Your search keyword '"Howard, AW"' showing total 170 results

1. Transmission Spectroscopy for the Warm Sub-Neptune HD 3167c: Evidence for Molecular Absorption and a Possible High-metallicity Atmosphere

Author

Mikal-Evans, T, Crossfield, IJM, Benneke, B, Kreidberg, L, Moses, J, Morley, CV, Thorngren, D, Molli re, P, Hardegree-Ullman, KK, Brewer, J, Christiansen, JL, Ciardi, DR, Dragomir, D, Dressing, C, Fortney, JJ, Gorjian, V, Greene, TP, Hirsch, LA, Howard, AW, Howell, SB, Isaacson, H, Kosiarek, MR, Krick, J, Livingston, JH, Lothringer, JD, Morales, FY, Petigura, EA, Schlieder, JE, and Werner, M

Subjects

Exoplanet astronomy, Exoplanets, Exoplanet atmospheres, astro-ph.EP, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

We present a transmission spectrum for the warm (500-600 K) sub-Neptune HD 3167c obtained using the Hubble Space Telescope Wide Field Camera 3 infrared spectrograph. We combine these data, which span the 1.125-1.643 μm wavelength range, with broadband transit measurements made using Kepler/K2 (0.6-0.9 μm) and Spitzer/IRAC (4-5 μm). We find evidence for absorption by at least one of H2O, HCN, CO2, and CH4 (Bayes factor 7.4; 2.5σ significance), although the data precision does not allow us to unambiguously discriminate between these molecules. The transmission spectrum rules out cloud-free hydrogen-dominated atmospheres with metallicities ≤100 solar at >5.8σ confidence. In contrast, good agreement with the data is obtained for cloud-free models assuming metallicities >700 solar. However, for retrieval analyses that include the effect of clouds, a much broader range of metallicities (including subsolar) is consistent with the data, due to the degeneracy with cloud-top pressure. Self-consistent chemistry models that account for photochemistry and vertical mixing are presented for the atmosphere of HD 3167c. The predictions of these models are broadly consistent with our abundance constraints, although this is primarily due to the large uncertainties on the latter. Interior structure models suggest that the core mass fraction is >40%, independent of a rock or water core composition, and independent of atmospheric envelope metallicity up to 1000 solar. We also report abundance measurements for 15 elements in the host star, showing that it has a very nearly solar composition.

Published

2021

2. Characterizing K2 Candidate Planetary Systems Orbiting Low-mass Stars. III. A High Mass and Low Envelope Fraction for the Warm Neptune K2-55b

Author

Dressing, CD, Sinukoff, E, Fulton, BJ, Lopez, ED, Beichman, CA, Howard, AW, Knutson, HA, Werner, M, Benneke, B, Crossfield, IJM, Isaacson, H, Krick, J, Gorjian, V, Livingston, J, Petigura, EA, Schlieder, JE, Akeson, RL, Batygin, K, Christiansen, JL, Ciardi, DR, Crepp, JR, Gonzales, EJ, Hardegree-Ullman, K, Hirsch, LA, Kosiarek, M, and Weiss, LM

Subjects

planets and satellites: composition, planets and satellites: formation, planets and satellites: individual, techniques: photometric, techniques: radial velocities, astro-ph.EP, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

K2-55b is a Neptune-sized planet orbiting a K7 dwarf with a radius of 0.715-0.040+0.043, a mass of 0.688±0.069 M, and an effective temperature of 4300-100+107 K. Having characterized the host star using near-infrared spectra obtained at IRTF/SpeX, we observed a transit of K2-55b with Spitzer/Infrared Array Camera (IRAC) and confirmed the accuracy of the original K2 ephemeris for future follow-up transit observations. Performing a joint fit to the Spitzer/IRAC and K2 photometry, we found a planet radius of 4.41-0.28+0.32 R, an orbital period of 2.849272656.42×10-66.87×10-6 days, and an equilibrium temperature of roughly 900 K. We then measured the planet mass by acquiring 12 radial velocity (RV) measurements of the system using the High Resolution Echelle Spectrometer on the 10 m Keck I Telescope. Our RV data set precisely constrains the mass of K2-55b to 43.13-5.80+5.98 M, indicating that K2-55b has a bulk density of 2.8-0.6+0.8g cm-3 and can be modeled as a rocky planet capped by a modest H/He envelope (Menvelope=12±3% Mp). K2-55b is denser than most similarly sized planets, raising the question of whether the high planetary bulk density of K2-55b could be attributed to the high metallicity of K2-55. The absence of a substantial volatile envelope despite the high mass of K2-55b poses a challenge to current theories of gas giant formation. We posit that K2-55b may have escaped runaway accretion by migration, late formation, or inefficient core accretion, or that K2-55b was stripped of its envelope by a late giant impact.

Published

2018

3. The Kepler Follow-up Observation Program. II. Stellar Parameters from Medium- and High-resolution Spectroscopy

Author

Furlan, E, Ciardi, DR, Cochran, WD, Everett, ME, Latham, DW, Marcy, GW, Buchhave, LA, Endl, M, Isaacson, H, Petigura, EA, Gautier, TN, Huber, D, Bieryla, A, Borucki, WJ, Brugamyer, E, Caldwell, C, Cochran, A, Howard, AW, Howell, SB, Johnson, MC, MacQueen, PJ, Quinn, SN, Robertson, P, Mathur, S, and Batalha, NM

Subjects

planets and satellites: fundamental parameters, stars: fundamental parameters, surveys, techniques: spectroscopic, astro-ph.SR, astro-ph.EP, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Astronomy & Astrophysics

Abstract

We present results from spectroscopic follow-up observations of stars identified in the Kepler field and carried out by teams of the Kepler Follow-up Observation Program. Two samples of stars were observed over 6 yr (2009-2015): 614 standard stars (divided into "platinum" and "gold" categories) selected based on their asteroseismic detections and 2667 host stars of Kepler Objects of Interest (KOIs), most of them planet candidates. Four data analysis pipelines were used to derive stellar parameters for the observed stars. We compare the T eff, log(g), and [Fe/H] values derived for the same stars by different pipelines; from the average of the standard deviations of the differences in these parameter values, we derive error floors of ∼100 K, 0.2 dex, and 0.1 dex for T eff, log(g), and [Fe/H], respectively. Noticeable disagreements are seen mostly at the largest and smallest parameter values (e.g., in the giant star regime). Most of the log(g) values derived from spectra for the platinum stars agree on average within 0.025 dex (but with a spread of 0.1-0.2 dex) with the asteroseismic log(g) values. Compared to the Kepler Input Catalog (KIC), the spectroscopically derived stellar parameters agree within the uncertainties of the KIC but are more precise and thus an important contribution toward deriving more reliable planetary radii.

Published

2018

4. Validation and Initial Characterization of the Long-period Planet Kepler-1654 b

Author

Beichman, CA, Giles, HAC, Akeson, R, Ciardi, D, Christiansen, J, Isaacson, H, Marcy, GM, Sinukoff, E, Greene, T, Fortney, JJ, Crossfield, I, Hu, R, Howard, AW, Petigura, EA, and Knutson, HA

Subjects

planetary systems, planets and satellites: detection, astro-ph.EP, astro-ph.SR, Astronomical and Space Sciences, Astronomy & Astrophysics

Abstract

Fewer than 20 transiting Kepler planets have periods longer than one year. Our early search of the Kepler light curves revealed one such system, Kepler-1654b (originally KIC 8410697b), which shows exactly two transit events and whose second transit occurred only five days before the failure of the second of two reaction wheels brought the primary Kepler mission to an end. A number of authors have also examined light curves from the Kepler mission searching for long-period planets and identified this candidate. Starting in 2014 September, we began an observational program of imaging, reconnaissance spectroscopy, and precision radial velocity (RV) measurements that confirm with a high degree of confidence that Kepler-1654b is a bona fide transiting planet orbiting a mature G5V star (T eff = 5580 K, [Fe/H] = -0.08) with a semimajor axis of 2.03 au, a period of 1047.84 days, and a radius of 0.82 ±0.02 R Jup. RV measurements using Keck's HIRES spectrometer obtained over 2.5 years set a limit to the planet's mass of

Published

2018

5. K2-137 b: an Earth-sized planet in a 4.3-h orbit around an M-dwarf

Author

Smith, AMS, Cabrera, J, Csizmadia, Sz, Dai, F, Gandolfi, D, Hirano, T, Winn, JN, Albrecht, S, Alonso, R, Antoniciello, G, Barragán, O, Deeg, H, Eigmüller, Ph, Endl, M, Erikson, A, Fridlund, M, Fukui, A, Grziwa, S, Guenther, EW, Hatzes, AP, Hidalgo, D, Howard, AW, Isaacson, H, Korth, J, Kuzuhara, M, Livingston, J, Narita, N, Nespral, D, Nowak, G, Palle, E, Pätzold, M, Persson, CM, Petigura, E, Prieto-Arranz, J, Rauer, H, Ribas, I, and Van Eylen, V

Subjects

planets and satellites: detection, planets and satellites: individual: K2-137 b, astro-ph.EP, Astronomical and Space Sciences, Astronomy & Astrophysics

Abstract

We report the discovery in K2's Campaign 10 of a transiting terrestrial planet in an ultrashort- period orbit around an M3-dwarf. K2-137 b completes an orbit in only 4.3 h, the second shortest orbital period of any known planet, just 4 min longer than that of KOI 1843.03, which also orbits an M-dwarf. Using a combination of archival images, adaptive optics imaging, radial velocity measurements, and light-curve modelling, we show that no plausible eclipsing binary scenario can explain the K2 light curve, and thus confirm the planetary nature of the system. The planet, whose radius we determine to be 0.89 ± 0.09 R⊕, and which must have an iron mass fraction greater than 0.45, orbits a star of mass 0.463 ± 0.052 M⊙ and radius 0.442 ± 0.044 R⊙.

Published

2018

6. Panoramic optical and near-infrared SETI instrument: Optical and structural design concepts

Author

Maire, J, Wright, SA, Cosens, M, Antonio, FP, Aronson, ML, Chaim-Weismann, SA, Drake, FD, Horowitz, P, Howard, AW, Marcy, GW, Raffanti, R, Siemion, APV, Stone, RPS, Treffers, RR, Uttamchandani, A, and Werthimer, D

Subjects

Technosignatures, Search for ExtraTerrestrial Intelligence, All-sky, Geodesic dome, Fresnel lenses, astro-ph.IM

Abstract

We propose a novel instrument design to greatly expand the current optical and near-infrared SETI search pa- rameter space by monitoring the entire observable sky during all observable time. This instrument is aimed to search for technosignatures by means of detecting nano- to micro-second light pulses that could have been emitted, for instance, for the purpose of interstellar communications or energy transfer. We present an instru- ment conceptual design based upon an assembly of 198 refracting 0.5-m telescopes tessellating two geodesic domes. This design produces a regular layout of hexagonal collecting apertures that optimizes the instrument footprint, aperture diameter, instrument sensitivity and total field-of-view coverage. We also present the optical performance of some Fresnel lenses envisaged to develop a dedicated panoramic SETI (PANOSETI) observatory that will dramatically increase sky-area searched (pi steradians per dome), wavelength range covered, number of stellar systems observed, interstellar space examined and duration of time monitored with respect to previous optical and near-infrared technosignature finders.

Published

2018

7. Panoramic optical and near-infrared SETI instrument: Overall specifications and science program

Author

Wright, SA, Horowitz, P, Maire, J, Werthimer, D, Antonio, F, Aronson, M, Chaim-Weismann, S, Cosens, M, Drake, FD, Howard, AW, Marcy, GW, Raffanti, R, Siemion, APV, Stone, RPS, Treffers, RR, and Uttamchandani, A

Subjects

techniques: high time resolution, instrumentation: detectors, instrumentation: telescopes, instrumentation: novel, astrophysical transients, astrophysical variable sources, astrobiology, technosignatures, SETI, astro-ph.IM

Abstract

We present overall specifications and science goals for a new optical and near-infrared (350 - 1650 nm) instru- ment designed to greatly enlarge the current Search for Extraterrestrial Intelligence (SETI) phase space. The Pulsed All-sky Near-infrared Optical SETI (PANOSETI) observatory will be a dedicated SETI facility that aims to increase sky area searched, wavelengths covered, number of stellar systems observed, and duration of time monitored. This observatory will offer an "all-observable-sky" optical and wide-field near-infrared pulsed tech- nosignature and astrophysical transient search that is capable of surveying the entire northern hemisphere. The final implemented experiment will search for transient pulsed signals occurring between nanosecond to second time scales. The optical component will cover a solid angle 2.5 million times larger than current SETI targeted searches, while also increasing dwell time per source by a factor of 10,000. The PANOSETI instrument will be the first near-infrared wide-field SETI program ever conducted. The rapid technological advance of fast-response optical and near-infrared detector arrays (i.e., Multi-Pixel Photon Counting; MPPC) make this program now feasible. The PANOSETI instrument design uses innovative domes that house 100 Fresnel lenses, which will search concurrently over 8,000 square degrees for transient signals (see Maire et al. and Cosens et al., this conference). In this paper, we describe the overall instrumental specifications and science objectives for PANOSETI.

Published

2018

8. Characterizing K2 Candidate Planetary Systems Orbiting Low-mass Stars. II. Planetary Systems Observed during Campaigns 1-7

Author

Dressing, CD, Vanderburg, A, Schlieder, JE, Crossfield, IJM, Knutson, HA, Newton, ER, Ciardi, DR, Fulton, BJ, Gonzales, EJ, Howard, AW, Isaacson, H, Livingston, J, Petigura, EA, Sinukoff, E, Everett, M, Horch, E, and Howell, SB

Subjects

planetary systems, planets and satellites: fundamental parameters, stars: fundamental parameters, stars: late-type, stars: low-mass, techniques: spectroscopic, astro-ph.EP, astro-ph.SR, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

We recently used near-infrared spectroscopy to improve the characterization of 76 low-mass stars around which K2 had detected 79 candidate transiting planets. 29 of these worlds were new discoveries that had not previously been published. We calculate the false positive probabilities that the transit-like signals are actually caused by non-planetary astrophysical phenomena and reject five new transit-like events and three previously reported events as false positives. We also statistically validate 17 planets (7 of which were previously unpublished), confirm the earlier validation of 22 planets, and announce 17 newly discovered planet candidates. Revising the properties of the associated planet candidates based on the updated host star characteristics and refitting the transit photometry, we find that our sample contains 21 planets or planet candidates with radii smaller than 1.25 R ⊕, 18 super-Earths (1.25-2 R ⊕), 21 small Neptunes (2-4 R ⊕), three large Neptunes (4-6 R ⊕), and eight giant planets (>6 R ⊕). Most of these planets are highly irradiated, but EPIC 206209135.04 (K2-72e, ), EPIC 211988320.01 (), and EPIC 212690867.01 () orbit within optimistic habitable zone boundaries set by the "recent Venus" inner limit and the "early Mars" outer limit. In total, our planet sample includes eight moderately irradiated 1.5-3 R ⊕ planet candidates (F p ≲ 20 F ⊕) orbiting brighter stars (Ks < 11) that are well-suited for atmospheric investigations with the Hubble, Spitzer, and/or James Webb Space Telescopes. Five validated planets orbit relatively bright stars (Kp < 12.5) and are expected to yield radial velocity semi-amplitudes of at least 2 m s-1. Accordingly, they are possible targets for radial velocity mass measurement with current facilities or the upcoming generation of red optical and near-infrared high-precision RV spectrographs.

Published

2017

9. EPIC 220204960: A Quadruple Star System Containing Two Strongly Interacting Eclipsing Binaries

Author

Rappaport, S, Vanderburg, A, Borkovits, T, Kalomeni, B, Halpern, JP, Ngo, H, Mace, GN, Fulton, BJ, Howard, AW, Isaacson, H, Petigura, EA, Mawet, D, Kristiansen, MH, Jacobs, TL, LaCourse, D, Bieryla, A, Forgács-Dajka, E, and Nelson, L

Subjects

binaries: close, binaries: eclipsing, binaries: general, binaries: visual, stars: low-mass, astro-ph.SR, Astronomical and Space Sciences, Astronomy & Astrophysics

Abstract

We present a strongly interacting quadruple system associated with the K2 target EPIC 220204960. The K2 target itself is a Kp = 12.7-mag star at Teff ≃ 6100 K, which we designate as 'B-N' (blue northerly image). The host of the quadruple system, however, is a Kp ≃ 17-mag star with a composite M-star spectrum, which we designate as 'R-S' (red southerly image). With a 3.2-arcsec separation and similar radial velocities and photometric distances, 'B-N' is likely physically associated with 'R-S', making this a quintuple system, but that is incidental to our main claim of a strongly interacting quadruple system in 'R-S'. The two binaries in 'R-S' have orbital periods of 13.27 and 14.41 d, respectively, and each has an inclination angle of ≳89°. From our analysis of radial-velocity (RV) measurements, and of the photometric light curve, we conclude that all four stars are very similar with masses close to 0.4M⊙. Both of the binaries exhibit significant eclipse-timing variations where those of the primary and secondary eclipses 'diverge' by 0.05 d over the course of the 80-d observations. Via a systematic set of numerical simulations of quadruple systems consisting of two interacting binaries, we conclude that the outer orbital period is very likely to be between 300 and 500 d. If sufficient time is devoted to RV studies of this faint target, the outer orbit should be measurable within a year.

Published

2017

10. 197 CANDIDATES and 104 VALIDATED PLANETS in K2's FIRST FIVE FIELDS

Author

Crossfield, IJM, Ciardi, DR, Petigura, EA, Sinukoff, E, Schlieder, JE, Howard, AW, Beichman, CA, Isaacson, H, Dressing, CD, Christiansen, JL, Fulton, BJ, Lépine, S, Weiss, L, Hirsch, L, Livingston, J, Baranec, C, Law, NM, Riddle, R, Ziegler, C, Howell, SB, Horch, E, Everett, M, Teske, J, Martinez, AO, Obermeier, C, Benneke, B, Scott, N, Deacon, N, Aller, KM, Hansen, BMS, Mancini, L, Ciceri, S, Brahm, R, Jordán, A, Knutson, HA, Henning, T, Bonnefoy, M, Liu, MC, Crepp, JR, Lothringer, J, Hinz, P, Bailey, V, Skemer, A, and Defrere, D

Subjects

catalogs, planets and satellites: fundamental parameters, planets and satellites: general, techniques: high angular resolution, techniques: photometric, techniques: spectroscopic, astro-ph.EP, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We present 197 planet candidates discovered using data from the first year of the NASA K2 mission (Campaigns 0-4), along with the results of an intensive program of photometric analyses, stellar spectroscopy, high-resolution imaging, and statistical validation. We distill these candidates into sets of 104 validated planets (57 in multi-planet systems), false positives, and 63 remaining candidates. Our validated systems span a range of properties, with median values of RP= 2.3 R⊕, P = 8.6 days, Teff = 5300 K, and Kp = 12.7mag. Stellar spectroscopy provides precise stellar and planetary parameters for most of these systems. We show that K2 has increased by 30% the number of small planets known to orbit moderately bright stars (1-4 R R⊕, Kp = 9-13 mag). Of particular interest are planets smaller than 2 R⊕, orbiting stars brighter than Kp = 11.5 mag, 5 receiving Earth-like irradiation levels, and several multi-planet systems - including 4 planets orbiting the M dwarf K2-72 near mean-motion resonances. By quantifying the likelihood that each candidate is a planet we demonstrate that our candidate sample has an overall false positive rate of 15%-30%, with rates substantially lower for small candidates (8 R⊕ and/or with P

Published

2016

11. 3.6 and 4.5 μm PHASE CURVES of the HIGHLY IRRADIATED ECCENTRIC HOT JUPITER WASP-14b

Author

Wong, I, Knutson, HA, Lewis, NK, Kataria, T, Burrows, A, Fortney, JJ, Schwartz, J, Agol, E, Cowan, NB, Deming, D, Désert, JM, Fulton, BJ, Howard, AW, Langton, J, Laughlin, G, Showman, AP, and Todorov, K

Subjects

binaries: eclipsing, planetary systems, stars: individual, techniques: photometric, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We present full-orbit phase curve observations of the eccentric (e ∼ 0.08) transiting hot Jupiter WASP-14b obtained in the 3.6 and 4.5 μm bands using the Spitzer Space Telescope. We use two different methods for removing the intrapixel sensitivity effect and compare their efficacy in decoupling the instrumental noise. Our measured secondary eclipse depths of 0.1882% ± 0.0048% and 0.2247% ± 0.0086% at 3.6 and 4.5 μm, respectively, are both consistent with a blackbody temperature of 2402 ± 35 K. We place a 2σ upper limit on the nightside flux at 3.6 μm and find it to be 9% ± 1% of the dayside flux, corresponding to a brightness temperature of 1079 K. At 4.5 μm, the minimum planet flux is 30% ± 5% of the maximum flux, corresponding to a brightness temperature of 1380 ± 65 K. We compare our measured phase curves to the predictions of one-dimensional radiative transfer and three-dimensional general circulation models. We find that WASP-14b's measured dayside emission is consistent with a model atmosphere with equilibrium chemistry and a moderate temperature inversion. These same models tend to overpredict the nightside emission at 3.6 μm, while underpredicting the nightside emission at 4.5 μm. We propose that this discrepancy might be explained by an enhanced global C/O ratio. In addition, we find that the phase curves of WASP-14b (7.8 MJup) are consistent with a much lower albedo than those of other Jovian mass planets with thermal phase curve measurements, suggesting that it may be emitting detectable heat from the deep atmosphere or interior processes.

Published

2015

12. SPITZER SECONDARY ECLIPSE OBSERVATIONS of FIVE COOL GAS GIANT PLANETS and EMPIRICAL TRENDS in COOL PLANET EMISSION SPECTRA

Author

Kammer, JA, Knutson, HA, Line, MR, Fortney, JJ, Deming, D, Burrows, A, Cowan, NB, Triaud, AHMJ, Agol, E, Desert, JM, Fulton, BJ, Howard, AW, Laughlin, GP, Lewis, NK, Morley, CV, Moses, JI, Showman, AP, and Todorov, KO

Subjects

eclipses, planetary systems, techniques: photometric, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

In this work we present Spitzer 3.6 and 4.5 μm secondary eclipse observations of five new cool ( K) transiting gas giant planets: HAT-P-19b, WASP-6b, WASP-10b, WASP-39b, and WASP-67b. We compare our measured eclipse depths to the predictions of a suite of atmosphere models and to eclipse depths for planets with previously published observations in order to constrain the temperature- and mass-dependent properties of gas giant planet atmospheres. We find that the dayside emission spectra of planets less massive than Jupiter require models with efficient circulation of energy to the night side and/or increased albedos, while those with masses greater than that of Jupiter are consistently best-matched by models with inefficient circulation and low albedos. At these relatively low temperatures we expect the atmospheric CH4/CO ratio to vary as a function of metallicity, and we therefore use our observations of these planets to constrain their atmospheric metallicities. We find that the most massive planets have dayside emission spectra that are best-matched by solar metallicity atmosphere models, but we are not able to place strong constraints on metallicities of the smaller planets in our sample. Interestingly, we find that the ratio of the 3.6 and 4.5 μm brightness temperatures for these cool transiting planets is independent of planet temperature, and instead exhibits a tentative correlation with planet mass. If this trend can be confirmed, it would suggest that the shape of these planets' emission spectra depends primarily on their masses, consistent with the hypothesis that lower-mass planets are more likely to have metal-rich atmospheres.

Published

2015

13. Hubble Space Telescope near-IR transmission spectroscopy of the super-Earth HD 97658B

Author

Knutson, HA, Dragomir, D, Kreidberg, L, Kempton, EMR, McCullough, PR, Fortney, JJ, Bean, JL, Gillon, M, Homeier, D, and Howard, AW

Subjects

binaries: eclipsing, planetary systems, techniques: spectroscopic, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

Recent results from the Kepler mission indicate that super-Earths (planets with masses between 1-10 times that of the Earth) are the most common kind of planet around nearby Sun-like stars. These planets have no direct solar system analogue, and are currently one of the least well-understood classes of extrasolar planets. Many super-Earths have average densities that are consistent with a broad range of bulk compositions, including both water-dominated worlds and rocky planets covered by a thick hydrogen and helium atmosphere. Measurements of the transmission spectra of these planets offer the opportunity to resolve this degeneracy by directly constraining the scale heights and corresponding mean molecular weights of their atmospheres. We present Hubble Space Telescope near-infrared spectroscopy of two transits of the newly discovered transiting super-Earth HD 97658b. We use the Wide Field Camera 3's (WFC3) scanning mode to measure the wavelength-dependent transit depth in 30 individual bandpasses. Our averaged differential transmission spectrum has a median 1σ uncertainty of 23 ppm in individual bins, making this the most precise observation of an exoplanetary transmission spectrum obtained with WFC3 to date. Our data are inconsistent with a cloud-free solar metallicity atmosphere at the 10σ level. They are consistent at the 0.4σ level with a flat line model, as well as effectively flat models corresponding to a metal-rich atmosphere or a solar metallicity atmosphere with a cloud or haze layer located at pressures of 10 mbar or higher.

Published

2014

14. Multiwavelength observations of the candidate disintegrating sub-mercury KIC 12557548B

Author

Croll, B, Rappaport, S, Devore, J, Gilliland, RL, Crepp, JR, Howard, AW, Star, KM, Chiang, E, Levine, AM, Jenkins, JM, Albert, L, Bonomo, AS, Fortney, JJ, and Isaacson, H

Subjects

eclipses, infrared: planetary systems, planetary systems, stars: individual, techniques: photometric, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We present multiwavelength photometry, high angular resolution imaging, and radial velocities of the unique and confounding disintegrating low-mass planet candidate KIC 12557548b. Our high angular resolution imaging, which includes space-based Hubble Space Telescope Wide Field Camera 3 (HST/WFC3) observations in the optical (∼0.53 μm and ∼0.77 μm), and ground-based Keck/NIRC2 observations in K′ band (∼2.12 μm), allow us to rule out background and foreground candidates at angular separations greater than 0.″2 that are bright enough to be responsible for the transits we associate with KIC 12557548. Our radial velocity limit from Keck/HIRES allows us to rule out bound, low-mass stellar companions (∼0.2 M) to KIC 12557548 on orbits less than 10 yr, as well as placing an upper limit on the mass of the candidate planet of 1.2 Jupiter masses; therefore, the combination of our radial velocities, high angular resolution imaging, and photometry are able to rule out most false positive interpretations of the transits. Our precise multiwavelength photometry includes two simultaneous detections of the transit of KIC 12557548b using Canada-France-Hawaii Telescope/Wide-field InfraRed Camera (CFHT/WIRCam) at 2.15 μm and the Kepler space telescope at 0.6 μm, as well as simultaneous null-detections of the transit by Kepler and HST/WFC3 at 1.4 μm. Our simultaneous HST/WFC3 and Kepler null-detections provide no evidence for radically different transit depths at these wavelengths. Our simultaneous CFHT/WIRCam detections in the near-infrared and with Kepler in the optical reveal very similar transit depths (the average ratio of the transit depths at ∼2.15 μm compared with ∼0.6 μm is: 1.02 ± 0.20). This suggests that if the transits we observe are due to scattering from single-size particles streaming from the planet in a comet-like tail, then the particles must be ∼0.5 μm in radius or larger, which would favor that KIC 12557548b is a sub-Mercury rather than super-Mercury mass planet. © 2014. The American Astronomical Society. All rights reserved.

Published

2014

15. Radial velocity variations of photometrically quiet, chromospherically inactive kepler stars: A link between RV jitter and photometric flicker

Author

Bastien, FA, Stassun, KG, Pepper, J, Wright, JT, Aigrain, S, Basri, G, Johnson, JA, Howard, AW, and Walkowicz, LM

Subjects

stars: activity, stars: solar-type, techniques: photometric, techniques: radial velocities, astro-ph.SR, Astronomy & Astrophysics, Astronomical and Space Sciences

Abstract

We compare stellar photometric variability, as measured from Kepler light curves by Basri et al., with measurements of radial velocity (RV) rms variations of all California Planet Search overlap stars. We newly derive rotation periods from the Kepler light curves for all of the stars in our study sample. The RV variations reported herein range from less than 4 to 135 m s-1, yet the stars all have amplitudes of photometric variability less than 3 mmag, reflecting the preference of the RV program for chromospherically "quiet" stars. Despite the small size of our sample, we find with high statistical significance that the RV rms manifests strongly in the Fourier power spectrum of the light curve: stars that are noisier in RV have a greater number of frequency components in the light curve. We also find that spot models of the observed light curves systematically underpredict the observed RV variations by factors of ;2-1000, likely because the low-level photometric variations in our sample are driven by processes not included in simple spot models. The stars best fit by these models tend to have simpler light curves, dominated by a single relatively high-amplitude component of variability. Finally, we demonstrate that the RV rms behavior of our sample can be explained in the context of the photometric variability evolutionary diagram introduced by Bastien et al. We use this diagram to derive the surface gravities of the stars in our sample, revealing many of them to have moved off the main sequence. More generally, we find that the stars with the largest RV rms are those that have evolved onto the "flicker floor" sequence in that diagram, characterized by relatively low amplitude but highly complex photometric variations which grow as the stars evolve to become subgiants. © 2014. The American Astronomical Society. All rights reserved.

Published

2014

16. Warm spitzer and palomar near-ir secondary eclipse photometry of two hot jupiters: Wasp-48b and hat-p-23b

Author

O'Rourke, JG, Knutson, HA, Zhao, M, Fortney, JJ, Burrows, A, Agol, E, Deming, D, Désert, JM, Howard, AW, Lewis, NK, Showman, AP, and Todorov, KO

Subjects

eclipses - planetary systems - stars, individual (WASP-48, HAT-P-23)-techniques, photometric, individual (WASP-48, HAT-P-23)-techniques, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)

Abstract

We report secondary eclipse photometry of two hot Jupiters, WASP-48b and HAT-P-23b, at 3.6 and 4.5 μm taken with the InfraRed Array Camera aboard the Spitzer Space Telescope during the warm Spitzer mission and in the H and K S bands with the Wide Field IR Camera at the Palomar 200 inch Hale Telescope. WASP-48b and HAT-P-23b are Jupiter-mass and twice Jupiter-mass objects orbiting an old, slightly evolved F star and an early G dwarf star, respectively. In the H, KS , 3.6 μm, and 4.5 μm bands, respectively, we measure secondary eclipse depths of 0.047% ± 0.016%, 0.109% ± 0.027%, 0.176% ± 0.013%, and 0.214% ± 0.020% for WASP-48b. In the KS , 3.6 μm, and 4.5 μm bands, respectively, we measure secondary eclipse depths of 0.234% ± 0.046%, 0.248% ± 0.019%, and 0.309% ± 0.026% for HAT-P-23b. For WASP-48b and HAT-P-23b, respectively, we measure delays of 2.6 ± 3.9 minutes and 4.0 ± 2.4 minutes relative to the predicted times of secondary eclipse for circular orbits, placing 2σ upper limits on |ecos ω| of 0.0053 and 0.0080, both of which are consistent with circular orbits. The dayside emission spectra of these planets are well-described by blackbodies with effective temperatures of 2158 ± 100 K (WASP-48b) and 2154 ± 90 K (HAT-P-23b), corresponding to moderate recirculation in the zero albedo case. Our measured eclipse depths are also consistent with one-dimensional radiative transfer models featuring varying degrees of recirculation and weak thermal inversions or no inversions at all. We discuss how the absence of strong temperature inversions on these planets may be related to the activity levels and metallicities of their host stars. © 2014. The American Astronomical Society. All rights reserved.

Published

2014

17. Erratum: Giant Outer Transiting Exoplanet Mass (GOT ‘EM) Survey. II. Discovery of a Failed Hot Jupiter on a 2.7 yr, Highly Eccentric Orbit (AJ (2021) 162 (154) DOI: 10.3847/1538-3881/ac134b)

Author

Dalba, PA, Dalba, PA, Kane, SR, Li, Z, MacDougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, Payne, MJ, Dalba, PA, Dalba, PA, Kane, SR, Li, Z, MacDougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, and Payne, MJ

Abstract

In the original analysis by Dalba et al. (2021) to confirm and characterize the Kepler-1704 system, an erroneous offset of 0.53878357713256 day was accidentally subtracted from the time stamps of the photometric measurements of this star acquired by the Kepler spacecraft. This photometry was then used in the comprehensive system modeling that yielded the final ephemeris of this exoplanet. As a result, parameters describing the timing of this planet’s orbit, most notably its conjunction (transit) time, were erroneously offset. This erratum serves to correct this error and the ephemeris of Kepler-1704 b. We added the 0.53878357713256 day offset to the time stamps of the Kepler photometry that was used in the original analysis. The corresponding flux values were unchanged. Besides the time stamps, we did not alter any other data product. We then conducted the joint modeling of the stellar and planetary parameters of the Kepler-1704 system using EXOFASTv2 (Eastman et al. 2019) exactly as described in Section 3 of Dalba et al. (2021). All priors and EXOFASTv2 settings were left as described in the original analysis. This new fit converged following the same criteria applied in the original analysis. We again observed a bimodality in mass and age of Kepler-1704 as described in Section 3.1 of Dalba et al. (2021). We selected the lower stellar mass solution just as before and calculated the updated stellar and planetary parameters, which are listed in Tables 1 and 2, respectively. The only parameter values in Tables 1 and 2 that changed significantly between Dalba et al. (2021) and this analysis are conjunction time (TC), periastron time (TP), and eclipse time (TS). This is expected given that the only change to the inputs to the EXOFASTv2 fit were the time stamps of the Kepler photometry. Changes for other parameters other than those listed above were only due to rounding error or small statistical variations in the Markov chain Monte Carlo analysis, and were all well with

Published

2022

18. Toi-1235 b: A keystone super-earth for testing radius valley emergence models around early m dwarfs

Author

Cloutier, R, Rodriguez, JE, Irwin, J, Charbonneau, D, Stassun, KG, Mortier, A, Latham, DW, Isaacson, H, Howard, AW, Udry, S, Wilson, TG, Watson, CA, Pinamonti, M, Lienhard, F, Giacobbe, P, Guerra, P, Collins, KA, Beiryla, A, Esquerdo, GA, Matthews, E, Matson, RA, Howell, SB, Furlan, E, Crossfield, IJM, Winters, JG, Nava, C, Ment, K, Lopez, ED, Ricker, G, Vanderspek, R, Seager, S, Jenkins, JM, Ting, EB, Tenenbaum, P, Sozzetti, A, Sha, L, Ségransan, D, Schlieder, JE, Sasselov, D, Roy, A, Robertson, P, Rice, K, Poretti, E, Piotto, G, Phillips, D, Pepper, J, Pepe, F, Molinari, E, Mocnik, T, Micela, G, Mayor, M, Martinez Fiorenzano, AF, Mallia, F, Lubin, J, Lovis, C, López-Morales, M, Kosiarek, MR, Kielkopf, JF, Kane, Jensen, ELN, Isopi, G, Huber, D, Hill, ML, Harutyunyan, A, Gonzales, E, Giacalone, S, Ghedina, A, Ercolino, A, Dumusque, X, Dressing, CD, Damasso, M, Dalba, PA, Cosentino, R, Conti, DM, Colón, KD, Collins, KI, Cameron, AC, Ciardi, D, Christiansen, J, Chontos, A, Cecconi, M, Caldwell, DA, Burke, C, Buchhave, L, Beichman, C, Behmard, A, Beard, C, Akana Murphy, JM, Cloutier, R [0000-0001-5383-9393], Rodriguez, JE [0000-0001-8812-0565], Charbonneau, D [0000-0002-9003-484X], Stassun, KG [0000-0002-3481-9052], Mortier, A [0000-0001-7254-4363], Latham, DW [0000-0001-9911-7388], Isaacson, H [0000-0002-0531-1073], Howard, AW [0000-0001-8638-0320], Udry, S [0000-0001-7576-6236], Collins, KA [0000-0001-6588-9574], Beiryla, A [0000-0001-6637-5401], Esquerdo, GA [0000-0002-9789-5474], Matthews, E [0000-0003-0593-1560], Matson, RA [0000-0001-7233-7508], Howell, SB [0000-0002-2532-2853], Winters, JG [0000-0001-6031-9513], Nava, C [0000-0001-8838-3883], Ment, K [0000-0001-5847-9147], Ricker, G [0000-0003-2058-6662], Vanderspek, R [0000-0001-6763-6562], Seager, S [0000-0002-6892-6948], Jenkins, JM [0000-0002-4715-9460], Ting, EB [0000-0002-8219-9505], Tenenbaum, P [0000-0002-1949-4720], Sozzetti, A [0000-0002-7504-365X], Sha, L [0000-0001-5401-8079], Ségransan, D [0000-0003-2355-8034], Schlieder, JE [0000-0001-5347-7062], Sasselov, D [0000-0001-7014-1771], Roy, A [0000-0001-8127-5775], Robertson, P [0000-0003-0149-9678], Poretti, E [0000-0003-1200-0473], Piotto, G [0000-0002-9937-6387], Pepper, J [0000-0002-3827-8417], Molinari, E [0000-0002-1742-7735], Mocnik, T [0000-0003-4603-556X], Micela, G [0000-0002-9900-4751], Lubin, J [0000-0001-8342-7736], López-Morales, M [0000-0003-3204-8183], Kielkopf, JF [0000-0003-0497-2651], Kane, SR [0000-0002-7084-0529], Jensen, ELN [0000-0002-4625-7333], Huber, D [0000-0001-8832-4488], Hill, ML [0000-0002-0139-4756], Giacalone, S [0000-0002-8965-3969], Ghedina, A [0000-0003-4702-5152], Dumusque, X [0000-0002-9332-2011], Dressing, CD [0000-0001-8189-0233], Dalba, PA [0000-0002-4297-5506], Cosentino, R [0000-0003-1784-1431], Conti, DM [0000-0003-2239-0567], Colón, KD [0000-0001-8020-7121], Collins, KI [0000-0003-2781-3207], Ciardi, D [0000-0002-5741-3047], Christiansen, J [0000-0002-8035-4778], Chontos, A [0000-0003-1125-2564], Caldwell, DA [0000-0003-1963-9616], Burke, C [0000-0002-7754-9486], Buchhave, L [0000-0003-1605-5666], Behmard, A [0000-0003-0012-9093], Beard, C [0000-0001-7708-2364], Akana Murphy, JM [0000-0001-8898-8284], and Apollo - University of Cambridge Repository

Subjects

Radial velocity, Exoplanet formation, Transit photometry, M dwarf stars, Exoplanet structure

Abstract

Small planets on close-in orbits tend to exhibit envelope mass fractions of either effectively zero or up to a few percent depending on their size and orbital period. Models of thermally-driven atmospheric mass loss and of terrestrial planet formation in a gas-poor environment make distinct predictions regarding the location of this rocky/non-rocky transition in period-radius space. Here we present the confirmation of TOI-1235 b ($P=3.44$ days, $r_p=1.738^{+0.087}_{-0.076}$ R$_{\oplus}$), a planet whose size and period are intermediate between the competing model predictions, thus making the system an important test case for emergence models of the rocky/non-rocky transition around early M dwarfs ($R_s=0.630\pm 0.015$ R$_{\odot}$, $M_s=0.640\pm 0.016$ M$_{\odot}$). We confirm the TESS planet discovery using reconnaissance spectroscopy, ground-based photometry, high-resolution imaging, and a set of 38 precise radial-velocities from HARPS-N and HIRES. We measure a planet mass of $6.91^{+0.75}_{-0.85}$ M$_{\oplus}$ which implies an iron core mass fraction of $20^{+15}_{-12}$% in the absence of a gaseous envelope. The bulk composition of TOI-1235 b is therefore consistent with being Earth-like and we constrain a H/He envelope mass fraction to be $

Published

2020

19. Understanding the impacts of stellar companions on planet formation and evolution: A survey of stellar and planetary companions within 25 pc

Author

Hirsch, LA, Hirsch, LA, Rosenthal, L, Fulton, BJ, Howard, AW, Ciardi, DR, Marcy, GW, Nielsen, E, Petigura, EA, De Rosa, RJ, Isaacson, H, Weiss, LM, Sinukoff, E, Macintosh, B, Hirsch, LA, Hirsch, LA, Rosenthal, L, Fulton, BJ, Howard, AW, Ciardi, DR, Marcy, GW, Nielsen, E, Petigura, EA, De Rosa, RJ, Isaacson, H, Weiss, LM, Sinukoff, E, and Macintosh, B

Abstract

We explore the impact of outer stellar companions on the occurrence rate of giant planets detected with radial velocities. We searched for stellar and planetary companions to a volume-limited sample of solar-type stars within 25 pc. Using adaptive optics imaging observations from the Lick 3 m and Palomar 200″ Telescopes, we characterized the multiplicity of our sample stars, down to the bottom of the main sequence. With these data, we confirm field star multiplicity statistics from previous surveys. We additionally combined three decades of radial velocity (RV) data from the California Planet Search with newly collected RV data from Keck/HIRES and the Automated Planet Finder/Levy Spectrometer to search for planetary companions in these same systems. Using an updated catalog of both stellar and planetary companions, as well as detailed injection/recovery tests to determine our sensitivity and completeness, we measured the occurrence rate of planets among the single- and multiple-star systems. We found that planets with masses in the range of 0.1–10 MJ and with semimajor axes of 0.1–10 au have an occurrence rate of 0.18-+0.030.04 planets per star when they orbit single stars and an occurrence rate of 0.12 ± 0.04 planets per star when they orbit a star in a binary system. Breaking the sample down by the binary separation, we found that only one planet-hosting binary system had a binary separation <100 au, and none had a separation <50 au. These numbers yielded planet occurrence rates of 0.20-+0.060.07 planets per star for binaries with separation aB > 100 au and 0.04-+0.020.04 planets per star for binaries with separation aB < 100 au. The similarity in the planet occurrence rate around single stars and wide primaries implies that wide binary systems should actually host more planets than single-star systems, since they have more potential host stars. We estimated a system-wide planet occurrence rate of 0.3 planets per wide binary system for binaries with se

Published

2021

20. Giant Outer Transiting Exoplanet Mass (GOT 'EM) Survey. II. Discovery of a Failed Hot Jupiter on a 2.7 Yr, Highly Eccentric Orbit

Author

Dalba, PA, Dalba, PA, Kane, SR, Li, Z, Macdougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, Payne, MJ, Dalba, PA, Dalba, PA, Kane, SR, Li, Z, Macdougall, MG, Rosenthal, LJ, Cherubim, C, Isaacson, H, Thorngren, DP, Fulton, B, Howard, AW, Petigura, EA, Schwieterman, EW, Peluso, DO, Esposito, TM, Marchis, F, and Payne, MJ

Abstract

Radial velocity (RV) surveys have discovered giant exoplanets on au-scale orbits with a broad distribution of eccentricities. Those with the most eccentric orbits are valuable laboratories for testing theories of high-eccentricity migration. However, few such exoplanets transit their host stars, thus removing the ability to apply constraints on formation from their bulk internal compositions. We report the discovery of Kepler-1704 b, a transiting 4.15 M J giant planet on a 988.88 day orbit with an extreme eccentricity of 0.921-0.015+0.010. Our decade-long RV baseline from the Keck I telescope allows us to measure the orbit and bulk heavy-element composition of Kepler-1704 b and place limits on the existence of undiscovered companions. A failed hot Jupiter, Kepler-1704 b was likely excited to high eccentricity by scattering events that possibly began during its gas accretion phase. Its final periastron distance was too large to allow for tidal circularization, so now it orbits its host from distances spanning 0.16-3.9 au. The maximum difference in planetary equilibrium temperature resulting from this elongated orbit is over 700 K. A simulation of the thermal phase curve of Kepler-1704 b during periastron passage demonstrates that it is a remarkable target for atmospheric characterization from the James Webb Space Telescope, which could potentially also measure the planet's rotational period as the hot spot from periastron rotates in and out of view. Continued characterization of the Kepler-1704 system promises to refine theories explaining the formation of hot Jupiters and cool giant planets like those in the solar system.

Published

2021

21. Giant outer transiting exoplanet mass (GOT 'EM) survey. I. Confirmation of an eccentric, cool jupiter with an interior earth-sized planet orbiting kepler-1514

Author

Dalba, PA, Dalba, PA, Kane, SR, Isaacson, H, Giacalone, S, Howard, AW, Rodriguez, JE, Vanderburg, A, Eastman, JD, Kraus, AL, Dupuy, TJ, Weiss, LM, Schwieterman, EW, Dalba, PA, Dalba, PA, Kane, SR, Isaacson, H, Giacalone, S, Howard, AW, Rodriguez, JE, Vanderburg, A, Eastman, JD, Kraus, AL, Dupuy, TJ, Weiss, LM, and Schwieterman, EW

Abstract

Despite the severe bias of the transit method of exoplanet discovery toward short orbital periods, a modest sample of transiting exoplanets with orbital periods greater than 100 days is known. Long-term radial velocity (RV) surveys are pivotal to confirming these signals and generating a set of planetary masses and densities for planets receiving moderate to low irradiation from their host stars. Here we conduct RV observations of Kepler-1514 from the Keck I telescope using the High Resolution Echelle Spectrometer. From these data, we measure the mass of the statistically validated giant (1.108 ± 0.023 RJ) exoplanet Kepler-1514 b with a 218-day orbital period as 5.28 ± 0.22MJ. The bulk density of this cool (~390 K) giant planet is -4.82+0.26-0.25g cm-3, consistent with a core supported by electron degeneracy pressure. We also infer an orbital eccentricity of 0.401+0.013-0.014 from the RV and transit observations, which is consistent with planet-planet scattering and disk cavity migration models. The Kepler-1514 system contains an Earth-size, Kepler Object of Interest on a 10.5-day orbit that we statistically validate against false-positive scenarios, including those involving a neighboring star. The combination of the brightness (V = 11.8) of the host star and the long period, low irradiation, and high density of Kepler-1514 b places this system among a rare group of known exoplanetary systems and as one that is amenable to continued study.

Published

2021

22. The TESS-Keck survey. II. An ultra-short-period rocky planet and its siblings transiting the galactic thick-disk star TOI-561

Author

Weiss, LM, Weiss, LM, Dai, F, Huber, D, Brewer, JM, Collins, KA, Ciardi, DR, Matthews, EC, Ziegler, C, Howell, SB, Batalha, NM, Crossfield, IJM, Dressing, C, Fulton, B, Howard, AW, Isaacson, H, Kane, SR, Petigura, EA, Robertson, P, Roy, A, Rubenzahl, RA, Twicken, JD, Claytor, ZR, Stassun, KG, MacDougall, MG, Chontos, A, Giacalone, S, Dalba, PA, Mocnik, T, Hill, ML, Beard, C, Murphy, JMA, Rosenthal, LJ, Behmard, A, Van Zandt, J, Lubin, J, Kosiarek, MR, Lund, MB, Christiansen, JL, Matson, RA, Beichman, CA, Schlieder, JE, Gonzales, EJ, Briceño, C, Law, N, Mann, AW, Collins, KI, Evans, P, Fukui, A, Jensen, ELN, Murgas, F, Narita, N, Palle, E, Parviainen, H, Schwarz, RP, Tan, TG, Acton, JS, Bryant, EM, Chaushev, A, Gill, S, Eigmüller, P, Jenkins, J, Ricker, G, Seager, S, Winn, JN, Weiss, LM, Weiss, LM, Dai, F, Huber, D, Brewer, JM, Collins, KA, Ciardi, DR, Matthews, EC, Ziegler, C, Howell, SB, Batalha, NM, Crossfield, IJM, Dressing, C, Fulton, B, Howard, AW, Isaacson, H, Kane, SR, Petigura, EA, Robertson, P, Roy, A, Rubenzahl, RA, Twicken, JD, Claytor, ZR, Stassun, KG, MacDougall, MG, Chontos, A, Giacalone, S, Dalba, PA, Mocnik, T, Hill, ML, Beard, C, Murphy, JMA, Rosenthal, LJ, Behmard, A, Van Zandt, J, Lubin, J, Kosiarek, MR, Lund, MB, Christiansen, JL, Matson, RA, Beichman, CA, Schlieder, JE, Gonzales, EJ, Briceño, C, Law, N, Mann, AW, Collins, KI, Evans, P, Fukui, A, Jensen, ELN, Murgas, F, Narita, N, Palle, E, Parviainen, H, Schwarz, RP, Tan, TG, Acton, JS, Bryant, EM, Chaushev, A, Gill, S, Eigmüller, P, Jenkins, J, Ricker, G, Seager, S, and Winn, JN

Abstract

We report the discovery of TOI-561, a multiplanet system in the galactic thick disk that contains a rocky, ultrashort- period planet. This bright (V = 10.2) star hosts three small transiting planets identified in photometry from the NASA TESS mission: TOI-561 b (TOI-561.02, P = 0.44 days, Rp = 1.45 ± 0.11 R⊕), c (TOI-561.01, P = 10.8 days, Rp = 2.90 ± 0.13 R⊕), and d (TOI-561.03, P = 16.3 days, Rp = 2.32 ± 0.16 R⊕). The star is chemically ([Fe/ H] = -0.41 ± 0.05, [a/Fe]=+0.23 ± 0.05) and kinematically consistent with the galactic thick-disk population, making TOI-561 one of the oldest (10 ± 3 Gyr) and most metal-poor planetary systems discovered yet. We dynamically confirm planets b and c with radial velocities from the W. M. Keck Observatory High Resolution Echelle Spectrometer. Planet b has a mass and density of 3.2 ± 0.8M⊕ and 5.5+2.0-1.6g cm-3, consistent with a rocky composition. Its lower-than-average density is consistent with an iron-poor composition, although an Earth-like iron-to-silicates ratio is not ruled out. Planet c is 7.0 ± 2.3M⊕ and 1.6 ± 0.6 g cm-3, consistent with an interior rocky core overlaid with a low-mass volatile envelope. Several attributes of the photometry for planet d (which we did not detect dynamically) complicate the analysis, but we vet the planet with high-contrast imaging, groundbased photometric follow-up, and radial velocities. TOI-561 b is the first rocky world around a galactic thick-disk star confirmed with radial velocities and one of the best rocky planets for thermal emission studies.

Published

2021

23. Physical parameters of the multiplanet systems HD 106315 and GJ 9827

Author

Kosiarek, MR, Kosiarek, MR, Berardo, DA, Crossfield, IJM, Laguna, C, Piaulet, C, Akana Murphy, JM, Howell, SB, Henry, GW, Isaacson, H, Fulton, B, Weiss, LM, Petigura, EA, Behmard, A, Hirsch, LA, Teske, J, Burt, JA, Mills, SM, Chontos, A, Močnik, T, Howard, AW, Werner, M, Livingston, JH, Krick, J, Beichman, C, Gorjian, V, Kreidberg, L, Morley, C, Christiansen, JL, Morales, FY, Scott, NJ, Crane, JD, Wang, SX, Shectman, SA, Rosenthal, LJ, Grunblatt, SK, Rubenzahl, RA, Dalba, PA, Giacalone, S, Villanueva, CD, Liu, Q, Dai, F, Hill, ML, Rice, M, Kane, SR, Mayo, AW, Kosiarek, MR, Kosiarek, MR, Berardo, DA, Crossfield, IJM, Laguna, C, Piaulet, C, Akana Murphy, JM, Howell, SB, Henry, GW, Isaacson, H, Fulton, B, Weiss, LM, Petigura, EA, Behmard, A, Hirsch, LA, Teske, J, Burt, JA, Mills, SM, Chontos, A, Močnik, T, Howard, AW, Werner, M, Livingston, JH, Krick, J, Beichman, C, Gorjian, V, Kreidberg, L, Morley, C, Christiansen, JL, Morales, FY, Scott, NJ, Crane, JD, Wang, SX, Shectman, SA, Rosenthal, LJ, Grunblatt, SK, Rubenzahl, RA, Dalba, PA, Giacalone, S, Villanueva, CD, Liu, Q, Dai, F, Hill, ML, Rice, M, Kane, SR, and Mayo, AW

Abstract

HD 106315 and GJ 9827 are two bright, nearby stars that host multiple super-Earths and sub-Neptunes discovered by K2 that are well suited for atmospheric characterization. We refined the planets' ephemerides through Spitzer transits, enabling accurate transit prediction required for future atmospheric characterization through transmission spectroscopy. Through a multiyear high-cadence observing campaign with Keck/High Resolution Echelle Spectrometer and Magellan/Planet Finder Spectrograph, we improved the planets' mass measurements in anticipation of Hubble Space Telescope transmission spectroscopy. For GJ 9827, we modeled activity-induced radial velocity signals with a Gaussian process informed by the Calcium II H&K lines in order to more accurately model the effect of stellar noise on our data. We measured planet masses of Mb = 4.87 ± 0.37 M⊕, Mc = 1.92 ± 0.49 M⊕, and Md = 3.42 ± 0.62 M⊕. For HD 106315, we found that such activity radial velocity decorrelation was not effective due to the reduced presence of spots and speculate that this may extend to other hot stars as well (Teff > 6200 K). We measured planet masses of Mb = 10.5 ± 3.1 M⊕ and Mc = 12.0 ± 3.8 M⊕. We investigated all of the planets' compositions through comparison of their masses and radii to a range of interior models. GJ 9827 b and GJ 9827 c are both consistent with a 50/50 rock-iron composition, GJ 9827 d and HD 106315 b both require additional volatiles and are consistent with moderate amounts of water or hydrogen/helium, and HD 106315 c is consistent with a ∼10% hydrogen/helium envelope surrounding an Earth-like rock and iron core.

Published

2020

24. The TESS-keck survey. III. A stellar obliquity measurement of TOI-1726 c

Author

Dai, F, Dai, F, Roy, A, Fulton, B, Robertson, P, Hirsch, L, Isaacson, H, Albrecht, S, Mann, AW, Kristiansen, MH, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dalba, PA, Dressing, C, Giacalone, S, Hill, M, Howard, AW, Huber, D, Kane, SR, Kosiarek, M, Lubin, J, Mayo, A, Mocnik, T, Akana Murphy, JM, Petigura, EA, Rosenthal, L, Rubenzahl, RA, Scarsdale, N, Weiss, LM, van Zandt, J, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Charbonneau, D, Daylan, T, Günther, MN, Morgan, E, Quinn, SN, Rose, ME, Smith, JC, Dai, F, Dai, F, Roy, A, Fulton, B, Robertson, P, Hirsch, L, Isaacson, H, Albrecht, S, Mann, AW, Kristiansen, MH, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dalba, PA, Dressing, C, Giacalone, S, Hill, M, Howard, AW, Huber, D, Kane, SR, Kosiarek, M, Lubin, J, Mayo, A, Mocnik, T, Akana Murphy, JM, Petigura, EA, Rosenthal, L, Rubenzahl, RA, Scarsdale, N, Weiss, LM, van Zandt, J, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Charbonneau, D, Daylan, T, Günther, MN, Morgan, E, Quinn, SN, Rose, ME, and Smith, JC

Abstract

We report the measurement of a spectroscopic transit of TOI-1726c, one of two planets transiting a G-type star with V = 6.9 in the Ursa Major Moving Group (∼400 Myr). With a precise age constraint from cluster membership, TOI-1726 provides a great opportunity to test various obliquity excitation scenarios that operate on different timescales. By modeling the Rossiter-McLaughlin (RM) effect, we derived a sky-projected obliquity of -1-+3235∘. This result rules out a polar/retrograde orbit and is consistent with an aligned orbit for planet c. Considering the previously reported, similarly prograde RM measurement of planet b and the transiting nature of both planets, TOI-1726 tentatively conforms to the overall picture that compact multitransiting planetary systems tend to have coplanar, likely aligned orbits. TOI-1726 is also a great atmospheric target for understanding differential atmospheric loss of sub-Neptune planets (planet b 2.2 R☉ and c 2.7 R☉ both likely underwent photoevaporation). The coplanar geometry points to a dynamically cold history of the system that simplifies any future modeling of atmospheric escape.

Published

2020

25. The TESS-Keck Survey. I. A Warm Sub-Saturn-mass Planet and a Caution about Stray Light in TESS Cameras

Author

Dalba, PA, Dalba, PA, Gupta, AF, Rodriguez, JE, Dragomir, D, Huang, CX, Kane, SR, Quinn, SN, Bieryla, A, Esquerdo, GA, Fulton, BJ, Scarsdale, N, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dressing, CD, Giacalone, S, Hill, ML, Hirsch, LA, Howard, AW, Huber, D, Isaacson, H, Kosiarek, M, Lubin, J, Mayo, AW, Mocnik, T, Akana Murphy, JM, Petigura, EA, Robertson, P, Rosenthal, LJ, Roy, A, Rubenzahl, RA, Van Zandt, J, Weiss, LM, Knudstrup, E, Andersen, MF, Grundahl, F, Yao, X, Pepper, J, Villanueva, S, Ciardi, DR, Cloutier, R, Jacobs, TL, Kristiansen, MH, Lacourse, DM, Lendl, M, Osborn, HP, Palle, E, Stassun, KG, Stevens, DJ, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Daylan, T, Fong, W, Goeke, RF, Rose, ME, Rowden, P, Schlieder, JE, Smith, JC, Vanderburg, A, Dalba, PA, Dalba, PA, Gupta, AF, Rodriguez, JE, Dragomir, D, Huang, CX, Kane, SR, Quinn, SN, Bieryla, A, Esquerdo, GA, Fulton, BJ, Scarsdale, N, Batalha, NM, Beard, C, Behmard, A, Chontos, A, Crossfield, IJM, Dressing, CD, Giacalone, S, Hill, ML, Hirsch, LA, Howard, AW, Huber, D, Isaacson, H, Kosiarek, M, Lubin, J, Mayo, AW, Mocnik, T, Akana Murphy, JM, Petigura, EA, Robertson, P, Rosenthal, LJ, Roy, A, Rubenzahl, RA, Van Zandt, J, Weiss, LM, Knudstrup, E, Andersen, MF, Grundahl, F, Yao, X, Pepper, J, Villanueva, S, Ciardi, DR, Cloutier, R, Jacobs, TL, Kristiansen, MH, Lacourse, DM, Lendl, M, Osborn, HP, Palle, E, Stassun, KG, Stevens, DJ, Ricker, GR, Vanderspek, R, Latham, DW, Seager, S, Winn, JN, Jenkins, JM, Caldwell, DA, Daylan, T, Fong, W, Goeke, RF, Rose, ME, Rowden, P, Schlieder, JE, Smith, JC, and Vanderburg, A

Abstract

We report the detection of a Saturn-size exoplanet orbiting HD 332231 (TOI 1456) in light curves from the Transiting Exoplanet Survey Satellite (TESS). HD 332231 - an F8 dwarf star with a V-band magnitude of 8.56 - was observed by TESS in Sectors 14 and 15. We detect a single-transit event in the Sector 15 presearch data conditioning (PDC) light curve. We obtain spectroscopic follow-up observations of HD 332231 with the Automated Planet Finder, Keck I, and SONG telescopes. The orbital period we infer from radial velocity (RV) observations leads to the discovery of another transit in Sector 14 that was masked by PDC due to scattered light contamination. A joint analysis of the transit and RV data confirms the planetary nature of HD 332231 b, a Saturn-size (0.867-0.025+0.027RJ), sub-Saturn-mass (0.244±0.021MJ) exoplanet on a 18.71 day circular orbit. The low surface gravity of HD 332231 b and the relatively low stellar flux it receives make it a compelling target for transmission spectroscopy. Also, the stellar obliquity is likely measurable via the Rossiter-McLaughlin effect, an exciting prospect given the 0.14 au orbital separation of HD 332231 b. The spectroscopic observations do not provide substantial evidence for any additional planets in the HD 332231 system, but continued RV monitoring is needed to further characterize this system. We also predict that the frequency and duration of masked data in the PDC light curves for TESS Sectors 14-16 could hide transits of some exoplanets with orbital periods between 10.5 and 17.5 days.

Published

2020

26. The Discovery of the Long-Period, Eccentric Planet Kepler-88 d and System Characterization with Radial Velocities and Photodynamical Analysis

Author

Weiss, LM, Weiss, LM, Fabrycky, DC, Agol, E, Mills, SM, Howard, AW, Isaacson, H, Petigura, EA, Fulton, B, Hirsch, L, Sinukoff, E, Weiss, LM, Weiss, LM, Fabrycky, DC, Agol, E, Mills, SM, Howard, AW, Isaacson, H, Petigura, EA, Fulton, B, Hirsch, L, and Sinukoff, E

Abstract

We present the discovery of Kepler-88 d (Pd = 1403 ± 14 days, M sin id =965 ± 44⊕ = 3.04 ± 0.13 MJ, ed = 0.41 ± 0.03) based on six years of radial velocity (RV) follow-up from the W. M. Keck Observatory High Resolution Echelle Spectrometer spectrograph. Kepler-88 has two previously identified planets. Kepler-88 b (KOI-142.01) transits in the NASA Kepler photometry and has very large transit timing variations (TTVs). Nesvorný et al. performed a dynamical analysis of the TTVs to uniquely identify the orbital period and mass of the perturbing planet (Kepler-88 c), which was later was confirmed with RVs from the Observatoire de Haute-Provence (OHP). To fully explore the architecture of this system, we performed photodynamical modeling on the Kepler photometry combined with the RVs from Keck and OHP and stellar parameters from spectroscopy and Gaia. Planet d is not detectable in the photometry, and long-baseline RVs are needed to ascertain its presence. A photodynamical model simultaneously optimized to fit the RVs and Kepler photometry yields the most precise planet masses and orbital properties yet for b and c: Pb=10.91647 ± 0.00014 days, Mb=9.5 ± 1.2 M⊕ Pc=22.2649±0.0007 days, and Mc=214.0±5.3 M⊕. The photodynamical solution also finds that planets b and c have low eccentricites and low mutual inclination, are apsidally anti-aligned, and have conjunctions on the same hemisphere of the star. Continued RV follow-up of systems with small planets will improve our understanding of the link between inner planetary system architectures and giant planets.

Published

2020

27. HD 202772A b: A Transiting Hot Jupiter around a Bright, Mildly Evolved Star in a Visual Binary Discovered by TESS

Author

Wang, S, Wang, S, Jones, M, Shporer, A, Fulton, BJ, Paredes, LA, Trifonov, T, Kossakowski, D, Eastman, J, Redfield, S, Günther, MN, Kreidberg, L, Huang, CX, Millholland, S, Seligman, D, Fischer, D, Brahm, R, Wang, XY, Cruz, B, Henry, T, James, HS, Addison, B, Liang, ES, Davis, AB, Tronsgaard, R, Worku, K, Brewer, JM, Kürster, M, Zhang, H, Beichman, CA, Bieryla, A, Brown, TM, Christiansen, JL, Ciardi, DR, Collins, KA, Esquerdo, GA, Howard, AW, Isaacson, H, Latham, DW, Mazeh, T, Petigura, EA, Quinn, SN, Shahaf, S, Siverd, RJ, Rodler, F, Reffert, S, Zakhozhay, O, Ricker, GR, Vanderspek, R, Seager, S, Winn, JN, Jenkins, JM, Boyd, PT, Frész, G, Henze, C, Levine, AM, Morris, R, Paegert, M, Stassun, KG, Ting, EB, Vezie, M, Laughlin, G, Wang, S, Wang, S, Jones, M, Shporer, A, Fulton, BJ, Paredes, LA, Trifonov, T, Kossakowski, D, Eastman, J, Redfield, S, Günther, MN, Kreidberg, L, Huang, CX, Millholland, S, Seligman, D, Fischer, D, Brahm, R, Wang, XY, Cruz, B, Henry, T, James, HS, Addison, B, Liang, ES, Davis, AB, Tronsgaard, R, Worku, K, Brewer, JM, Kürster, M, Zhang, H, Beichman, CA, Bieryla, A, Brown, TM, Christiansen, JL, Ciardi, DR, Collins, KA, Esquerdo, GA, Howard, AW, Isaacson, H, Latham, DW, Mazeh, T, Petigura, EA, Quinn, SN, Shahaf, S, Siverd, RJ, Rodler, F, Reffert, S, Zakhozhay, O, Ricker, GR, Vanderspek, R, Seager, S, Winn, JN, Jenkins, JM, Boyd, PT, Frész, G, Henze, C, Levine, AM, Morris, R, Paegert, M, Stassun, KG, Ting, EB, Vezie, M, and Laughlin, G

Abstract

We report the first confirmation of a hot Jupiter discovered by the Transiting Exoplanet Survey Satellite (TESS) mission: HD 202772A b. The transit signal was detected in the data from TESS Sector 1, and was confirmed to be of planetary origin through radial velocity (RV) measurements. HD 202772A b is orbiting a mildly evolved star with a period of 3.3 days. With an apparent magnitude of V = 8.3, the star is among the brightest and most massive known to host a hot Jupiter. Based on the 27 days of TESS photometry and RV data from the CHIRON, HARPS, and Tillinghast Reflector Echelle Spectrograph, the planet has a mass of and radius of , making it an inflated gas giant. HD 202772A b is a rare example of a transiting hot Jupiter around a quickly evolving star. It is also one of the most strongly irradiated hot Jupiters currently known.

Published

2019

28. A Super-Earth and Sub-Neptune Transiting the Late-type M Dwarf LP 791-18

Author

Crossfield, IJM, Crossfield, IJM, Waalkes, W, Newton, ER, Narita, N, Muirhead, P, Ment, K, Matthews, E, Kraus, A, Kostov, V, Kosiarek, MR, Kane, SR, Isaacson, H, Halverson, S, Gonzales, E, Everett, M, Dragomir, D, Collins, KA, Chontos, A, Berardo, D, Winters, JG, Winn, JN, Scott, NJ, Rojas-Ayala, B, Rizzuto, AC, Petigura, EA, Peterson, M, Mocnik, T, Mikal-Evans, T, Mehrle, N, Matson, R, Kuzuhara, M, Irwin, J, Huber, D, Huang, C, Howell, S, Howard, AW, Hirano, T, Fulton, BJ, Dupuy, T, Dressing, CD, Dalba, PA, Charbonneau, D, Burt, J, Berta-Thompson, Z, Benneke, B, Watanabe, N, Twicken, JD, Tamura, M, Schlieder, J, Seager, S, Rose, ME, Ricker, G, Quintana, E, Lépine, S, Latham, DW, Kotani, T, Jenkins, JM, Hori, Y, Colon, K, Caldwell, DA, Crossfield, IJM, Crossfield, IJM, Waalkes, W, Newton, ER, Narita, N, Muirhead, P, Ment, K, Matthews, E, Kraus, A, Kostov, V, Kosiarek, MR, Kane, SR, Isaacson, H, Halverson, S, Gonzales, E, Everett, M, Dragomir, D, Collins, KA, Chontos, A, Berardo, D, Winters, JG, Winn, JN, Scott, NJ, Rojas-Ayala, B, Rizzuto, AC, Petigura, EA, Peterson, M, Mocnik, T, Mikal-Evans, T, Mehrle, N, Matson, R, Kuzuhara, M, Irwin, J, Huber, D, Huang, C, Howell, S, Howard, AW, Hirano, T, Fulton, BJ, Dupuy, T, Dressing, CD, Dalba, PA, Charbonneau, D, Burt, J, Berta-Thompson, Z, Benneke, B, Watanabe, N, Twicken, JD, Tamura, M, Schlieder, J, Seager, S, Rose, ME, Ricker, G, Quintana, E, Lépine, S, Latham, DW, Kotani, T, Jenkins, JM, Hori, Y, Colon, K, and Caldwell, DA

Abstract

Planets occur most frequently around cool dwarfs, but only a handful of specific examples are known to orbit the latest-type M stars. Using TESS photometry, we report the discovery of two planets transiting the low-mass star called LP 791-18 (identified by TESS as TOI 736). This star has spectral type M6V, effective temperature 2960 K, and radius 0.17 R o, making it the third-coolest star known to host planets. The two planets straddle the radius gap seen for smaller exoplanets; they include a 1.1R ⊕ planet on a 0.95 day orbit and a 2.3R ⊕ planet on a 5 day orbit. Because the host star is small the decrease in light during these planets' transits is fairly large (0.4% and 1.7%). This has allowed us to detect both planets' transits from ground-based photometry, refining their radii and orbital ephemerides. In the future, radial velocity observations and transmission spectroscopy can both probe these planets' bulk interior and atmospheric compositions, and additional photometric monitoring would be sensitive to even smaller transiting planets.

Published

2019

29. A Warm Jupiter-sized Planet Transiting the Pre-main-sequence Star V1298 Tau

Author

David, TJ, David, TJ, Cody, AM, Hedges, CL, Mamajek, EE, Hillenbrand, LA, Ciardi, DR, Beichman, CA, Petigura, EA, Fulton, BJ, Isaacson, HT, Howard, AW, Gagné, J, Saunders, NK, Rebull, LM, Stauffer, JR, Vasisht, G, Hinkley, S, David, TJ, David, TJ, Cody, AM, Hedges, CL, Mamajek, EE, Hillenbrand, LA, Ciardi, DR, Beichman, CA, Petigura, EA, Fulton, BJ, Isaacson, HT, Howard, AW, Gagné, J, Saunders, NK, Rebull, LM, Stauffer, JR, Vasisht, G, and Hinkley, S

Abstract

We report the detection of V1298 Tau b, a warm Jupiter-sized planet (R P = 0.91 ± 0.05 R Jup, P = 24.1 days) transiting a young solar analog with an estimated age of 23 Myr. The star and its planet belong to Group 29, a young association in the foreground of the Taurus-Auriga star-forming region. While hot Jupiters have been previously reported around young stars, those planets are non-transiting and near-term atmospheric characterization is not feasible. The V1298 Tau system is a compelling target for follow-up study through transmission spectroscopy and Doppler tomography owing to the transit depth (0.5%), host star brightness (K s = 8.1 mag), and rapid stellar rotation (= 23 km s-1). Although the planet is Jupiter-sized, its mass is currently unknown due to high-amplitude radial velocity jitter. Nevertheless, V1298 Tau b may help constrain formation scenarios for at least one class of close-in exoplanets, providing a window into the nascent evolution of planetary interiors and atmospheres.

Published

2019

30. Spitzer Transit Follow-up of Planet Candidates from the K2 Mission

Author

Livingston, JH, Livingston, JH, Crossfield, IJM, Werner, MW, Gorjian, V, Petigura, EA, Ciardi, DR, Dressing, CD, Fulton, BJ, Hirano, T, Schlieder, JE, Sinukoff, E, Kosiarek, M, Akeson, R, Beichman, CA, Benneke, B, Christiansen, JL, Hansen, BMS, Howard, AW, Isaacson, H, Knutson, HA, Krick, J, Martinez, AO, Sato, B, Tamura, M, Livingston, JH, Livingston, JH, Crossfield, IJM, Werner, MW, Gorjian, V, Petigura, EA, Ciardi, DR, Dressing, CD, Fulton, BJ, Hirano, T, Schlieder, JE, Sinukoff, E, Kosiarek, M, Akeson, R, Beichman, CA, Benneke, B, Christiansen, JL, Hansen, BMS, Howard, AW, Isaacson, H, Knutson, HA, Krick, J, Martinez, AO, Sato, B, and Tamura, M

Abstract

We present precision 4.5 mm Spitzer transit photometry of eight planet candidates discovered by the K2 mission: K2-52 b, K2-53 b, EPIC 205084841.01, K2-289 b, K2-174 b, K2-87 b, K2-90 b, and K2-124 b. The sample includes four sub-Neptunes and two sub-Saturns, with radii between 2.6 and 18 R ® and equilibrium temperatures between 440 and 2000 K. In this paper we identify several targets of potential interest for future characterization studies, demonstrate the utility of transit follow-up observations for planet validation and ephemeris refinement, and present new imaging and spectroscopy data. Our simultaneous analysis of the K2 and Spitzer light curves yields improved estimates of the planet radii and multiwavelength information that helps validate their planetary nature, including the previously unvalidated candidate EPIC 205686202.01 (K2-289 b). Our Spitzer observations yield an order-of-magnitude increase in ephemeris precision, thus paving the way for efficient future study of these interesting systems by reducing the typical transit timing uncertainty in mid-2021 from several hours to a dozen or so minutes. K2-53 b, K2-289 b, K2-174 b, K2-87 b, and K2-90 b are promising radial velocity (RV) targets given the performance of spectrographs available today or in development, and the M3V star K2-124 hosts a temperate sub-Neptune that is potentially a good target for both RV and atmospheric characterization studies.

Published

2019

31. The Mass of the White Dwarf Companion in the Self-lensing Binary KOI-3278: Einstein versus Newton

Author

Yahalomi, DA, Yahalomi, DA, Shvartzvald, Y, Agol, E, Shporer, A, Latham, DW, Kruse, E, Brewer, JM, Buchhave, LA, Fulton, BJ, Howard, AW, Isaacson, H, Petigura, EA, Quinn, SN, Yahalomi, DA, Yahalomi, DA, Shvartzvald, Y, Agol, E, Shporer, A, Latham, DW, Kruse, E, Brewer, JM, Buchhave, LA, Fulton, BJ, Howard, AW, Isaacson, H, Petigura, EA, and Quinn, SN

Abstract

KOI-3278 is a self-lensing stellar binary consisting of a white dwarf secondary orbiting a Sun-like primary star. Kruse & Agol noticed small periodic brightenings every 88.18 days in the Kepler photometry and interpreted these as the result of microlensing by a white dwarf with about 63% of the mass of the Sun. We obtained two sets of spectra for the primary that allowed us to derive three sets of spectroscopic estimates for its effective temperature, surface gravity, and metallicity for the first time. We used these values to update the Kruse & Agol Einsteinian microlensing model, resulting in a revised mass for the white dwarf of 0.539-0.020+0.022 M o. The spectra also allowed us to determine radial velocities and derive orbital solutions, with good agreement between the two independent data sets. An independent Newtonian dynamical MCMC model of the combined velocities yielded a mass for the white dwarf of 0.5122-0.0058+0.0057 M o. The nominal uncertainty for the Newtonian mass is about four times better than for the Einsteinian, ± 1.1% versus ± 4.1%, and the difference between the two mass determinations is 5.2%. We then present a joint Einsteinian microlensing and Newtonian radial velocity model for KOI-3278, which yielded a mass for the white dwarf of 0.5250-0.0089+0.0082M o. This joint model does not rely on any white dwarf evolutionary models or assumptions on the white dwarf mass-radius relation. We discuss the benefits of a joint model of self-lensing binaries, and how future studies of these systems can provide insight into the mass-radius relation of white dwarfs.

Published

2019

32. The California-Kepler Survey. VIII. Eccentricities of Kepler Planets and Tentative Evidence of a High-metallicity Preference for Small Eccentric Planets

Author

Mills, SM, Mills, SM, Howard, AW, Petigura, EA, Fulton, BJ, Isaacson, H, Weiss, LM, Mills, SM, Mills, SM, Howard, AW, Petigura, EA, Fulton, BJ, Isaacson, H, and Weiss, LM

Abstract

Characterizing the dependence of the orbital architectures and formation environments on the eccentricity distribution of planets is vital for understanding planet formation. In this work, we perform statistical eccentricity studies of transiting exoplanets using transit durations measured via Kepler combined with precise and accurate stellar radii from the California-Kepler Survey and Gaia. Compared to previous works that characterized the eccentricity distribution from transit durations, our analysis benefits from both high-precision stellar radii (∼3%) and a large sample of ∼1000 planets. We observe that systems with only a single observed transiting planet have a higher mean eccentricity () than systems with multiple transiting planets (), in agreement with previous studies. We confirm the preference for high- and low-eccentricity subpopulations among the single transiting systems. Finally, we show suggestive new evidence that high-e planets in the Kepler sample are preferentially found around high-metallicity ([Fe/H] > 0) stars. We conclude by discussing the implications on planetary formation theories.

Published

2019

33. Long-period Giant Companions to Three Compact, Multiplanet Systems

Author

Mills, SM, Mills, SM, Howard, AW, Weiss, LM, Steffen, JH, Isaacson, H, Fulton, BJ, Petigura, EA, Kosiarek, MR, Hirsch, LA, Boisvert, JH, Mills, SM, Mills, SM, Howard, AW, Weiss, LM, Steffen, JH, Isaacson, H, Fulton, BJ, Petigura, EA, Kosiarek, MR, Hirsch, LA, and Boisvert, JH

Abstract

Understanding the relationship between long-period giant planets and multiple smaller short-period planets is critical for formulating a complete picture of planet formation. This work characterizes three such systems. We present Kepler-65, a system with an eccentric (e = 0.28 ±0.07) giant planet companion discovered via radial velocities (RVs) exterior to a compact, multiply transiting system of sub-Neptune planets. We also use precision RVs to improve mass and radius constraints on two other systems with similar architectures, Kepler-25 and Kepler-68. In Kepler-68 we propose a second exterior giant planet candidate. Finally, we consider the implications of these systems for planet formation models, particularly that the moderate eccentricity in Kepler-65's exterior giant planet did not disrupt its inner system.

Published

2019

34. HATS-50b through HATS-53b: Four Transiting Hot Jupiters Orbiting G-type Stars Discovered by the HATSouth Survey

Author

Henning, T, Mancini, L, Sarkis, P, Bakos, G, Hartman, JD, Bayliss, D, Bento, J, Bhatti, W, Brahm, R, Ciceri, S, Csubry, Z, Val-Borro, MD, Espinoza, N, Fulton, BJ, Howard, AW, Isaacson, HT, Jordán, A, Marcy, GW, Penev, K, Rabus, M, Suc, V, Tan, TG, Tinney, CG, Wright, DJ, Zhou, G, Durkan, S, Lazar, J, Papp, I, Sari, P, Henning, T, Mancini, L, Sarkis, P, Bakos, G, Hartman, JD, Bayliss, D, Bento, J, Bhatti, W, Brahm, R, Ciceri, S, Csubry, Z, Val-Borro, MD, Espinoza, N, Fulton, BJ, Howard, AW, Isaacson, HT, Jordán, A, Marcy, GW, Penev, K, Rabus, M, Suc, V, Tan, TG, Tinney, CG, Wright, DJ, Zhou, G, Durkan, S, Lazar, J, Papp, I, and Sari, P

Abstract

© 2018. The American Astronomical Society. All rights reserved. We report the discovery of four close-in transiting exoplanets (HATS-50b through HATS-53b), discovered using the HATSouth three-continent network of homogeneous and automated telescopes. These new exoplanets belong to the class of hot Jupiters and orbit G-type dwarf stars, with brightness in the range V = 12.5-14.0 mag. While HATS-53 has many physical characteristics similar to the Sun, the other three stars appear to be metal-rich ([Fe H] = 0.2-0.3), larger, and more massive. Three of the new exoplanets, namely HATS-50b, HATS-51b, and HATS-53b, have low density (HATS-50b: 0.39 ± 0.10 M J , 1.130 ± 0.075 R J ; HATS-51b: 0.768 ± 0.045 M J , 1.41 ± 0.19 R J ; HATS-53b: 0.595 ± 0.089 M J , 1.340 ± 0.056 R J ) and similar orbital periods (3.8297 days, 3.3489 days, 3.8538 days, respectively). Instead, HATS-52b is more dense (mass 2.24 ± 0.15 MJ and radius 1.382 ± 0.086 RJ) and has a shorter orbital period (1.3667 days). It also receives an intensive radiation from its parent star and, consequently, presents a high equilibrium temperature (T eq = 1834 ± 73 K). HATS-50 shows a marginal additional transit feature consistent with an ultra-short-period hot super Neptune (upper mass limit 0.16 M J ), which will be able to be confirmed with TESS photometry.

Published

2018

35. A 2 R ⊕ Planet Orbiting the Bright Nearby K Dwarf Wolf 503

Author

Peterson, MS, Peterson, MS, Benneke, B, David, TJ, Dressing, CD, Ciardi, D, Crossfield, IJM, Schlieder, JE, Petigura, EA, Mamajek, EE, Christiansen, JL, Quinn, SN, Fulton, BJ, Howard, AW, Sinukoff, E, Beichman, C, Latham, DW, Yu, L, Arango, N, Shporer, A, Henning, T, Huang, CX, Kosiarek, MR, Dittmann, J, Isaacson, H, Peterson, MS, Peterson, MS, Benneke, B, David, TJ, Dressing, CD, Ciardi, D, Crossfield, IJM, Schlieder, JE, Petigura, EA, Mamajek, EE, Christiansen, JL, Quinn, SN, Fulton, BJ, Howard, AW, Sinukoff, E, Beichman, C, Latham, DW, Yu, L, Arango, N, Shporer, A, Henning, T, Huang, CX, Kosiarek, MR, Dittmann, J, and Isaacson, H

Abstract

Since its launch in 2009, the Kepler telescope has found thousands of planets with radii between that of Earth and Neptune. Recent studies of the distribution of these planets have revealed a gap in the population near 1.5-2.0 R ⊕, informally dividing these planets into "super-Earths" and "sub-Neptunes." The origin of this division is difficult to investigate directly because the majority of planets found by Kepler orbit distant, dim stars and are not amenable to radial velocity follow-up or transit spectroscopy, making bulk density and atmospheric measurements difficult. Here, we present the discovery and validation of a newly found planet in direct proximity to the radius gap, orbiting the bright (J = 8.32 mag), nearby (D = 44.5 pc) high proper motion K3.5V star Wolf 503 (EPIC 212779563). We determine the possibility of a companion star and false positive detection to be extremely low using both archival images and high-contrast adaptive optics images from the Palomar observatory. The brightness of the host star makes Wolf 503b a prime target for prompt radial velocity follow-up, and with the small stellar radius (0.690 ± 0.025R o), it is also an excellent target for HST transit spectroscopy and detailed atmospheric characterization with JWST. With its measured radius near the gap in the planet radius and occurrence rate distribution, Wolf 503b offers a key opportunity to better understand the origin of this radius gap as well as the nature of the intriguing populations of "super-Earths" and "sub-Neptunes" as a whole.

Published

2018

36. HAT-P-11: Discovery of a Second Planet and a Clue to Understanding Exoplanet Obliquities

Author

Yee, SW, Yee, SW, Petigura, EA, Fulton, BJ, Knutson, HA, Batygin, K, Bakos, GA, Hartman, JD, Hirsch, LA, Howard, AW, Isaacson, H, Kosiarek, MR, Sinukoff, E, Weiss, LM, Yee, SW, Yee, SW, Petigura, EA, Fulton, BJ, Knutson, HA, Batygin, K, Bakos, GA, Hartman, JD, Hirsch, LA, Howard, AW, Isaacson, H, Kosiarek, MR, Sinukoff, E, and Weiss, LM

Abstract

HAT-P-11 is a mid-K dwarf that hosts one of the first Neptune-sized planets found outside the solar system. The orbit of HAT-P-11b is misaligned with the star's spin - one of the few known cases of a misaligned planet orbiting a star less massive than the Sun. We find an additional planet in the system based on a decade of precision radial velocity (RV) measurements from Keck/High Resolution Echelle Spectrometer. HAT-P-11c is similar to Jupiter in its mass ( M J) and orbital period ( year), but has a much more eccentric orbit (e = 0.60 ± 0.03). In our joint modeling of RV and stellar activity, we found an activity-induced RV signal of ∼7 , consistent with other active K dwarfs, but significantly smaller than the 31 reflex motion due to HAT-P-11c. We investigated the dynamical coupling between HAT-P-11b and c as a possible explanation for HAT-P-11b's misaligned orbit, finding that planet-planet Kozai interactions cannot tilt planet b's orbit due to general relativistic precession; however, nodal precession operating on million year timescales is a viable mechanism to explain HAT-P-11b's high obliquity. This leaves open the question of why HAT-P-11c may have such a tilted orbit. At a distance of 38 pc, the HAT-P-11 system offers rich opportunities for further exoplanet characterization through astrometry and direct imaging.

Published

2018

37. The California-Kepler Survey. V. Peas in a Pod: Planets in a Kepler Multi-planet System Are Similar in Size and Regularly Spaced

Author

Weiss, LM, Weiss, LM, Marcy, GW, Petigura, EA, Fulton, BJ, Howard, AW, Winn, JN, Isaacson, HT, Morton, TD, Hirsch, LA, Sinukoff, EJ, Cumming, A, Hebb, L, Cargile, PA, Weiss, LM, Weiss, LM, Marcy, GW, Petigura, EA, Fulton, BJ, Howard, AW, Winn, JN, Isaacson, HT, Morton, TD, Hirsch, LA, Sinukoff, EJ, Cumming, A, Hebb, L, and Cargile, PA

Abstract

We have established precise planet radii, semimajor axes, incident stellar fluxes, and stellar masses for 909 planets in 355 multi-planet systems discovered by Kepler. In this sample, we find that planets within a single multi-planet system have correlated sizes: each planet is more likely to be the size of its neighbor than a size drawn at random from the distribution of observed planet sizes. In systems with three or more planets, the planets tend to have a regular spacing: the orbital period ratios of adjacent pairs of planets are correlated. Furthermore, the orbital period ratios are smaller in systems with smaller planets, suggesting that the patterns in planet sizes and spacing are linked through formation and/or subsequent orbital dynamics. Yet, we find that essentially no planets have orbital period ratios smaller than 1.2, regardless of planet size. Using empirical mass-radius relationships, we estimate the mutual Hill separations of planet pairs. We find that 93% of the planet pairs are at least 10 mutual Hill radii apart, and that a spacing of ∼20 mutual Hill radii is most common. We also find that when comparing planet sizes, the outer planet is larger in 65% ± 0.4% of cases, and the typical ratio of the outer to inner planet size is positively correlated with the temperature difference between the planets. This could be the result of photo-evaporation.

Published

2018

38. Three Small Planets Transiting the Bright Young Field Star K2-233

Author

David, TJ, David, TJ, Crossfield, IJM, Benneke, B, Petigura, EA, Gonzales, EJ, Schlieder, JE, Yu, L, Isaacson, HT, Howard, AW, Ciardi, DR, Mamajek, EE, Hillenbrand, LA, Cody, AM, Riedel, A, Schwengeler, HM, Tanner, C, Ende, M, David, TJ, David, TJ, Crossfield, IJM, Benneke, B, Petigura, EA, Gonzales, EJ, Schlieder, JE, Yu, L, Isaacson, HT, Howard, AW, Ciardi, DR, Mamajek, EE, Hillenbrand, LA, Cody, AM, Riedel, A, Schwengeler, HM, Tanner, C, and Ende, M

Abstract

We report the detection of three small transiting planets around the young K3 dwarf K2-233 (2MASS J15215519-2013539) from observations during Campaign 15 of the K2 mission. The star is relatively nearby (d = 69 pc) and bright (V = 10.7 mag, K s = 8.4 mag), making the planetary system an attractive target for radial velocity follow-up and atmospheric characterization with the James Webb Space Telescope. The inner two planets are hot super-Earths (R b = 1.40 ± 0.06 , R c = 1.34 ± 0.08 ), while the outer planet is a warm sub-Neptune (R d = 2.6 ± 0.1 ). We estimate the stellar age to be Myr based on rotation, activity, and kinematic indicators. The K2-233 system is particularly interesting given recent evidence for inflated radii in planets around similarly aged stars, a trend potentially related to photo-evaporation, core cooling, or both mechanisms.

Published

2018

39. Two Warm, Low-density Sub-Jovian Planets Orbiting Bright Stars in K2 Campaigns 13 and 14

Author

Yu, L, Yu, L, Rodriguez, JE, Eastman, JD, Crossfield, IJM, Shporer, A, Gaudi, BS, Burt, J, Fulton, BJ, Sinukoff, E, Howard, AW, Isaacson, H, Kosiarek, MR, Ciardi, DR, Schlieder, JE, Penev, K, Vanderburg, A, Stassun, KG, Bieryla, A, Butler, RP, Berlind, P, Calkins, ML, Esquerdo, GA, Latham, DW, Murawski, G, Stevens, DJ, Petigura, EA, Kreidberg, L, Bristow, M, Yu, L, Yu, L, Rodriguez, JE, Eastman, JD, Crossfield, IJM, Shporer, A, Gaudi, BS, Burt, J, Fulton, BJ, Sinukoff, E, Howard, AW, Isaacson, H, Kosiarek, MR, Ciardi, DR, Schlieder, JE, Penev, K, Vanderburg, A, Stassun, KG, Bieryla, A, Butler, RP, Berlind, P, Calkins, ML, Esquerdo, GA, Latham, DW, Murawski, G, Stevens, DJ, Petigura, EA, Kreidberg, L, and Bristow, M

Abstract

We report the discovery of two planets transiting the bright stars HD 89345 (EPIC 248777106, V = 9.376, K = 7.721) in K2 Campaign 14 and HD 286123 (EPIC 247098361, V = 9.822, K = 8.434) in K2 Campaign 13. Both stars are G-Type stars, one of which is at or near the end of its main-sequence lifetime, and the other is just over halfway through its main-sequence lifetime. HD 89345 hosts a warm sub-Saturn (0.66 , 0.11 , = 1100 K) in an 11.81 day orbit. The planet is similar in size to WASP-107b, which falls in the transition region between ice giants and gas giants. HD 286123 hosts a Jupiter-sized, low-mass planet (1.06 , 0.39 , = 1000 K) in an 11.17 day, mildly eccentric orbit, with e = 0.255 ± 0.035. Given that they orbit relatively evolved main-sequence stars and have orbital periods longer than 10 days, these planets are interesting candidates for studies of gas planet evolution, migration, and (potentially) reinflation. Both planets have spent their entire lifetimes near the proposed stellar irradiation threshold at which giant planets become inflated, and neither shows any sign of radius inflation. They probe the regime where inflation begins to become noticeable and are valuable in constraining planet inflation models. In addition, the brightness of the host stars, combined with large atmospheric scale heights of the planets, makes these two systems favorable targets for transit spectroscopy to study their atmospheres and perhaps provide insight into the physical mechanisms that lead to inflated hot Jupiters.

Published

2018

40. A TESS Dress Rehearsal: Planetary Candidates and Variables from K2 Campaign 17

Author

Crossfield, IJM, Crossfield, IJM, Guerrero, N, David, T, Quinn, SN, Feinstein, AD, Huang, C, Yu, L, Collins, KA, Fulton, BJ, Benneke, B, Peterson, M, Bieryla, A, Schlieder, JE, Kosiarek, MR, Bristow, M, Newton, E, Bedell, M, Latham, DW, Christiansen, JL, Esquerdo, GA, Berlind, P, Calkins, ML, Shporer, A, Burt, J, Ballard, S, Rodriguez, JE, Mehrle, N, Dressing, CD, Livingston, JH, Petigura, EA, Seager, S, Dittmann, J, Berardo, D, Sha, L, Essack, Z, Zhan, Z, Owens, M, Kain, I, Isaacson, H, Ciardi, DR, Gonzales, EJ, Howard, AW, Cardoso, JVDM, Crossfield, IJM, Crossfield, IJM, Guerrero, N, David, T, Quinn, SN, Feinstein, AD, Huang, C, Yu, L, Collins, KA, Fulton, BJ, Benneke, B, Peterson, M, Bieryla, A, Schlieder, JE, Kosiarek, MR, Bristow, M, Newton, E, Bedell, M, Latham, DW, Christiansen, JL, Esquerdo, GA, Berlind, P, Calkins, ML, Shporer, A, Burt, J, Ballard, S, Rodriguez, JE, Mehrle, N, Dressing, CD, Livingston, JH, Petigura, EA, Seager, S, Dittmann, J, Berardo, D, Sha, L, Essack, Z, Zhan, Z, Owens, M, Kain, I, Isaacson, H, Ciardi, DR, Gonzales, EJ, Howard, AW, and Cardoso, JVDM

Abstract

We produce light curves for all ∼34,000 targets observed with K2 in Campaign 17 (C17), identifying planet candidates, eclipsing binaries, and other periodic variables. The forward-facing direction of the C17 field means follow-up can begin immediately now that the campaign has concluded and interesting targets have been identified. The C17 field has a large overlap with C6, so this latest campaign also offers an infrequent opportunity to study a large number of targets already observed in a previous K2 campaign. The timing of the C17 data release, shortly before science operations begin with the Transiting Exoplanet Survey Satellite (TESS), also lets us exercise some of the tools and methods developed for identification and dissemination of planet candidates from TESS. We find excellent agreement between these results and those identified using only K2-based tools. Among our planet candidates are several planet candidates with sizes <4 R ⊕ and orbiting stars with Kp ≲ 10 (indicating good RV targets of the sort TESS hopes to find) and a Jupiter-sized single-transit event around a star already hosting a 6 day planet candidate.

Published

2018

41. Sixty validated planets from K2 campaigns 5-8

Author

Livingston, JH, Livingston, JH, Crossfield, IJM, Petigura, EA, Gonzales, EJ, Ciardi, DR, Beichman, CA, Christiansen, JL, Dressing, CD, Henning, T, Howard, AW, Isaacson, H, Fulton, BJ, Kosiarek, M, Schlieder, JE, Sinukoff, E, Tamura, M, Livingston, JH, Livingston, JH, Crossfield, IJM, Petigura, EA, Gonzales, EJ, Ciardi, DR, Beichman, CA, Christiansen, JL, Dressing, CD, Henning, T, Howard, AW, Isaacson, H, Fulton, BJ, Kosiarek, M, Schlieder, JE, Sinukoff, E, and Tamura, M

Abstract

We present a uniform analysis of 155 candidates from the second year of NASA's K2 mission (Campaigns 5-8), yielding 60 statistically validated planets spanning a range of properties with median values of R p = 2.5 R Å , P = 7.1 days, T eq = 811 K, and J = 11.3 mag. The sample includes 24 planets in 11 multiplanetary systems, as well as 18 false positives and 77 remaining planet candidates. Of particular interest are 18 planets smaller than 2 R Å , five orbiting stars brighter than J = 10 mag, and a system of four small planets orbiting the solar-type star EPIC 212157262. We compute planetary transit parameters and false-positive probabilities using a robust statistical framework and present a complete analysis incorporating the results of an intensive campaign of high-resolution imaging and spectroscopic observations. This work brings the K2 yield to over 360 planets, and by extrapolation, we expect that K2 will have discovered ∼600 planets before the expected depletion of its onboard fuel in late 2018.

Published

2018

42. Kepler-1656b: A Dense Sub-Saturn with an Extreme Eccentricity

Author

Brady, MT, Brady, MT, Petigura, EA, Knutson, HA, Sinukoff, E, Isaacson, H, Hirsch, LA, Fulton, BJ, Kosiarek, MR, Howard, AW, Brady, MT, Brady, MT, Petigura, EA, Knutson, HA, Sinukoff, E, Isaacson, H, Hirsch, LA, Fulton, BJ, Kosiarek, MR, and Howard, AW

Abstract

Kepler-1656b is a 5 RÅ planet with an orbital period of 32 days initially detected by the prime Kepler mission. We obtained precision radial velocities of Kepler-1656 with Keck/HIRES in order to confirm the planet and to characterize its mass and orbital eccentricity. With a mass of 48±4 M·, Kepler-1656b is more massive than most planets of comparable size. Its high mass implies that a significant fraction, roughly 80%, of the planet's total mass is in high-density material such as rock/iron, with the remaining mass in a low-density H/He envelope. The planet also has a high eccentricity of 0.84 ± 0.01, the largest measured eccentricity for any planet less than 100 M·. The planet's high density and high eccentricity may be the result of one or more scattering and merger events during or after the dispersal of the protoplanetary disk.

Published

2018

43. Planetary Candidates from K2 Campaign 16

Author

Yu, L, Yu, L, Crossfield, IJM, Schlieder, JE, Kosiarek, MR, Feinstein, AD, Livingston, JH, Howard, AW, Benneke, B, Petigura, EA, Bristow, M, Christiansen, JL, Ciardi, DR, Crepp, JR, Dressing, CD, Fulton, BJ, Gonzales, EJ, Hardegree-Ullman, KK, Henning, T, Isaacson, H, Lépine, S, Martinez, AO, Morales, FY, Sinukoff, E, Yu, L, Yu, L, Crossfield, IJM, Schlieder, JE, Kosiarek, MR, Feinstein, AD, Livingston, JH, Howard, AW, Benneke, B, Petigura, EA, Bristow, M, Christiansen, JL, Ciardi, DR, Crepp, JR, Dressing, CD, Fulton, BJ, Gonzales, EJ, Hardegree-Ullman, KK, Henning, T, Isaacson, H, Lépine, S, Martinez, AO, Morales, FY, and Sinukoff, E

Abstract

Given that Campaign 16 of the K2 mission is one of just two K2 campaigns observed so far in "forward-facing" mode, which enables immediate follow-up observations from the ground, we present a catalog of interesting targets identified through photometry alone. Our catalog includes 30 high-quality planet candidates (showing no signs of being non-planetary in nature), 48 more ambiguous events that may be either planets or false positives, 164 eclipsing binaries, and 231 other regularly periodic variable sources. We have released light curves for all targets in C16 and have also released system parameters and transit vetting plots for all interesting candidates identified in this paper. Of particular interest is a candidate planet orbiting the bright F dwarf HD 73344 (V = 6.9, K = 5.6) with an orbital period of 15 days. If confirmed, this object would correspond to a 2.56 ±0.18 R ⊕ planet and would likely be a favorable target for radial velocity characterization. This paper is intended as a rapid release of planet candidates, eclipsing binaries, and other interesting periodic variables to maximize the scientific yield of this campaign, and as a test run for the upcoming TESS mission, whose frequent data releases call for similarly rapid candidate identification and efficient follow up.

Published

2018

44. Planet Candidates from K2 Campaigns 5-8 and Follow-up Optical Spectroscopy

Author

Petigura, EA, Petigura, EA, Crossfield, IJM, Isaacson, H, Beichman, CA, Christiansen, JL, Dressing, CD, Fulton, BJ, Howard, AW, Kosiarek, MR, Lépine, S, Schlieder, JE, Sinukoff, E, Yee, SW, Petigura, EA, Petigura, EA, Crossfield, IJM, Isaacson, H, Beichman, CA, Christiansen, JL, Dressing, CD, Fulton, BJ, Howard, AW, Kosiarek, MR, Lépine, S, Schlieder, JE, Sinukoff, E, and Yee, SW

Abstract

We present 151 planet candidates orbiting 141 stars from K2 campaigns 5-8 (C5-C8), identified through a systematic search of K2 photometry. In addition, we identify 16 targets as likely eclipsing binaries, based on their light curve morphology. We obtained follow-up optical spectra of 105/141 candidate host stars and 8/16 eclipsing binaries to improve stellar properties and to identify spectroscopic binaries. Importantly, spectroscopy enables measurements of host star radii with ≈10% precision, compared to ≈40% precision when only broadband photometry is available. The improved stellar radii enable improved planet radii. Our curated catalog of planet candidates provides a starting point for future efforts to confirm and characterize K2 discoveries.

Published

2018

45. The California-Kepler Survey. I. High-resolution Spectroscopy of 1305 Stars Hosting Kepler Transiting Planets

Author

Petigura, EA, Petigura, EA, Howard, AW, Marcy, GW, Johnson, JA, Isaacson, H, Cargile, PA, Hebb, L, Fulton, BJ, Weiss, LM, Morton, TD, Winn, JN, Rogers, LA, Sinukoff, E, Hirsch, LA, Crossfield, IJM, Petigura, EA, Petigura, EA, Howard, AW, Marcy, GW, Johnson, JA, Isaacson, H, Cargile, PA, Hebb, L, Fulton, BJ, Weiss, LM, Morton, TD, Winn, JN, Rogers, LA, Sinukoff, E, Hirsch, LA, and Crossfield, IJM

Abstract

The California-Kepler Survey (CKS) is an observational program developed to improve our knowledge of the properties of stars found to host transiting planets by NASA's Kepler Mission. The improvement stems from new high-resolution optical spectra obtained using HIRES at the W. M. Keck Observatory. The CKS stellar sample comprises 1305 stars classified as Kepler objects of interest, hosting a total of 2075 transiting planets. The primary sample is magnitude-limited (Kp < 14.2) and contains 960 stars with 1385 planets. The sample was extended to include some fainter stars that host multiple planets, ultra-short period planets, or habitable zone planets. The spectroscopic parameters were determined with two different codes, one based on template matching and the other on direct spectral synthesis using radiative transfer. We demonstrate a precision of 60 K in Teff, 0.10 dex in log g, 0.04 dex in [Fe/H], and 1.0km s-1 in V sin i. In this paper, we describe the CKS project and present a uniform catalog of spectroscopic parameters. Subsequent papers in this series present catalogs of derived stellar properties such as mass, radius, and age; revised planet properties; and statistical explorations of the ensemble. CKS is the largest survey to determine the properties of Kepler stars using a uniform set of high-resolution, high signal-to-noise ratio spectra. The HIRES spectra are available to the community for independent analyses.

Published

2017

46. The California-Kepler Survey. III. A Gap in the Radius Distribution of Small Planets

Author

Fulton, BJ, Fulton, BJ, Petigura, EA, Howard, AW, Isaacson, H, Marcy, GW, Cargile, PA, Hebb, L, Weiss, LM, Johnson, JA, Morton, TD, Sinukoff, E, Crossfield, IJM, Hirsch, LA, Fulton, BJ, Fulton, BJ, Petigura, EA, Howard, AW, Isaacson, H, Marcy, GW, Cargile, PA, Hebb, L, Weiss, LM, Johnson, JA, Morton, TD, Sinukoff, E, Crossfield, IJM, and Hirsch, LA

Abstract

The size of a planet is an observable property directly connected to the physics of its formation and evolution. We used precise radius measurements from the California-Kepler Survey to study the size distribution of 2025 Kepler planets in fine detail. We detect a factor of ≥2 deficit in the occurrence rate distribution at 1.5-2.0 R⊕. This gap splits the population of close-in (P < 100 days) small planets into two size regimes: Rp < 1.5⊕ and RP = 2.0-3.0R⊕, with few planets in between. Planets in these two regimes have nearly the same intrinsic frequency based on occurrence measurements that account for planet detection efficiencies. The paucity of planets between 1.5 and 2.0 R⊕ supports the emerging picture that close-in planets smaller than Neptune are composed of rocky cores measuring 1.5 R⊕ or smaller with varying amounts of low-density gas that determine their total sizes.

Published

2017

47. Four Sub-Saturns with Dissimilar Densities: Windows into Planetary Cores and Envelopes

Author

Petigura, EA, Petigura, EA, Sinukoff, E, Lopez, ED, Crossfield, IJM, Howard, AW, Brewer, JM, Fulton, BJ, Isaacson, HT, Ciardi, DR, Howell, SB, Everett, ME, Horch, EP, Hirsch, LA, Weiss, LM, Schlieder, JE, Petigura, EA, Petigura, EA, Sinukoff, E, Lopez, ED, Crossfield, IJM, Howard, AW, Brewer, JM, Fulton, BJ, Isaacson, HT, Ciardi, DR, Howell, SB, Everett, ME, Horch, EP, Hirsch, LA, Weiss, LM, and Schlieder, JE

Abstract

We present results from a Keck/HIRES radial velocity campaign to study four sub-Saturn-sized planets, K2-27b, K2-32b, K2-39b, and K2-108b, with the goal of understanding their masses, orbits, and heavy-element enrichment. The planets have similar sizes (RP=4.5-5.5 ), but have dissimilar masses (MP=16-60 ), implying a diversity in their core and envelope masses. K2-32b is the least massive (MP = 16.5 ± 2.7 M) and orbits in close proximity to two sub-Neptunes near a 3:2:1 period commensurability. K2-27b and K2-39b are significantly more massive at MP = 30.9 ± 4.6 M and MP = 39.8 ± 4.4 M, respectively, and show no signs of additional planets. K2-108b is the most massive at MP = 59.4 ± 4.4 M, implying a large reservoir of heavy elements of about ≈50 . Sub-Saturns as a population have a large diversity in planet mass at a given size. They exhibit remarkably little correlation between mass and size; sub-Saturns range from ≈6-60 M, regardless of size. We find a strong correlation between planet mass and host star metallicity, suggesting that metal-rich disks form more massive planet cores. The most massive sub-Saturns tend to lack detected companions and have moderately eccentric orbits, perhaps as a result of a previous epoch of dynamical instability. Finally, we observe only a weak correlation between the planet envelope fraction and present-day equilibrium temperature, suggesting that photo-evaporation does not play a dominant role in determining the amount of gas sub-Saturns accrete from their protoplanetary disks.

Published

2017

48. Constraints on the Obliquities of Kepler Planet-hosting Stars

Author

Winn, JN, Winn, JN, Petigura, EA, Morton, TD, Weiss, LM, Dai, F, Schlaufman, KC, Howard, AW, Isaacson, H, Marcy, GW, Justesen, AB, Albrecht, S, Winn, JN, Winn, JN, Petigura, EA, Morton, TD, Weiss, LM, Dai, F, Schlaufman, KC, Howard, AW, Isaacson, H, Marcy, GW, Justesen, AB, and Albrecht, S

Abstract

Stars with hot Jupiters have obliquities ranging from 0° to 180°, but relatively little is known about the obliquities of stars with smaller planets. Using data from the California-Kepler Survey, we investigate the obliquities of stars with planets spanning a wide range of sizes, most of which are smaller than Neptune. First, we identify 156 planet hosts for which measurements of the projected rotation velocity () and rotation period are both available. By combining estimates of v and , we find nearly all the stars to be compatible with high inclination, and hence, low obliquity (≲20°). Second, we focus on a sample of 159 hot stars ( K) for which is available but not necessarily the rotation period. We find six stars for which is anomalously low, an indicator of high obliquity. Half of these have hot Jupiters, even though only 3% of the stars that were searched have hot Jupiters. We also compare the distribution of the hot stars with planets to that of 83 control stars selected without prior knowledge of planets. The mean of the control stars is lower than that of the planet hosts by a factor of approximately , as one would expect if the planet hosts have low obliquities. All these findings suggest that the Kepler planet-hosting stars generally have low obliquities, with the exception of hot stars with hot Jupiters.

Published

2017

49. Seeing Double with K2: Testing re-inflation with two remarkably similar planets around red giant branch stars

Author

Grunblatt, SK, Grunblatt, SK, Huber, D, Gaidos, E, Lopez, ED, Howard, AW, Isaacson, HT, Sinukoff, E, Vanderburg, A, Nofi, L, Yu, J, North, TSH, Chaplin, W, Foreman-Mackey, D, Petigura, E, Ansdell, M, Weiss, L, Fulton, B, Lin, DNC, Grunblatt, SK, Grunblatt, SK, Huber, D, Gaidos, E, Lopez, ED, Howard, AW, Isaacson, HT, Sinukoff, E, Vanderburg, A, Nofi, L, Yu, J, North, TSH, Chaplin, W, Foreman-Mackey, D, Petigura, E, Ansdell, M, Weiss, L, Fulton, B, and Lin, DNC

Abstract

Despite more than 20 years since the discovery of the first gas giant planet with an anomalously large radius, the mechanism for planet inflation remains unknown. Here, we report the discovery of K2-132b, an inflated gas giant planet found with the NASA K2 Mission, and a revised mass for another inflated planet, K2-97b. These planets orbit on ≈9 day orbits around host stars that recently evolved into red giants. We constrain the irradiation history of these planets using models constrained by asteroseismology and Keck/High Resolution Echelle Spectrometer spectroscopy and radial velocity measurements. We measure planet radii of 1.31 0.11 R J and 1.30 0.07 R J, respectively. These radii are typical for planets receiving the current irradiation, but not the former, zero age main-sequence irradiation of these planets. This suggests that the current sizes of these planets are directly correlated to their current irradiation. Our precise constraints of the masses and radii of the stars and planets in these systems allow us to constrain the planetary heating efficiency of both systems as . These results are consistent with a planet re-inflation scenario, but suggest that the efficiency of planet re-inflation may be lower than previously theorized. Finally, we discuss the agreement within 10% of the stellar masses and radii, and the planet masses, radii, and orbital periods of both systems, and speculate that this may be due to selection bias in searching for planets around evolved stars.

Published

2017

50. A Transient Transit Signature Associated with the Young Star RIK-210

Author

David, TJ, David, TJ, Petigura, EA, Hillenbrand, LA, Cody, AM, Cameron, AC, Stauffer, JR, Fulton, BJ, Isaacson, HT, Howard, AW, Howell, SB, Everett, ME, Wang, J, Benneke, B, Hellier, C, West, RG, Pollacco, D, Anderson, DR, David, TJ, David, TJ, Petigura, EA, Hillenbrand, LA, Cody, AM, Cameron, AC, Stauffer, JR, Fulton, BJ, Isaacson, HT, Howard, AW, Howell, SB, Everett, ME, Wang, J, Benneke, B, Hellier, C, West, RG, Pollacco, D, and Anderson, DR

Abstract

We find transient transit-like dimming events within the K2 time series photometry of the young star RIK-210 in the Upper Scorpius OB association. These dimming events are variable in depth, duration, and morphology. High spatial resolution imaging revealed that the star is single and radial velocity monitoring indicated that the dimming events cannot be due to an eclipsing stellar or brown dwarf companion. Archival and follow-up photometry suggest the dimming events are transient in nature. The variable morphology of the dimming events suggests they are not due to a single spherical body. The ingress of each dimming event is always shallower than egress, as one would expect for an orbiting body with a leading tail. The dimming events are periodic and synchronous with the stellar rotation. However, we argue it is unlikely the dimming events could be attributed to anything on the stellar surface based on the observed depths and durations. Variable obscuration by a protoplanetary disk is unlikely on the basis that the star is not actively accreting and lacks the infrared excess associated with an inner disk. Rather, we explore the possibilities that the dimming events are due to magnetospheric clouds, a transiting protoplanet surrounded by circumplanetary dust and debris, eccentric orbiting bodies undergoing periodic tidal disruption, or an extended field of dust or debris near the corotation radius.

Published

2017