George Dransfield

Transit timings variations in the three-planet system: TOI-270

Monthly Notices of the Royal Astronomical Society Oxford University Press 510:4 (2021) 5464-5485

Authors:

Laurel Kaye, Shreyas Vissapragada, Maximilian N Gunther, Suzanne Aigrain, Thomas Mikal-Evans, Eric LN Jensen, Hannu Parviainen, Francisco J Pozuelos, Lyu Abe, Jack S Acton, Abdelkrim Agabi, Douglas R Alves, David R Anderson, David J Armstrong, Khalid Barkaoui, Oscar Barragan, Bjorn Benneke, Patricia T Boyd, Rafael Brahm, Ivan Bruni, Edward M Bryant, Matthew R Burleigh, Sarah L Casewell, David Ciardi, Ryan Cloutier, Karen A Collins, Kevin I Collins, Dennis M Conti, Ian JM Crossfield, Nicolas Crouzet, Tansu Daylan, Diana Dragomir, Georgina Dransfield, Daniel Fabrycky, Michael Fausnaugh, Tianjun Gan, Samuel Gill, Michael Gillon, Michael R Goad, Varoujan Gorjian, Michael Greklek-McKeon, Natalia Guerrero, Tristan Guillot, Emmanuel Jehin, Js Jenkins, Monika Lendl, Jacob Kamler, Stephen R Kane, John F Kielkopf, Michelle Kunimoto

Abstract:

We present ground- and space-based photometric observations of TOI-270 (L231-32), a system of three transiting planets consisting of one super-Earth and two sub-Neptunes discovered by TESS around a bright (K-mag = 8.25) M3V dwarf. The planets orbit near low-order mean-motion resonances (5:3 and 2:1) and are thus expected to exhibit large transit timing variations (TTVs). Following an extensive observing campaign using eight different observatories between 2018 and 2020, we now report a clear detection of TTVs for planets c and d, with amplitudes of ∼10 min and a super-period of ∼3 yr, as well as significantly refined estimates of the radii and mean orbital periods of all three planets. Dynamical modelling of the TTVs alone puts strong constraints on the mass ratio of planets c and d and on their eccentricities. When incorporating recently published constraints from radial velocity observations, we obtain masses of Mb=1.48± 0.18, M⊕, Mc=6.20± 0.31, M⊕, and Md=4.20± 0.16, M⊕ for planets b, c, and d, respectively. We also detect small but significant eccentricities for all three planets: eb = 0.0167 ± 0.0084, ec = 0.0044 ± 0.0006, and ed = 0.0066 ± 0.0020. Our findings imply an Earth-like rocky composition for the inner planet, and Earth-like cores with an additional He/H2O atmosphere for the outer two. TOI-270 is now one of the best constrained systems of small transiting planets, and it remains an excellent target for atmospheric characterization.

TOI-1231 b: A Temperate, Neptune-sized Planet Transiting the Nearby M3 Dwarf NLTT 24399

The Astronomical Journal American Astronomical Society 162:3 (2021) 87

Authors:

Jennifer A Burt, Diana Dragomir, Paul Mollière, Allison Youngblood, Antonio García Muñoz, John McCann, Laura Kreidberg, Chelsea X Huang, Karen A Collins, Jason D Eastman, Lyu Abe, Jose M Almenara, Ian JM Crossfield, Carl Ziegler, Joseph E Rodriguez, Eric E Mamajek, Keivan G Stassun, Samuel P Halverson, Steven Villanueva, R Paul Butler, Sharon Xuesong Wang, Richard P Schwarz, George R Ricker, Roland Vanderspek, David W Latham, S Seager, Joshua N Winn, Jon M Jenkins, Abdelkrim Agabi, Xavier Bonfils, David Ciardi, Marion Cointepas, Jeffrey D Crane, Nicolas Crouzet, Georgina Dransfield, Fabo Feng, Elise Furlan, Tristan Guillot, Arvind F Gupta, Steve B Howell, Eric LN Jensen, Nicholas Law, Andrew W Mann, Wenceslas Marie-Sainte, Rachel A Matson, Elisabeth C Matthews, Djamel Mékarnia, Joshua Pepper, Nic Scott, Stephen A Shectman, Joshua E Schlieder, François-Xavier Schmider, Daniel J Stevens, Johanna K Teske, Amaury HMJ Triaud, David Charbonneau, Zachory K Berta-Thompson, Christopher J Burke, Tansu Daylan, Thomas Barclay, Bill Wohler, CE Brasseur

Warm jupiters in tess full-frame images: A catalog and observed eccentricity distribution for year 1

Astrophysical Journal Supplement Series 255:1 (2021)

Authors:

J Dong, CX Huang, RI Dawson, D Foreman-Mackey, KA Collins, SN Quinn, JJ Lissauer, T Beatty, B Quarles, L Sha, A Shporer, Z Guo, SR Kane, L Abe, K Barkaoui, Z Benkhaldoun, R Brahm, F Bouchy, TW Carmichael, KI Collins, DM Conti, N Crouzet, G Dransfield, P Evans, T Gan, M Ghachoui, M Gillon, N Grieves, T Guillot, C Hellier, E Jehin, ELN Jensen, A Jordán, J Kamler, JF Kielkopf, D Mékarnia, LD Nielsen, FJ Pozuelos, DJ Radford, FX Schmider, RP Schwarz, C Stockdale, TG Tan, M Timmermans, AHMJ Triaud, G Wang, G Ricker, R Vanderspek, DW Latham, S Seager, JN Winn, JM Jenkins, I Mireles, DA Yahalomi, EH Morgan, M Vezie, EV Quintana, ME Rose, JC Smith, B Shiao

Abstract:

Warm Jupiters-defined here as planets larger than 6 Earth radii with orbital periods of 8-200 days-are a key missing piece in our understanding of how planetary systems form and evolve. It is currently debated whether Warm Jupiters form in situ, undergo disk or high-eccentricity tidal migration, or have a mixture of origin channels. These different classes of origin channels lead to different expectations for Warm Jupiters' properties, which are currently difficult to evaluate due to the small sample size. We take advantage of the Transiting Exoplanet Survey Satellite (TESS) survey and systematically search for Warm Jupiter candidates around main-sequence host stars brighter than the TESS-band magnitude of 12 in the full-frame images in Year 1 of the TESS Prime Mission data. We introduce a catalog of 55 Warm Jupiter candidates, including 19 candidates that were not originally released as TESS objects of interest by the TESS team. We fit their TESS light curves, characterize their eccentricities and transit-timing variations, and prioritize a list for ground-based follow-up and TESS Extended Mission observations. Using hierarchical Bayesian modeling, we find the preliminary eccentricity distributions of our Warm-Jupiter-candidate catalog using a beta distribution, a Rayleigh distribution, and a two-component Gaussian distribution as the functional forms of the eccentricity distribution. Additional follow-up observations will be required to clean the sample of false positives for a full statistical study, derive the orbital solutions to break the eccentricity degeneracy, and provide mass measurements.

Cluster Difference Imaging Photometric Survey. II. TOI 837: A Young Validated Planet in IC 2602

Astronomical Journal 160:5 (2020)

Authors:

LG Bouma, JD Hartman, R Brahm, P Evans, KA Collins, G Zhou, P Sarkis, SN Quinn, J De Leon, J Livingston, C Bergmann, KG Stassun, W Bhatti, JN Winn, G Bakos, L Abe, N Crouzet, G Dransfield, T Guillot, W Marie-Sainte, D Mékarnia, AHMJ Triaud, CG Tinney, T Henning, N Espinoza, A Jordán, M Barbieri, S Nandakumar, T Trifonov, JI Vines, M Vuckovic, C Ziegler, N Law, AW Mann, GR Ricker, R Vanderspek, S Seager, JM Jenkins, CJ Burke, D Dragomir, AM Levine, EV Quintana, JE Rodriguez, JC Smith, B Wohler

Abstract:

We report the discovery of TOI 837b and its validation as a transiting planet. We characterize the system using data from the NASA Transiting Exoplanet Survey Satellite mission, the ESA Gaia mission, ground-based photometry from El Sauce and ASTEP400, and spectroscopy from CHIRON, FEROS, and Veloce. We find that TOI 837 is a T = 9.9 mag G0/F9 dwarf in the southern open cluster IC 2602. The star and planet are therefore million years old. Combining the transit photometry with a prior on the stellar parameters derived from the cluster color-magnitude diagram, we find that the planet has an orbital period of and is slightly smaller than Jupiter. From radial velocity monitoring, we limit to less than 1.20 M Jup (3σ). The transits either graze or nearly graze the stellar limb. Grazing transits are a cause for concern, as they are often indicative of astrophysical false-positive scenarios. Our follow-up data show that such scenarios are unlikely. Our combined multicolor photometry, high-resolution imaging, and radial velocities rule out hierarchical eclipsing binary scenarios. Background eclipsing binary scenarios, though limited by speckle imaging, remain a 0.2% possibility. TOI 837b is therefore a validated adolescent exoplanet. The planetary nature of the system can be confirmed or refuted through observations of the stellar obliquity and the planetary mass. Such observations may also improve our understanding of how the physical and orbital properties of exoplanets change in time.