Transiting Exoplanet Survey Satellite

Ricker, G.; Winn, Joshua N.; Vanderspek, R.; Latham, David W.; Bakos, G. Á.; Bean, Jacob L.; Berta-Thompson, Zachory K.; Brown, Timothy M.; Buchhave, Lars A.; Butler, Nathaniel R.; Butler, R. Paul; Chaplin, W. J.; Charbonneau, David; Christensen‐Dalsgaard, J.; Clampin, Mark; Deming, Drake; Doty, J.; Lee, Nathan De; Dressing, Courtney D.; Dunham, E. W.; Endl, Michael; Fressin, François; Ge, Jian; Henning, Thomas; Holman, Matthew J.; Howard, Andrew W.; Ida, Shigeru; Jenkins, Jon M.; Jernigan, G.; Johnson, John Asher; Kaltenegger, Lisa; Kawai, N.; Kjeldsen, H.; Laughlin, Gregory; Levine, Alan M.; Lin, D. N. C.; Lissauer, Jack J.; MacQueen, Phillip J.; Marcy, Geoffrey W.; McCullough, P. R.; Morton, Timothy; Narita, Norio; Paegert, Martin; Πάλλη, Ε.; Pepe, F.; Pepper, Joshua; Quirrenbach, A.; Rinehart, Stephen A.; Sasselov, Dimitar; Sato, Bun’ei; Seager, Sara; Sozzetti, A.; Stassun, Keivan G.; Sullivan, Peter; Szentgyorgyi, Andrew; Torres, Guillermo; Udry, S.; Villaseñor, J.

doi:10.1117/1.jatis.1.1.014003

Cited by 2,816 publications

(1,638 citation statements)

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“…A southern analog to Robo-AO, mounted on the Southern Astrophysical Research Telescope (SOAR) at CTIO and capable of twice HST resolution imaging, is also in development. With unmatched efficiency, Robo-AO and its lineage of instruments are uniquely able to perform high-acuity imaging of the hundreds of K2 ) planetary candidates, ground-based transit surveys such as MEarth (Nutzman & Charbonneau 2008), KELT (Pepper et al 2007, HATNet (Bakos et al 2004), SuperWASP (Pollacco et al 2006), NGTS (Wheatley et al 2013), XO (McCullough et al 2005), and the Evryscope , as well as the thousands of expected exoplanet hosts discovered by the forthcoming NASA Transiting Exoplanet Survey Satellite (TESS, Ricker et al 2015) and ESA PLAnetary Transits and Oscillations of stars 2.0 (PLATO, Rauer et al 2014) missions.…”

Section: Resultsmentioning

confidence: 99%

Robo-Ao Kepler Planetary Candidate Survey. Iii. Adaptive Optics Imaging of 1629 Kepler Exoplanet Candidate Host Stars

Ziegler

Law

Morton

et al. 2017

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The Robo-AO Kepler Planetary Candidate Survey is observing every Kepler planet candidate host star with laser adaptive optics imaging to search for blended nearby stars, which may be physically associated companions and/or responsible for transit false positives. In this paper, we present the results of our search for stars nearby 1629 Kepler planet candidate hosts. With survey sensitivity to objects as close as ∼0 15, and magnitude differences Δm 6, we find 223 stars in the vicinity of 206 target KOIs; 209 of these nearby stars have not been previously imaged in high resolution. We measure an overall nearby-star probability for Kepler planet candidates of  12.6% 0.9% at separations between 0 15 and 4 0. Particularly interesting KOI systems are discussed, including 26 stars with detected companions that host rocky, habitable zone candidates and five new candidate planet-hosting quadruple star systems. We explore the broad correlations between planetary systems and stellar binarity, using the combined data set of Baranec et al. and this paper. Our previous 2σ result of a low detected nearby star fraction of KOIs hosting close-in giant planets is less apparent in this larger data set. We also find a significant correlation between detected nearby star fraction and KOI number, suggesting possible variation between early and late Kepler data releases.

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Section: Resultsmentioning

confidence: 99%

Robo-Ao Kepler Planetary Candidate Survey. Iii. Adaptive Optics Imaging of 1629 Kepler Exoplanet Candidate Host Stars

Ziegler

Law

Morton

et al. 2017

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“…The upcoming TESS mission (Ricker et al 2015) is expected to yield more than 1500 total exoplanet discoveries, but it is also estimated that TESS will detect over 1000 falsepositive signals (Sullivan et al 2015). Even so, one (out of three) of the level-one baseline science requirements for TESS is to measure the masses of 50 planets with R p <4 R ⊕ .…”

Section: Future Applicationsmentioning

confidence: 99%

275 Candidates and 149 Validated Planets Orbiting Bright Stars in K2 Campaigns 0–10

Mayo

Vanderburg

Latham

et al. 2018

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172

233

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Since 2014, NASA's K2 mission has observed large portions of the ecliptic plane in search of transiting planets and has detected hundreds of planet candidates. With observations planned until at least early 2018, K2 will continue to identify more planet candidates. We present here 275 planet candidates observed during Campaigns 0-10 of the K2 mission that are orbiting stars brighter than 13 mag (in Kepler band) and for which we have obtained highresolution spectra (R = 44,000). These candidates are analyzed using the vespa package in order to calculate their false-positive probabilities (FPP). We find that 149 candidates are validated with an FPP lower than 0.1%, 39 of which were previously only candidates and 56 of which were previously undetected. The processes of data reduction, candidate identification, and statistical validation are described, and the demographics of the candidates and newly validated planets are explored. We show tentative evidence of a gap in the planet radius distribution of our candidate sample. Comparing our sample to the Kepler candidate sample investigated by Fulton et al., we conclude that more planets are required to quantitatively confirm the gap with K2 candidates or validated planets. This work, in addition to increasing the population of validated K2 planets by nearly 50% and providing new targets for follow-up observations, will also serve as a framework for validating candidates from upcoming K2 campaigns and the Transiting Exoplanet Survey Satellite, expected to launch in 2018.

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“…Transit spectroscopy means that no angular resolution is required and detailed performance studies show that a telescope collecting area of 0.64 m 2 is sufficient to achieve the necessary observations on all the ARIEL targets within the mission lifetime. ARIEL will carry a single, passively-cooled, highly capable and stable spectrometer [4], to be launched in 2018) and will build on the success of ESA exoplanet missions such as Cheops [5] and PLATO [6], which will provide an optimized target list prior to launch.…”

Section: Introductionmentioning

confidence: 99%