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K2-14 , the SIMBAD biblio (16 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.04.23CEST11:45:05 |
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 |
---|---|---|---|---|---|---|---|---|---|
2015ApJ...806..215F | 16 | D | 1 | 67 | 104 | A systematic search for transiting planets in the K2 data. | FOREMAN-MACKEY D., MONTET B.T., HOGG D.W., et al. | ||
2015ApJ...809...25M | 17 | D | 1 | 35 | 123 | Stellar and planetary properties of K2 campaign 1 candidates and validation of 17 planets, including a planet receiving earth-like insolation. | MONTET B.T., MORTON T.D., FOREMAN-MACKEY D., et al. | ||
2016ApJS..222...14V | 16 | D | 1 | 209 | 177 | Planetary candidates from the first year of the K2 mission. | VANDERBURG A., LATHAM D.W., BUCHHAVE L.A., et al. | ||
2016AJ....151..159S | 16 | D | 2 | 76 | 11 | Planet Hunters. X searching for nearby neighbors of 75 planet and eclipsing binary candidates from the K2 Kepler extended mission. | SCHMITT J.R., TOKOVININ A., WANG J., et al. | ||
2016ApJS..226....7C | 16 | D | 2 | 400 | 165 | 197 candidates and 104 validated planets in K2's first five fields. | CROSSFIELD I.J.M., CIARDI D.R., PETIGURA E.A., et al. | ||
2017ApJ...836..167D | 16 | D | 1 | 144 | 30 | Characterizing K2 candidate planetary systems orbiting low-mass stars. I. Classifying low-mass host stars observed during Campaigns 1-7. | DRESSING C.D., NEWTON E.R., SCHLIEDER J.E., et al. | ||
2017MNRAS.465.2634A | 16 | D | 4 | 5400 | 21 | Transit shapes and self-organizing maps as a tool for ranking planetary candidates: application to Kepler and K2. | ARMSTRONG D.J., POLLACCO D. and SANTERNE A. | ||
2017A&A...603A..30S | 16 | D | 2 | 2500 | 58 | Observational evidence for two distinct giant planet populations. | SANTOS N.C., ADIBEKYAN V., FIGUEIRA P., et al. | ||
2017AJ....154..207D | 16 | D | 1 | 118 | 78 | Characterizing K2 candidate planetary systems orbiting low-mass stars. II. Planetary systems observed during campaigns 1-7. | DRESSING C.D., VANDERBURG A., SCHLIEDER J.E., et al. | ||
2018MNRAS.473..345W | 16 | D | 1 | 69 | 1 | Transit visibility zones of the Solar system planets. | WELLS R., POPPENHAEGER K., WATSON C.A., et al. | ||
2019AJ....157..124K | 17 | D | 1 | 603 | 7 | Discovery and Vetting of Exoplanets. I. Benchmarking K2 vetting tools. | KOSTOV V.B., MULLALLY S.E., QUINTANA E.V., et al. | ||
2019ApJS..244...11K | 17 | D | 1 | 2120 | 48 | Detection of hundreds of new planet candidates and eclipsing binaries in K2 campaigns 0-8. | KRUSE E., AGOL E., LUGER R., et al. | ||
2019AJ....158..135R | 17 | D | 4 | 49 | ~ | Characterization of low-mass K2 planet hosts using near-infrared spectroscopy. | RODRIGUEZ MARTINEZ R., BALLARD S., MAYO A., et al. | ||
2020ApJ...890...23L | 17 | D | 1 | 4935 | 35 | Current population statistics do not favor photoevaporation over core-powered mass loss as the dominant cause of the exoplanet radius gap. | LOYD R.O.P., SHKOLNIK E.L., SCHNEIDER A.C., et al. | ||
2021AJ....162..259Z | 17 | D | 1 | 1094 | 12 | Scaling K2. IV. A uniform planet sample for Campaigns 1-8 and 10-18. | ZINK J.K., HARDEGREE-ULLMAN K.K., CHRISTIANSEN J.L., et al. | ||
2023MNRAS.520.5283G | 93 | X | 2 | 91 | 6 | The TIME Table: rotation and ages of cool exoplanet host stars. | GAIDOS E., CLAYTOR Z., DUNGEE R., et al. |