100 research outputs found
High-Spatial-Resolution K-Band Imaging of Select K2 Campaign Fields
NASA's K2 mission began observing fields along the ecliptic plane in 2014.
Each observing campaign lasts approximately 80 days, during which
high-precision optical photometry of select astrophysical targets is collected
by the Kepler spacecraft. Due to the 4 arcsec pixel scale of the Kepler
photometer, significant blending between the observed targets can occur
(especially in dense fields close to the Galactic plane). We undertook a
program to use the Wide Field Camera (WFCAM) on the 3.8 m United Kingdom
InfraRed Telescope (UKIRT) to collect high-spatial-resolution near-infrared
images of targets in select K2 campaign fields, which we report here. These 0.4
arcsec resolution K-band images offer the opportunity to perform a variety of
science, including vetting exoplanet candidates by identifying nearby stars
blended with the target star and estimating the size, color, and type of
galaxies observed by K2.Comment: 2 pages, Published by Research Notes of the American Astronomical
Societ
Constraining the False Positive Rate for Kepler Planet Candidates with Multi-Color Photometry from the GTC
Using the OSIRIS instrument installed on the 10.4-m Gran Telescopio Canarias
(GTC) we acquired multi-color transit photometry of four small (Rp < 5 R_Earth)
short-period (P < 6 days) planet candidates recently identified by the Kepler
space mission. These observations are part of a program to constrain the false
positive rate for small, short-period Kepler planet candidates. Since planetary
transits should be largely achromatic when observed at different wavelengths
(excluding the small color changes due to stellar limb darkening), we use the
observed transit color to identify candidates as either false positives (e.g.,
a blend with a stellar eclipsing binary either in the background/foreground or
bound to the target star) or validated planets. Our results include the
identification of KOI 225.01 and KOI 1187.01 as false positives and the
tentative validation of KOI 420.01 and KOI 526.01 as planets. The probability
of identifying two false positives out of a sample of four targets is less than
1%, assuming an overall false positive rate for Kepler planet candidates of 10%
(as estimated by Morton & Johnson 2011). Therefore, these results suggest a
higher false positive rate for the small, short-period Kepler planet candidates
than has been theoretically predicted by other studies which consider the
Kepler planet candidate sample as a whole. Furthermore, our results are
consistent with a recent Doppler study of short-period giant Kepler planet
candidates (Santerne et al. 2012). We also investigate how the false positive
rate for our sample varies with different planetary and stellar properties. Our
results suggest that the false positive rate varies significantly with orbital
period and is largest at the shortest orbital periods (P < 3 days), where there
is a corresponding rise in the number of detached eclipsing binary stars...
(truncated)Comment: 13 pages, 12 figures, 3 tables; revised for MNRA
Benefits of Ground-Based Photometric Follow-Up for Transiting Extrasolar Planets Discovered with Kepler and CoRoT
Currently, over forty transiting planets have been discovered by ground-based
photometric surveys, and space-based missions like Kepler and CoRoT are
expected to detect hundreds more. Follow-up photometric observations from the
ground will play an important role in constraining both orbital and physical
parameters for newly discovered planets, especially those with small radii (R_p
less than approximately 4 Earth radii) and/or intermediate to long orbital
periods (P greater than approximately 30 days). Here, we simulate transit light
curves from Kepler-like photometry and ground-based observations in the
near-infrared (NIR) to determine how jointly modeling space-based and
ground-based light curves can improve measurements of the transit duration and
planet-star radius ratio. We find that adding observations of at least one
ground-based transit to space-based observations can significantly improve the
accuracy for measuring the transit duration and planet-star radius ratio of
small planets (R_p less than approximately 4 Earth radii) in long-period (~1
year) orbits, largely thanks to the reduced effect of limb darkening in the
NIR. We also demonstrate that multiple ground-based observations are needed to
gain a substantial improvement in the measurement accuracy for small planets
with short orbital periods (~3 days). Finally, we consider the role that higher
ground-based precisions will play in constraining parameter measurements for
typical Kepler targets. Our results can help inform the priorities of transit
follow-up programs (including both primary and secondary transit of planets
discovered with Kepler and CoRoT), leading to improved constraints for transit
durations, planet sizes, and orbital eccentricities.Comment: 29 pages, including 4 tables and 5 figures; accepted for publication
in Ap
Characterizing Transiting Extrasolar Planets with Narrow-Band Photometry and GTC/OSIRIS
We report the first extrasolar planet observations from the 10.4-m Gran
Telescopio Canarias (GTC), currently the world's largest, fully steerable,
single-aperture optical telescope. We used the OSIRIS tunable filter imager on
the GTC to acquire high-precision, narrow-band photometry of the transits of
the giant exoplanets, TrES-2b and TrES-3b. We obtained near-simultaneous
observations in two near-infrared (NIR) wavebands (790.2 and 794.4 +/- 2.0 nm)
specifically chosen to avoid water vapor absorption and skyglow so as to
minimize the atmospheric effects that often limit the precision of ground-based
photometry. Our results demonstrate a very-high photometric precision with
minimal atmospheric contamination despite relatively poor atmospheric
conditions and some technical problems with the telescope. We find the
photometric precision for the TrES-2 observations to be 0.343 and 0.412 mmag
for the 790.2 and 794.4 nm light curves, and the precision of the TrES-3
observations was found to be 0.470 and 0.424 mmag for the 790.2 and 794.4 nm
light curves. We also discuss how future follow-up observations of transiting
planets with this novel technique can contribute to the characterization of
Neptune- and super-Earth-size planets to be discovered by space-based missions
like CoRoT and Kepler, as well as measure atmospheric properties of giant
planets, such as the strength of atmospheric absorption features.Comment: 9 pages, including 3 figures and 2 tables; accepted for publication
in MNRA
A Habitable-zone Earth-sized Planet Rescued from False Positive Status
We report the discovery of an Earth-sized planet in the habitable zone of a
low-mass star called Kepler-1649. The planet, Kepler-1649 c, is
1.06 times the size of Earth and transits its 0.1977 +/-
0.0051 Msun mid M-dwarf host star every 19.5 days. It receives 74 +/- 3 % the
incident flux of Earth, giving it an equilibrium temperature of 234 +/- 20K and
placing it firmly inside the circumstellar habitable zone. Kepler-1649 also
hosts a previously-known inner planet that orbits every 8.7 days and is roughly
equivalent to Venus in size and incident flux. Kepler-1649 c was originally
classified as a false positive by the Kepler pipeline, but was rescued as part
of a systematic visual inspection of all automatically dispositioned Kepler
false positives. This discovery highlights the value of human inspection of
planet candidates even as automated techniques improve, and hints that
terrestrial planets around mid to late M-dwarfs may be more common than those
around more massive stars.Comment: 11 pages, 3 figures, 1 table. Accepted for publication in ApJ
Probing potassium in the atmosphere of HD 80606b with tunable filter transit spectrophotometry from the Gran Telescopio Canarias
We report observations of HD 80606 using the 10.4-m Gran Telescopio Canarias
(GTC) and the OSIRIS tunable filter imager. We acquired very-high-precision,
narrow-band photometry in four bandpasses around the K I absorption feature
during the January 2010 transit of HD 80606b and during out-of-transit
observations conducted in January and April of 2010. We obtained differential
photometric precisions of \sim 2.08e-4 for the in-transit flux ratio measured
at 769.91-nm, which probes the K I line core. We find no significant difference
in the in-transit flux ratio between observations at 768.76 and 769.91 nm. Yet,
we find a difference of \sim 8.09 \pm 2.88e-4 between these observations and
observations at a longer wavelength that probes the K I wing (777.36 nm). While
the presence of red noise in the transit data has a non-negligible effect on
the uncertainties in the flux ratio, the 777.36-769.91 nm colour during transit
shows no effects from red noise and also indicates a significant colour change,
with a mean value of \sim 8.99\pm0.62e-4. This large change in the colour is
equivalent to a \sim 4.2% change in the apparent planetary radius with
wavelength, which is much larger than the atmospheric scale height. This
implies the observations probed the atmosphere at very low pressures as well as
a dramatic change in the pressure at which the slant optical depth reaches
unity between \sim770 and 777 nm. We hypothesize that the excess absorption may
be due to K I in a high-speed wind being driven from the exoplanet's exosphere.
We discuss the viability of this and alternative interpretations, including
stellar limb darkening, starspots, and effects from Earth's atmosphere. We
strongly encourage follow-up observations of HD 80606b to confirm the signal
measured here. Finally, we discuss the future prospects for exoplanet
characterization using tunable filter spectrophotometry.Comment: Accepted to MNRAS; revised version includes some major updates; now
21 pages, with 14 figures and 9 table
The L 98-59 System: Three Transiting, Terrestrial-size Planets Orbiting a Nearby M Dwarf
We report the Transiting Exoplanet Survey Satellite (TESS) discovery of three terrestrial-size planets transiting L 98-59 (TOI-175, TIC 307210830)-a bright M dwarf at a distance of 10.6 pc. Using the Gaia-measured distance and broadband photometry, we find that the host star is an M3 dwarf. Combined with the TESS transits from three sectors, the corresponding stellar parameters yield planet radii ranging from 0.8 R ⊕ to 1.6 R ⊕. All three planets have short orbital periods, ranging from 2.25 to 7.45 days with the outer pair just wide of a 2:1 period resonance. Diagnostic tests produced by the TESS Data Validation Report and the vetting package DAVE rule out common false-positive sources. These analyses, along with dedicated follow-up and the multiplicity of the system, lend confidence that the observed signals are caused by planets transiting L 98-59 and are not associated with other sources in the field. The L 98-59 system is interesting for a number of reasons: the host star is bright (V = 11.7 mag, K = 7.1 mag) and the planets are prime targets for further follow-up observations including precision radial-velocity mass measurements and future transit spectroscopy with the James Webb Space Telescope; the near-resonant configuration makes the system a laboratory to study planetary system dynamical evolution; and three planets of relatively similar size in the same system present an opportunity to study terrestrial planets where other variables (age, metallicity, etc.) can be held constant. L 98-59 will be observed in four more TESS sectors, which will provide a wealth of information on the three currently known planets and have the potential to reveal additional planets in the system.Funding for the TESS mission is provided by NASA’s Science Mission directorate. Funding for the DPAC has been provided
by national institutions, in particular the institutions participating in
the Gaia Multilateral Agreement. The research
leading to these results has received funding from the European
Research Council under the European Union’s Seventh Framework
Programme (FP/2007-2013) ERC grant agreement No. 336480,
and from the ARC grant for Concerted Research Actions, financed
by the Wallonia-Brussels Federatio
An Unusual Transmission Spectrum for the Sub-Saturn KELT-11b Suggestive of a Sub-Solar Water Abundance
We present an optical-to-infrared transmission spectrum of the inflated
sub-Saturn KELT-11b measured with the Transiting Exoplanet Survey Satellite
(TESS), the Hubble Space Telescope (HST) Wide Field Camera 3 G141 spectroscopic
grism, and the Spitzer Space Telescope (Spitzer) at 3.6 m, in addition to
a Spitzer 4.5 m secondary eclipse. The precise HST transmission spectrum
notably reveals a low-amplitude water feature with an unusual shape. Based on
free retrieval analyses with varying molecular abundances, we find strong
evidence for water absorption. Depending on model assumptions, we also find
tentative evidence for other absorbers (HCN, TiO, and AlO). The retrieved water
abundance is generally solar (0.001--0.7 solar
over a range of model assumptions), several orders of magnitude lower than
expected from planet formation models based on the solar system metallicity
trend. We also consider chemical equilibrium and self-consistent 1D
radiative-convective equilibrium model fits and find they too prefer low
metallicities (, consistent with the free retrieval
results). However, all the retrievals should be interpreted with some caution
since they either require additional absorbers that are far out of chemical
equilibrium to explain the shape of the spectrum or are simply poor fits to the
data. Finally, we find the Spitzer secondary eclipse is indicative of full heat
redistribution from KELT-11b's dayside to nightside, assuming a clear dayside.
These potentially unusual results for KELT-11b's composition are suggestive of
new challenges on the horizon for atmosphere and formation models in the face
of increasingly precise measurements of exoplanet spectra.Comment: Accepted to The Astronomical Journal. 31 pages, 20 figures, 7 table
Gravity-darkening Analysis of the Misaligned Hot Jupiter MASCARA-4 b
MASCARA-4 b is a hot Jupiter in a highly misaligned orbit around a rapidly rotating A3V star that was observed for 54 days by the Transiting Exoplanet Survey Satellite (TESS). We perform two analyses of MASCARA-4 b using a stellar gravity-darkened model. First, we measure MASCARA-4 b's misaligned orbital configuration by modeling its TESS photometric light curve. We take advantage of the asymmetry in MASCARA-4 b's transit due to its host star's gravity-darkened surface to measure MASCARA-4 b's true spin–orbit angle to be 104°+7°-13°. We also detect a ~4σ secondary eclipse at 0.491 ± 0.007 orbital phase, proving that the orbit is slightly eccentric. Second, we model MASCARA-4 b's insolation including gravity darkening and find that the planet's received X-ray and ultraviolet flux varies by 4% throughout its orbit. MASCARA-4 b's short-period, polar orbit suggests that the planet likely underwent dramatic orbital evolution to end up in its present-day configuration and that it receives a varying stellar irradiance that perpetually forces the planet out of thermal equilibrium. These findings make MASCARA-4 b an excellent target for follow-up characterization to better understand the orbital evolution and present-day environment of planets around high-mass stars
The K2 & TESS Synergy II: Revisiting 26 systems in the TESS Primary Mission
The legacy of NASA's K2 mission has provided hundreds of transiting
exoplanets that can be revisited by new and future facilities for further
characterization, with a particular focus on studying the atmospheres of these
systems. However, the majority of K2-discovered exoplanets have typical
uncertainties on future times of transit within the next decade of greater than
four hours, making observations less practical for many upcoming facilities.
Fortunately, NASA's Transiting exoplanet Survey Satellite (TESS) mission is
reobserving most of the sky, providing the opportunity to update the
ephemerides for 300 K2 systems. In the second paper of this series, we
reanalyze 26 single-planet, K2-discovered systems that were observed in the
TESS primary mission by globally fitting their K2 and TESS lightcurves
(including extended mission data where available), along with any archival
radial velocity measurements. As a result of the faintness of the K2 sample, 13
systems studied here do not have transits detectable by TESS. In those cases,
we re-fit the K2 lightcurve and provide updated system parameters. For the 23
systems with , we determine the host star parameters
using a combination of Gaia parallaxes, Spectral Energy Distribution (SED)
fits, and MESA Isochrones and Stellar Tracks (MIST) stellar evolution models.
Given the expectation of future TESS extended missions, efforts like the K2 &
TESS Synergy project will ensure the accessibility of transiting planets for
future characterization while leading to a self-consistent catalog of stellar
and planetary parameters for future population efforts.Comment: Accepted for publication in ApJ. 29 pages, 9 figures, 12 table
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