Exoplanets and Stellar Physics

About the modelling of the SED for the inner boundary of protoplanetary discs at the lower stellar mass regime

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 506:4 (2021) 5361-5372

Authors:

Sebastián Morales-Gutiérrez, Erick Nagel, Oscar Barragan

Erratum: “Vertical Tracer Mixing in Hot Jupiter Atmospheres” (2019, ApJ, 881, 152)

The Astrophysical Journal American Astronomical Society 917:2 (2021) 112

Authors:

Thaddeus D Komacek, Adam P Showman, Vivien Parmentier

A HARPS-N mass for the elusive Kepler-37d: a case study in disentangling stellar activity and planetary signals

Monthly Notices of the Royal Astronomical Society Oxford University Press 507:2 (2021) 1847-1868

Authors:

Vinesh Maguire Rajpaul, La Buchhave, G Lacedelli, K Rice, A Mortier, L Malavolta, Suzanne Aigrain, L Borsato, Aw Mayo, D Charbonneau, M Damasso, X Dumusque, A Ghedina, Dw Latham, M López-Morales, A Magazzù, G Micela, E Molinari, F Pepe, G Piotto, E Poretti, S Rowther, A Sozzetti, S Udry, Ca Watson

Abstract:

To date, only 18 exoplanets with radial velocity (RV) semi-amplitude <2 m s⁻¹ have had their masses directly constrained. The biggest obstacle to RV detection of such exoplanets is variability intrinsic to stars themselves, e.g. nuisance signals arising from surface magnetic activity such as rotating spots and plages, which can drown out or even mimic planetary RV signals. We use Kepler-37 – known to host three transiting planets, one of which, Kepler-37d, should be on the cusp of RV detectability with modern spectrographs – as a case study in disentangling planetary and stellar activity signals. We show how two different statistical techniques – one seeking to identify activity signals in stellar spectra, and another to model activity signals in extracted RVs and activity indicators – can each enable a detection of the hitherto elusive Kepler-37d. Moreover, we show that these two approaches can be complementary, and in combination, facilitate a definitive detection and precise characterization of Kepler-37d. Its RV semi-amplitude of 1.22 ± 0.31 m s⁻¹ (mass 5.4 ± 1.4 M_⊕) is formally consistent with TOI-178b’s 1.05^+0.25_−0.30 m s⁻¹, the latter being the smallest detected RV signal of any transiting planet to date, though dynamical simulations suggest Kepler-37d’s mass may be on the lower end of our 1σ credible interval. Its consequent density is consistent with either a water-world or that of a gaseous envelope (⁠∼0.4 per cent by mass) surrounding a rocky core. Based on RV modelling and a re-analysis of Kepler-37 TTVs, we also suggest that the putative (non-transiting) planet Kepler-37e should be stripped of its ‘confirmed’ status.

A HARPS-N mass for the elusive Kepler-37d: a case study in disentangling stellar activity and planetary signals

(2021)

Authors:

VM Rajpaul, LA Buchhave, G Lacedelli, K Rice, A Mortier, L Malavolta, S Aigrain, L Borsato, AW Mayo, D Charbonneau, M Damasso, X Dumusque, A Ghedina, DW Latham, M López-Morales, A Magazzù, G Micela, E Molinari, F Pepe, G Piotto, E Poretti, S Rowther, A Sozzetti, S Udry, CA Watson

High-contrast observations of brown dwarf companion HR 2562 B with the vector Apodizing Phase Plate coronagraph

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 506:3 (2021) 3224-3238

Authors:

Ben J Sutlieff, Alexander J Bohn, Jayne L Birkby, Matthew A Kenworthy, Katie M Morzinski, David S Doelman, Jared R Males, Frans Snik, Laird M Close, Philip M Hinz, David Charbonneau