George Dransfield

Three Long-period Transiting Giant Planets from TESS

Astronomical Journal 165:6 (2023)

Authors:

R Brahm, S Ulmer-Moll, MJ Hobson, A Jordán, T Henning, T Trifonov, MI Jones, M Schlecker, N Espinoza, FI Rojas, P Torres, P Sarkis, M Tala, J Eberhardt, D Kossakowski, DJ Muñoz, JD Hartman, G Boyle, V Suc, F Bouchy, A Deline, G Chaverot, N Grieves, M Lendl, O Suarez, T Guillot, AHMJ Triaud, N Crouzet, G Dransfield, R Cloutier, K Barkaoui, RP Schwarz, C Stockdale, M Harris, I Mireles, P Evans, AW Mann, C Ziegler, D Dragomir, S Villanueva, C Mordasini, G Ricker, R Vanderspek, DW Latham, S Seager, JN Winn, JM Jenkins, M Vezie, A Youngblood, T Daylan, KA Collins, DA Caldwell, DR Ciardi, E Palle, F Murgas

Abstract:

We report the discovery and orbital characterization of three new transiting warm giant planets. These systems were initially identified as presenting single-transit events in the light curves generated from the full-frame images of the Transiting Exoplanet Survey Satellite. Follow-up radial velocity measurements and additional light curves were used to determine the orbital periods and confirm the planetary nature of the candidates. The planets orbit slightly metal-rich late F- and early G-type stars. We find that TOI 4406b has a mass of M P = 0.30 ± 0.04 M J, a radius of R P = 1.00 ± 0.02 R J, and a low-eccentricity orbit (e = 0.15 ± 0.05) with a period of P = 30.08364 ±0.00005 days. TOI 2338b has a mass of M P = 5.98 ± 0.20 M J, a radius of R P = 1.00 ± 0.01 R J, and a highly eccentric orbit (e = 0.676 ± 0.002) with a period of P = 22.65398 ± 0.00002 days. Finally, TOI 2589b has a mass of M P = 3.50 ± 0.10 M J, a radius of R P = 1.08 ± 0.03 R J, and an eccentric orbit (e = 0.522 ± 0.006) with a period of P = 61.6277 ± 0.0002 days. TOI 4406b and TOI 2338b are enriched in metals compared to their host stars, while the structure of TOI 2589b is consistent with having similar metal enrichment to its host star.

TOI-2525 b and c: A Pair of Massive Warm Giant Planets with Strong Transit Timing Variations Revealed by TESS

Astronomical Journal 165:4 (2023)

Authors:

T Trifonov, R Brahm, A Jordán, C Hartogh, T Henning, MJ Hobson, M Schlecker, S Howard, F Reichardt, N Espinoza, MH Lee, D Nesvorny, FI Rojas, K Barkaoui, D Kossakowski, G Boyle, S Dreizler, M Kürster, R Heller, T Guillot, AHMJ Triaud, L Abe, A Agabi, P Bendjoya, N Crouzet, G Dransfield, T Gasparetto, MN Günther, W Marie-Sainte, D Mékarnia, O Suarez, J Teske, RP Butler, JD Crane, S Shectman, GR Ricker, A Shporer, R Vanderspek, JM Jenkins, B Wohler, KA Collins, KI Collins, DR Ciardi, T Barclay, I Mireles, S Seager, JN Winn

Abstract:

The K-type star TOI-2525 has an estimated mass of M = 0.849 − 0.033 + 0.024 M ⊙ and radius of R = 0.785 − 0.007 + 0.007 R ⊙ observed by the TESS mission in 22 sectors (within sectors 1 and 39). The TESS light curves yield significant transit events of two companions, which show strong transit timing variations (TTVs) with a semiamplitude of ∼6 hr. We performed TTV dynamical and photodynamical light-curve analysis of the TESS data combined with radial velocity measurements from FEROS and PFS, and we confirmed the planetary nature of these companions. The TOI-2525 system consists of a transiting pair of planets comparable to Neptune and Jupiter with estimated dynamical masses of m b = 0.088 − 0.004 + 0.005 and m c = 0.709 − 0.033 + 0.034 M Jup, radii of r b = 0.88 − 0.02 + 0.02 and r c = 0.98 − 0.02 + 0.02 R Jup, and orbital periods of P b = 23.288 − 0.002 + 0.001 and P c = 49.260 − 0.001 + 0.001 days for the inner and outer planet, respectively. The period ratio is close to the 2:1 period commensurability, but the dynamical simulations of the system suggest that it is outside the mean-motion resonance (MMR) dynamical configuration. Object TOI-2525 b is among the lowest-density Neptune-mass planets known to date, with an estimated median density of ρ b = 0.174 − 0.015 + 0.016 g cm⁻³. The TOI-2525 system is very similar to the other K dwarf systems discovered by TESS, TOI-2202 and TOI-216, which are composed of almost identical K dwarf primaries and two warm giant planets near the 2:1 MMR.

The EBLM project - IX. Five fully convective M-dwarfs, precisely measured with CHEOPS and TESS light curves

Monthly Notices of the Royal Astronomical Society 519:3 (2023) 3546-3563

Authors:

D Sebastian, MI Swayne, PFL Maxted, AHMJ Triaud, SG Sousa, G Olofsson, M Beck, N Billot, S Hoyer, S Gill, N Heidari, DV Martin, CM Persson, MR Standing, Y Alibert, R Alonso, G Anglada, J Asquier, T Bárczy, D Barrado, SCC Barros, MP Battley, W Baumjohann, T Beck, W Benz, M Bergomi, I Boisse, X Bonfils, A Brandeker, C Broeg, J Cabrera, S Charnoz, A Collier Cameron, S Csizmadia, MB Davies, M Deleuil, L Delrez, ODS Demangeon, BO Demory, G Dransfield, D Ehrenreich, A Erikson, A Fortier, L Fossati, M Fridlund, D Gandolfi, M Gillon, M Güdel, J Hasiba, G Hébrard, K Heng, KG Isaak, LL Kiss, E Kopp, V Kunovac, J Laskar, A Lecavelier Des Etangs, M Lendl, C Lovis, D Magrin, J McCormac, NJ Miller, V Nascimbeni, R Ottensamer, I Pagano, E Pallé, FA Pepe, G Peter, G Piotto, D Pollacco, D Queloz, R Ragazzoni, N Rando, H Rauer, I Ribas, S Lalitha, A Santerne, NC Santos, G Scandariato, D Ségransan, AE Simon, AMS Smith, M Steller, GM Szabó, N Thomas, S Udry, V Van Grootel, NA Walton

Abstract:

Eclipsing binaries are important benchmark objects to test and calibrate stellar structure and evolution models. This is especially true for binaries with a fully convective M-dwarf component for which direct measurements of these stars' masses and radii are difficult using other techniques. Within the potential of M-dwarfs to be exoplanet host stars, the accuracy of theoretical predictions of their radius and effective temperature as a function of their mass is an active topic of discussion. Not only the parameters of transiting exoplanets but also the success of future atmospheric characterization relies on accurate theoretical predictions. We present the analysis of five eclipsing binaries with low-mass stellar companions out of a subsample of 23, for which we obtained ultra-high-precision light curves using the CHEOPS satellite. The observation of their primary and secondary eclipses are combined with spectroscopic measurements to precisely model the primary parameters and derive the M-dwarfs mass, radius, surface gravity, and effective temperature estimates using the PYCHEOPS data analysis software. Combining these results to the same set of parameters derived from TESS light curves, we find very good agreement (better than 1 per cent for radius and better than 0.2 per cent for surface gravity). We also analyse the importance of precise orbits from radial velocity measurements and find them to be crucial to derive M-dwarf radii in a regime below 5 per cent accuracy. These results add five valuable data points to the mass-radius diagram of fully convective M-dwarfs.

Precise near-infrared photometry, accounting for precipitable water vapour at SPECULOOS Southern Observatory

Monthly Notices of the Royal Astronomical Society 518:2 (2023) 2661-2670

Authors:

PP Pedersen, CA Murray, D Queloz, M Gillon, BO Demory, AHMJ Triaud, J de Wit, L Delrez, G Dransfield, E Ducrot, LJ Garcia, YGM Chew, MN Günther, E Jehin, J McCormac, P Niraula, FJ Pozuelos, BV Rackham, N Schanche, D Sebastian, SJ Thompson, M Timmermans, R Wells

Abstract:

The variability induced by precipitable water vapour (PWV) can heavily affect the accuracy of time-series photometric measurements gathered from the ground, especially in the near-infrared. We present here a novel method of modelling and mitigating this variability, as well as open-sourcing the developed tool – Umbrella. In this study, we evaluate the extent to which the photometry in three common bandpasses (ŕ, í, ź), and SPECULOOS’ primary bandpass (I + ź ), are photometrically affected by PWV variability. In this selection of bandpasses, the I + ź bandpass was found to be most sensitive to PWV variability, followed by ź, í, and ŕ. The correction was evaluated on global light curves of nearby late M- and L-type stars observed by SPECULOOS’ Southern Observatory (SSO) with the I + ź bandpass, using PWV measurements from the LHATPRO and local temperature/humidity sensors. A median reduction in RMS of 1.1 per cent was observed for variability shorter than the expected transit duration for SSO’s targets. On timescales longer than the expected transit duration, where long-term variability may be induced, a median reduction in RMS of 53.8 per cent was observed for the same method of correction.

Two temperate super-Earths transiting a nearby late-type M dwarf

Astronomy and Astrophysics 667 (2022)

Authors:

L Delrez, CA Murray, FJ Pozuelos, N Narita, E Ducrot, M Timmermans, N Watanabe, AJ Burgasser, T Hirano, BV Rackham, KG Stassun, V Van Grootel, C Aganze, M Cointepas, S Howell, L Kaltenegger, P Niraula, D Sebastian, JM Almenara, K Barkaoui, TA Baycroft, X Bonfils, F Bouchy, A Burdanov, DA Caldwell, D Charbonneau, DR Ciardi, KA Collins, T Daylan, BO Demory, J De Wit, G Dransfield, SB Fajardo-Acosta, M Fausnaugh, A Fukui, E Furlan, LJ Garcia, CL Gnilka, Y Gomez Maqueo Chew, MA Gomez-Munoz, MN Gunther, H Harakawa, K Heng, MJ Hooton, Y Hori, M Ikoma, E Jehin, JM Jenkins, T Kagetani, K Kawauchi, T Kimura, T Kodama, T Kotani, V Krishnamurthy, T Kudo, V Kunovac, N Kusakabe, DW Latham, C Littlefield, J McCormac, C Melis, M Mori, F Murgas, E Palle, PP Pedersen, D Queloz, G Ricker, L Sabin, N Schanche, U Schroffenegger, S Seager, B Shiao, S Sohy, MR Standing, M Tamura, CA Theissen, SJ Thompson, AHMJ Triaud, R Vanderspek, S Vievard, RD Wells, JN Winn, Y Zou, S Zuniga-Fernandez, M Gillon

Abstract:

Context. In the age of JWST, temperate terrestrial exoplanets transiting nearby late-type M dwarfs provide unique opportunities for characterising their atmospheres, as well as searching for biosignature gases. In this context, the benchmark TRAPPIST-1 planetary system has garnered the interest of a broad scientific community. Aims. We report here the discovery and validation of two temperate super-Earths transiting LP 890-9 (TOI-4306, SPECULOOS-2), a relatively low-activity nearby (32 pc) M6V star. The inner planet, LP 890-9 b, was first detected by TESS (and identified as TOI-4306.01) based on four sectors of data. Intensive photometric monitoring of the system with the SPECULOOS Southern Observatory then led to the discovery of a second outer transiting planet, LP 890-9 c (also identified as SPECULOOS-2 c), previously undetected by TESS. The orbital period of this second planet was later confirmed by MuSCAT3 follow-up observations. Methods. We first inferred the properties of the host star by analyzing its Lick/Kast optical and IRTF/SpeX near-infrared spectra, as well as its broadband spectral energy distribution, and Gaia parallax. We then derived the properties of the two planets by modelling multi-colour transit photometry from TESS, SPECULOOS-South, MuSCAT3, ExTrA, TRAPPIST-South, and SAINT-EX. Archival imaging, Gemini-South/Zorro high-resolution imaging, and Subaru/IRD radial velocities also support our planetary interpretation. Results. With a mass of 0.118 ± 0.002 Ma, a radius of 0.1556 ± 0.0086 Ra, and an effective temperature of 2850 ± 75 K, LP 890-9 is the second-coolest star found to host planets, after TRAPPIST-1. The inner planet has an orbital period of 2.73 d, a radius of 1.320 a0.027+0.053 Ra, and receives an incident stellar flux of 4.09 ± 0.12 Sa. The outer planet has a similar size of 1.367 a0.039+0.055Ra and an orbital period of 8.46 d. With an incident stellar flux of 0.906 ± 0.026 Sa, it is located within the conservative habitable zone, very close to its inner limit (runaway greenhouse). Although the masses of the two planets remain to be measured, we estimated their potential for atmospheric characterisation via transmission spectroscopy using a mass-radius relationship and found that, after the TRAPPIST-1 planets, LP 890-9 c is the second-most favourable habitable-zone terrestrial planet known so far (assuming for this comparison a similar atmosphere for all planets). Conclusions. The discovery of this remarkable system offers another rare opportunity to study temperate terrestrial planets around our smallest and coolest neighbours.