18       D               1 1570 6 The influence of 10 unique chemical elements in shaping the distribution of Kepler planets. WILSON R.F., CANAS C.I., MAJEWSKI S.R., et al.
2022ApJ...927L...5A 46           X         1 10 15 The First Near-infrared Transmission Spectrum of HIP 41378 f, A Low-mass Temperate Jovian World in a Multiplanet System. ALAM M.K., KIRK J., DRESSING C.D., et al.
2023AJ....165..171W 19       D               1 42 7 Evidence for Hidden Nearby Companions to Hot Jupiters. WU D.-H., RICE M. and WANG S.
2023A&A...675A.174S 93           X         2 11 ~ Oblique rings from migrating exomoons: A possible origin for long-period exoplanets with enlarged radii. SAILLENFEST M., SULIS S., CHARPENTIER P., et al.
2024AJ....167...20Z 20       D               1 230 ~ The Breakthrough Listen Search for Intelligent Life: Detection and Characterization of Anomalous Transits in Kepler Lightcurves. ZUCKERMAN A., DAVENPORT J.R.A., CROFT S., et al.

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