A search for transiting planets around hot subdwarfs. II. Supplementary methods and results from TESS Cycle 1
Metadatos
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EDP Sciences
Materia
Planet-star interactions Planetary systems Stars: horizontal-branch Subdwarfs Techniques: photometric
Date
2022-08-17Referencia bibliográfica
A. Thuillier et al. A search for transiting planets around hot subdwarfs. II. Supplementary methods and results from TESS Cycle 1. A&A 664, A113 (2022) [https://doi.org/10.1051/0004-6361/202243554]
Patrocinador
Aarhus Universitet; Australian Research Council; Danmarks Grundforskningsfond DNRF106; ESA PEA 4000119301; Wallonia-Brussels Federation; National Aeronautics and Space Administration; Centre National d’Etudes Spatiales; Université de LiègeRésumé
Context. Hot subdwarfs, which are hot and small He-burning objects, are ideal targets for exploring the evolution of planetary systems
after the red giant branch (RGB). Thus far, no planets have been confirmed around them, and no systematic survey to find planets has
been carried out.
Aims. In this project, we aim to perform a systematic transit survey in all light curves of hot subdwarfs from space-based telescopes
(Kepler, K2, TESS, and CHEOPS). The goal is to compute meaningful statistics on two points: firstly, the occurrence rates of planets
around hot subdwarfs, and secondly, the probability of survival for close-in planets engulfed during the RGB phase of their host. This
paper focuses on the analysis of the observations carried out during cycle 1 of the TESS mission.
Methods. We used our specifically designed pipeline SHERLOCK to search for transits in the available light curves. When a signal is
detected, it is processed in the next evaluating stages before an object is qualified for follow-up observations and in-depth analysis to
determine the nature of the transiting body.
Results. We applied our method to the 792 hot subdwarfs observed during cycle 1 of TESS. While 378 interesting signals were
detected in the light curves, only 26 stars were assigned for follow-up observations. We have identified a series of eclipsing binaries,
transiting white dwarfs, and other types of false positives, but no planet has been confirmed thus far. A first computation of the upper
limit for occurrence rates was made with the 549 targets displaying no signal.
Conclusions. The tools and method we developed proved their efficiency in analysing the available light curves from space missions,
from detecting an interesting signal to identifying a transiting planet. This will allow us to fulfil the two main goals of this project.