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WASP-72b , the SIMBAD biblio (32 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.04.19CEST23:40:17 |
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 |
---|---|---|---|---|---|---|---|---|---|
2013A&A...552A..82G | 664 | T A | D | X C | 16 | 9 | 24 |
WASP-64b and WASP-72b: two new transiting highly irradiated giant planets. |
GILLON M., ANDERSON D.R., COLLIER-CAMERON A., et al. |
2013A&A...559A..36G | 78 | X | 2 | 13 | 9 | Discovery of WASP-65b and WASP-75b: Two hot Jupiters without highly inflated radii. | GOMEZ MAQUEO CHEW Y., FAEDI F., POLLACCO D., et al. | ||
2014MNRAS.440.1982H | 40 | X | 1 | 23 | 77 | Transiting hot Jupiters from WASP-South, Euler and TRAPPIST: WASP-95b to WASP-101b. | HELLIER C., ANDERSON D.R., COLLIER CAMERON A., et al. | ||
2014ApJ...796...48Z | 16 | D | 1 | 199 | 11 | The ground-based H-, K-, and L-band absolute emission spectra of HD 209458b. | ZELLEM R.T., GRIFFITH C.A., DEROO P., et al. | ||
2014MNRAS.445.4395Y | 16 | D | 1 | 192 | 1 | On the structure and evolution of planets and their host stars - effects of various heating mechanisms on the size of giant gas planets. | YILDIZ M., CELIK ORHAN Z., KAYHAN C., et al. | ||
2016A&A...585A.126W | 44 | X | 1 | 18 | 84 | Three irradiated and bloated hot Jupiters: WASP-76b, WASP-82b, and WASP-90b. | WEST R.G., HELLIER C., ALMENARA J.-M., et al. | ||
2016AJ....152..182H | 16 | D | 1 | 205 | 26 | HAT-P-65b and HAT-P-66b: two transiting inflated hot Jupiters and observational evidence for the reinflation of close-in giant planets. | HARTMAN J.D., BAKOS G.A., BHATTI W., et al. | ||
2017ApJ...834...17C | 17 | D | 1 | 290 | 454 | Probabilistic forecasting of the masses and radii of other worlds. | CHEN J. and KIPPING D. | ||
2017A&A...602A.107B | 16 | D | 3 | 476 | 185 | The GAPS Programme with HARPS-N at TNG. XIV. Investigating giant planet migration history via improved eccentricity and mass determination for 231 transiting planets. | BONOMO A.S., DESIDERA S., BENATTI S., et al. | ||
2018AJ....156..197A | 766 | T A | X C | 17 | 15 | 6 |
Stellar Obliquities and Planetary Alignments (SOPA). I. Spin-orbit measurements of three transiting hot Jupiters: WASP-72b, WASP-100b, and WASP-109b. |
ADDISON B.C., WANG S., JOHNSON M.C., et al. | |
2018ApJS..239...14J | 16 | D | 1 | 1561 | 6 | Revised exoplanet radii and habitability using Gaia data release 2. | JOHNS D., MARTI C., HUFF M., et al. | ||
2019ApJ...874L..31T | 17 | D | 1 | 403 | 62 | Connecting giant planet atmosphere and interior modeling: constraints on atmospheric metal enrichment. | THORNGREN D. and FORTNEY J.J. | ||
2019AJ....157..242E | 17 | D | 1 | 371 | 71 | An updated study of potential targets for Ariel. | EDWARDS B., MUGNAI L., TINETTI G., et al. | ||
2020AJ....159...41T | 17 | D | 1 | 564 | ~ | Estimating planetary mass with deep learning. | TASKER E.J., LANEUVILLE M. and GUTTENBERG N. | ||
2020AJ....159..150P | 316 | D | S X C | 6 | 33 | 51 | The continuing search for evidence of tidal orbital decay of hot Jupiters. | PATRA K.C., WINN J.N., HOLMAN M.J., et al. | |
2020MNRAS.498.2270B | 62 | D | X | 2 | 23 | 56 | Tidal dissipation in evolving low-mass and solar-type stars with predictions for planetary orbital decay. | BARKER A.J. | |
2020AJ....160..155W | 170 | X | 4 | 61 | 45 | Systematic phase curve study of known transiting systems from year one of the TESS mission. | WONG I., SHPORER A., DAYLAN T., et al. | ||
2021A&A...645A...7K | 17 | D | 1 | 1569 | 17 | Determining the true mass of radial-velocity exoplanets with Gaia. Nine planet candidates in the brown dwarf or stellar regime and 27 confirmed planets. | KIEFER F., HEBRARD G., LECAVELIER DES ETANGS A., et al. | ||
2021AJ....162...36W | 783 | A | D | X C | 18 | 80 | ~ | Trends in Spitzer secondary eclipses. | WALLACK N.L., KNUTSON H.A. and DEMING D. |
2021ApJS..254...39G | 17 | D | 1 | 2256 | 165 | The TESS Objects of Interest Catalog from the TESS Prime Mission. | GUERRERO N.M., SEAGER S., HUANG C.X., et al. | ||
2021ApJ...918...16M | 105 | D | X | 3 | 15 | 20 | Orbital decay of short-period exoplanets via tidal resonance locking. | MA L. and FULLER J. | |
2021AJ....162..263H | 17 | D | 1 | 346 | 17 | A uniform search for nearby planetary companions to hot Jupiters in TESS data reveals hot Jupiters are still lonely. | HORD B.J., COLON K.D., KOSTOV V., et al. | ||
2022AJ....164...15E | 18 | D | 1 | 514 | 13 | The Ariel Target List: The Impact of TESS and the Potential for Characterizing Multiple Planets within a System. | EDWARDS B. and TINETTI G. | ||
2022AJ....164...26H | 18 | D | 1 | 120 | 4 | Evidence for the Late Arrival of Hot Jupiters in Systems with High Host-star Obliquities. | HAMER J.H. and SCHLAUFMAN K.C. | ||
2022AJ....164...56L | 108 | D | X | 3 | 46 | ~ | Determining Which Binary Component Hosts the TESS Transiting Planet. | LESTER K.V., HOWELL S.B., CIARDI D.R., et al. | |
2022ApJS..261...26S | 18 | D | 2 | 1893 | 2 | Magnetic Activity and Physical Parameters of Exoplanet Host Stars Based on LAMOST DR7, TESS, Kepler, and K2 Surveys. | SU T., ZHANG L.-Y., LONG L., et al. | ||
2022PASP..134h2001A | 18 | D | 1 | 366 | 39 | Stellar Obliquities in Exoplanetary Systems. | ALBRECHT S.H., DAWSON R.I. and WINN J.N. | ||
2022AJ....164..198M | 45 | X | 1 | 18 | 1 | Revisiting the Transit Timing Variations in the TrES-3 and Qatar-1 Systems with TESS Data. | MANNADAY V.K., THAKUR P., SOUTHWORTH J., et al. | ||
2023AJ....165..104D | 19 | D | 1 | 73 | 1 | Emergent Spectral Fluxes of Hot Jupiters: An Abrupt Rise in Dayside Brightness Temperature Under Strong Irradiation. | DEMING D., LINE M.R., KNUTSON H.A., et al. | ||
2023ApJS..265....4K | 19 | D | 1 | 454 | 2 | ExoClock Project. III. 450 New Exoplanet Ephemerides from Ground and Space Observations. | KOKORI A., TSIARAS A., EDWARDS B., et al. | ||
2023A&A...674A.120A | 19 | D | 1 | 189 | 1 | DREAM II. The spin-orbit angle distribution of close-in exoplanets under the lens of tides. | ATTIA O., BOURRIER V., DELISLE J.-B., et al. | ||
2024ApJS..270...14W | 20 | D | 1 | 333 | ~ | Long-term Variations in the Orbital Period of Hot Jupiters from Transit-timing Analysis Using TESS Survey Data. | WANG W., ZHANG Z., CHEN Z., et al. |