The TESS–Keck Survey. IV. A Retrograde, Polar Orbit for the Ultra-low-density, Hot Super-Neptune WASP-107b

Rubenzahl, Ryan A.; Dai, Fei; Howard, Andrew W.; Chontos, Ashley; Giacalone, Steven; Lubin, Jack; Rosenthal, Lee J.; Isaacson, Howard; Batalha, Natalie M.; Crossfield, Ian J. M.; Dressing, Courtney D.; Fulton, Benjamin J.; Huber, Daniel; Kane, Stephen R.; Petigura, Erik A.; Robertson, Paul; Roy, Arpita; Weiss, Lauren M.; Beard, Corey; Hill, Michelle L.; Mayo, Andrew W.; Močnik, Teo; Murphy, Joseph M. Akana; Scarsdale, Nicholas

doi:10.3847/1538-3881/abd177

Cited by 36 publications

(28 citation statements)

References 68 publications

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“…Specifically for WASP-107, Anderson et al (2017) reported a K6 host star with a mass of M * = 0.69 M e , a radius of R * = 0.66 R e , and an effective temperature of T *,eff = 4430 K. Planet b orbits its host on a near-circular but polar orbit (Dai & Winn 2017, C. Piaulet et al 2021Rubenzahl et al 2021). The semimajor axis is a = 0.055 au where the equilibrium temperature is T eq = 740 K; the transit light curve indicates a small impact parameter (b = 0.07 Dai & Winn 2017).…”

Section: Basic Setupmentioning

confidence: 99%

“…Dai & Winn (2017) suspected that the planet is on a polar orbit owing to the lack of repeating spot-crossing events. More recently, a Rossiter-McLaughlin measurement by Rubenzahl et al (2021) confirmed this suspicion and thus demands a dynamically hot formation and evolution pathway that may involve the nontransiting planet 107c (P ∼ 1100 days,M i sin Å M 110 ; C. Piaulet et al 2021). These reasons render WASP-107b a unique and interesting system.…”

Section: Introductionmentioning

confidence: 96%

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Metastable Helium Absorptions with 3D Hydrodynamics and Self-consistent Photochemistry. II. WASP-107b, Stellar Wind, Radiation Pressure, and Shear Instability

Wang

Dai

2021

ApJ

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This paper presents simulations of the metastable helium (He * ) observations of WASP-107b, so far the highest signal-to-noise ratio detection that is confirmed by three different instruments. We employ full 3D hydrodynamics coupled with coevolving nonequilibrium thermochemistry and ray-tracing radiation, predicting mass-loss rates, temperature profiles, and synthetic He * line profiles and light curves from first principles. We find that a stellar wind stronger than solar is demanded by the observed heavily blueshifted line profile and asymmetric transit light curve. Radiation pressure can be important for Lyα observations, but not He * . Our model finds that WASP-107b is losing mass at a rate of  ´-Å -M M 1.0 10 yr 9 1 . Although  M varies by <1% given constant wind and irradiation from the host, shear instabilities still emerge from wind impacts, producing ∼10% fluctuations of He * transit depths over hour-long timescales. The common assumption that He * transit depth indicates the fluctuation of  M is problematic. The trailing tail is more susceptible than planet adjacency to the shear instabilities; thus, the line profile is more variable in the blueshifted wing, while the transit light curve is more variable after midtransit. We stress that the synergy between Lyα (higher altitudes, lower density) and He * (lower altitudes, higher density) transit observations, particularly simultaneous ones, yields better understanding of planetary outflows and stellar wind properties.

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Section: Basic Setupmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Metastable Helium Absorptions with 3D Hydrodynamics and Self-consistent Photochemistry. II. WASP-107b, Stellar Wind, Radiation Pressure, and Shear Instability

Wang

Dai

2021

ApJ

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“…Several exoplanets systems that host spin-orbit misaligned close-in small planets have been found to contain an distant giant planet, e.g., HAT-P-11 (Winn et al 2010;Yee et al 2018), π Men (Jones et al 2002;Kunovac Hodžić et al 2021), Kepler-56 (Huber et al 2013Otor et al 2016), andWASP-107 (Piaulet et al 2021;Rubenzahl et al 2021). Kepler-129 joins their ranks.…”

Section: Comparison To Other Planetary Systemsmentioning

confidence: 99%

“…The alignment between solar spin and planetary orbital axes is considered to result from the protoplanetary disk where these planets formed and has been maintained throughout the history of the solar system (Kant 1755;de Laplace 1796). On the contrary, spin-orbit misalignment has been found in dozens of exoplanet systems (e.g., Winn et al 2010;Huber et al 2013;Bourrier et al 2018;Yee et al 2018;Kamiaka et al 2019;Rubenzahl et al 2021), suggesting a different formation pathway or the occurrence of dynamical events in those systems. Measuring the spin-orbit angle therefore helps to understand the formation and evolution of planetary systems.…”

Section: Introductionmentioning

confidence: 99%

Long-period Jovian Tilts the Orbits of Two sub-Neptunes Relative to Stellar Spin Axis in Kepler-129

Zhang

Weiss

Huber

et al. 2021

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We present the discovery of Kepler-129 d ( = -+ P 7.2 d 0.3 0.4 yr, = -+ m i M sin 8.3 d 0.7 1.1 Jup , = -+ e 0.15 d 0.05 0.07 ) based on six years of radial-velocity observations from Keck/HIRES. Kepler-129 also hosts two transiting sub-Neptunes: Kepler-129 b (P b = 15.79 days, r b = 2.40 ± 0.04 R ⊕ ) and Kepler-129 c (P c = 82.20 days, r c = 2.52 ± 0.07 R ⊕ ) for which we measure masses of m b < 20 M ⊕ and = -+ Å m M 43 c 12 13. Kepler-129 is a hierarchical system consisting of two tightly packed inner planets and a massive external companion. In such a system, two inner planets precess around the orbital normal of the outer companion, causing their inclinations to oscillate with time. Based on an asteroseismic analysis of Kepler data, we find tentative evidence that Kepler-129 b and c are misaligned with stellar spin axis by 38°, which could be torqued by Kepler-129 d if it is inclined by 19°relative to inner planets. Using N-body simulations, we provide additional constraints on the mutual inclination between Kepler-129 d and inner planets by estimating the fraction of time during which two inner planets both transit. The probability that two planets both transit decreases as their misalignment with Kepler-129 d increases. We also find a more massive Kepler-129 c enables the two inner planets to become strongly coupled and more resistant to perturbations from Kepler-129 d. The unusually high mass of Kepler-129 c provides a valuable benchmark for both planetary dynamics and interior structure, since the best-fit mass is consistent with this 2.5 R ⊕ planet having a rocky surface.

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“…TKS is a consortium performing precise RV (PRV) followup of TESS planet candidates (Dalba et al 2020;Dai et al 2020;Rubenzahl et al 2021;Weiss et al 2021). One of our group's primary science goals is to measure a diverse set of planet masses at high enough precision to be suitable for atmospheric characterization (Batalha et al 2019), particularly with the James Webb Space Telescope (JWST), which is what led us to observe HD 63935.…”

Section: Introductionmentioning

confidence: 99%

TESS-Keck Survey. V. Twin Sub-Neptunes Transiting the Nearby G Star HD 63935

Scarsdale

Murphy

Batalha

et al. 2021

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We present the discovery of two nearly identically sized sub-Neptune transiting planets orbiting HD 63935, a bright (V = 8.6 mag), Sun-like (T eff = 5560 K) star at 49 pc. TESS identified the first planet, HD 63935 b (TOI-509.01), in Sectors 7 and 34. We identified the second signal (HD 63935 c) in Keck High Resolution Echelle Spectrometer and Lick Automated Planet Finder radial velocity data as part of our follow-up campaign. It was subsequently confirmed with TESS photometry in Sector 34 as TOI-509.02. Our analysis of the photometric and radial velocity data yielded a robust detection of both planets with periods of 9.0600 ± 0.007 and 21.40 ± 0.0019 days, radii of 2.99 ± 0.14 and 2.90 ± 0.13 R ⊕ , and masses of 10.8 ± 1.8 and 11.1 ± 2.4 M ⊕ . We calculated

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The TESS–Keck Survey. IV. A Retrograde, Polar Orbit for the Ultra-low-density, Hot Super-Neptune WASP-107b

Cited by 36 publications

References 68 publications

Metastable Helium Absorptions with 3D Hydrodynamics and Self-consistent Photochemistry. II. WASP-107b, Stellar Wind, Radiation Pressure, and Shear Instability

Metastable Helium Absorptions with 3D Hydrodynamics and Self-consistent Photochemistry. II. WASP-107b, Stellar Wind, Radiation Pressure, and Shear Instability

Long-period Jovian Tilts the Orbits of Two sub-Neptunes Relative to Stellar Spin Axis in Kepler-129

TESS-Keck Survey. V. Twin Sub-Neptunes Transiting the Nearby G Star HD 63935

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