The Kepler Mission has recently announced the discovery of Kepler-10 b, the smallest exoplanet discovered to date and the first rocky planet found by the spacecraft. A second, 45-day period transit-like signal present in the photometry from the first eight months of data could not be confirmed as being caused by a planet at the time of that announcement. Here we apply the light-curve modeling technique known as BLENDER to explore the possibility that the signal might be due to an astrophysical false positive (blend). To aid in this analysis we report the observation of two transits with the Spitzer Space Telescope at 4.5 \$\backslash$mu\m. When combined they yield a transit depth of 344 $\backslash$pm 85 ppm that is consistent with the depth in the Kepler passband (376 $\backslash$pm 9 ppm, ignoring limb darkening), which rules out blends with an eclipsing binary of a significantly different color than the target. Using these observations along with other constraints from high resolution imaging and spectroscopy we are able to exclude the vast majority of possible false positives. We assess the likelihood of the remaining blends, and arrive conservatively at a false alarm rate of 1.6 $\backslash$times 10-5 that is small enough to validate the candidate as a planet (designated Kepler-10 c) with a very high level of confidence. The radius of this object is measured to be Rp = 2.227+0.052 -0.057 Earth radii. Kepler-10 c represents another example (with Kepler-9 d and Kepler-11 g) of statistical "validation" of a transiting exoplanet, as opposed to the usual "confirmation" that can take place when the Doppler signal is detected or transit timing variations are measured. It is anticipated that many of Kepler's smaller candidates will receive a similar treatment since dynamical confirmation may be difficult or impractical with the sensitivity of current instrumentation.
%0 Journal Article
%1 Fressin2011
%A Fressin, Francois
%A Torres, Guillermo
%A Desert, Jean-Michel
%A Charbonneau, David
%A Batalha, Natalie M.
%A Fortney, Jonathan J
%A Rowe, Jason F
%A Allen, Christopher
%A Borucki, William J
%A Brown, Timothy M
%A Bryson, Stephen T
%A Ciardi, David R
%A Cochran, William D
%A Deming, Drake
%A Dunham, Edward W
%A Fabrycky, Daniel C.
%A Gautier, Thomas N.
%A Gilliland, Ronald L.
%A Henze, Christopher E.
%A Holman, Matthew J.
%A Howell, Steve B.
%A Jenkins, Jon M.
%A Kinemuchi, Karen
%A Knutson, Heather
%A Koch, David G.
%A Latham, David W.
%A Lissauer, Jack J.
%A Marcy, Geoffrey W.
%A Ragozzine, Darin
%A Sasselov, Dimitar D.
%A Still, Martin
%A Tenenbaum, Peter
%A Uddin, Kamal
%D 2011
%K 2011 a:Marcy kepler kepler10 planets rocky
%N May
%T Kepler-10c, a 2.2-Earth radius transiting planet in a multiple system
%U http://arxiv.org/abs/1105.4647
%X The Kepler Mission has recently announced the discovery of Kepler-10 b, the smallest exoplanet discovered to date and the first rocky planet found by the spacecraft. A second, 45-day period transit-like signal present in the photometry from the first eight months of data could not be confirmed as being caused by a planet at the time of that announcement. Here we apply the light-curve modeling technique known as BLENDER to explore the possibility that the signal might be due to an astrophysical false positive (blend). To aid in this analysis we report the observation of two transits with the Spitzer Space Telescope at 4.5 \$\backslash$mu\m. When combined they yield a transit depth of 344 $\backslash$pm 85 ppm that is consistent with the depth in the Kepler passband (376 $\backslash$pm 9 ppm, ignoring limb darkening), which rules out blends with an eclipsing binary of a significantly different color than the target. Using these observations along with other constraints from high resolution imaging and spectroscopy we are able to exclude the vast majority of possible false positives. We assess the likelihood of the remaining blends, and arrive conservatively at a false alarm rate of 1.6 $\backslash$times 10-5 that is small enough to validate the candidate as a planet (designated Kepler-10 c) with a very high level of confidence. The radius of this object is measured to be Rp = 2.227+0.052 -0.057 Earth radii. Kepler-10 c represents another example (with Kepler-9 d and Kepler-11 g) of statistical "validation" of a transiting exoplanet, as opposed to the usual "confirmation" that can take place when the Doppler signal is detected or transit timing variations are measured. It is anticipated that many of Kepler's smaller candidates will receive a similar treatment since dynamical confirmation may be difficult or impractical with the sensitivity of current instrumentation.
@article{Fressin2011,
abstract = {The Kepler Mission has recently announced the discovery of Kepler-10 b, the smallest exoplanet discovered to date and the first rocky planet found by the spacecraft. A second, 45-day period transit-like signal present in the photometry from the first eight months of data could not be confirmed as being caused by a planet at the time of that announcement. Here we apply the light-curve modeling technique known as BLENDER to explore the possibility that the signal might be due to an astrophysical false positive (blend). To aid in this analysis we report the observation of two transits with the Spitzer Space Telescope at 4.5 \{$\backslash$mu\}m. When combined they yield a transit depth of 344 $\backslash$pm 85 ppm that is consistent with the depth in the Kepler passband (376 $\backslash$pm 9 ppm, ignoring limb darkening), which rules out blends with an eclipsing binary of a significantly different color than the target. Using these observations along with other constraints from high resolution imaging and spectroscopy we are able to exclude the vast majority of possible false positives. We assess the likelihood of the remaining blends, and arrive conservatively at a false alarm rate of 1.6 $\backslash$times 10-5 that is small enough to validate the candidate as a planet (designated Kepler-10 c) with a very high level of confidence. The radius of this object is measured to be Rp = 2.227+0.052 -0.057 Earth radii. Kepler-10 c represents another example (with Kepler-9 d and Kepler-11 g) of statistical "validation" of a transiting exoplanet, as opposed to the usual "confirmation" that can take place when the Doppler signal is detected or transit timing variations are measured. It is anticipated that many of Kepler's smaller candidates will receive a similar treatment since dynamical confirmation may be difficult or impractical with the sensitivity of current instrumentation.},
added-at = {2013-08-03T21:51:48.000+0200},
archiveprefix = {arXiv},
arxivid = {1105.4647},
author = {Fressin, Francois and Torres, Guillermo and Desert, Jean-Michel and Charbonneau, David and Batalha, Natalie M. and Fortney, Jonathan J and Rowe, Jason F and Allen, Christopher and Borucki, William J and Brown, Timothy M and Bryson, Stephen T and Ciardi, David R and Cochran, William D and Deming, Drake and Dunham, Edward W and Fabrycky, Daniel C. and Gautier, Thomas N. and Gilliland, Ronald L. and Henze, Christopher E. and Holman, Matthew J. and Howell, Steve B. and Jenkins, Jon M. and Kinemuchi, Karen and Knutson, Heather and Koch, David G. and Latham, David W. and Lissauer, Jack J. and Marcy, Geoffrey W. and Ragozzine, Darin and Sasselov, Dimitar D. and Still, Martin and Tenenbaum, Peter and Uddin, Kamal},
biburl = {https://www.bibsonomy.org/bibtex/2eec61beb233543ed0a8984a21e3f6e2d/danielcarrera},
eprint = {1105.4647},
file = {:home/daniel/Papers/Planets-Observed/1105.AstroPh - Fressin - Kepler 10C, A 2.2 Earth mass planet in multiple system.pdf:pdf},
interhash = {2fc98c2b3b3b286a14af4aebe90d0b1c},
intrahash = {eec61beb233543ed0a8984a21e3f6e2d},
keywords = {2011 a:Marcy kepler kepler10 planets rocky},
month = may,
number = {May},
timestamp = {2014-07-18T13:38:45.000+0200},
title = {{Kepler-10c, a 2.2-Earth radius transiting planet in a multiple system}},
url = {http://arxiv.org/abs/1105.4647},
year = 2011
}