# HATS-54b-HATS-58Ab: five new transiting hot Jupiters including one with   a possible temperate companion

**Authors:** N\'estor Espinoza, Joel D. Hartman, Gaspar \'A. Bakos, Thomas Henning,, Daniel Bayliss, Joao Bento, Waqas Bhatti, Rafael Brahm, Zoltan Csubry,, Vincent Suc, Andr\'es Jord\'an, Luigi Mancini, T. G. Tan, Kaloyan Penev,, Markus Rabus, Paula Sarkis, Miguel de Val-Borro, Stephen Durkan, Josef Lazar,, Istvan Papp, Pal Sari

arXiv: 1812.07668 · 2019-07-24

## TL;DR

This paper reports the discovery of five new transiting hot Jupiters with diverse properties, including one with a potential temperate companion, using the HATSouth survey and Gaia data, highlighting their physical characteristics and possible additional planets.

## Contribution

The study presents five newly discovered hot Jupiters, including a candidate temperate companion, with detailed characterization and analysis of their orbital and physical properties, and evidence for an additional planet in the HATS-56 system.

## Key findings

- HATS-54b, HATS-55b, HATS-58Ab are typical short-period hot Jupiters.
- HATS-57b is a dense, massive hot Jupiter orbiting an active star.
- HATS-56b is a highly inflated hot Jupiter with a potential additional planet.

## Abstract

We report the discovery by the HATSouth project of 5 new transiting hot Jupiters (HATS-54b through HATS-58Ab). HATS-54b, HATS-55b and HATS-58Ab are prototypical short period ($P = 2.5-4.2$ days, $R_p\sim1.1-1.2$ $R_J$) hot-Jupiters that span effective temperatures from 1350 K to 1750 K, putting them in the proposed region of maximum radius inflation efficiency. The HATS-58 system is composed of two stars, HATS-58A and HATS-58B, which are detected thanks to Gaia DR2 data and which we account for in the joint modelling of the available data --- with this, we are led to conclude that the hot jupiter orbits the brighter HATS-58A star. HATS-57b is a short-period (2.35-day) massive (3.15 $M_J$) 1.14 $R_J$, dense ($2.65\pm0.21$ g cm$^{-3}$) hot-Jupiter, orbiting a very active star ($2\%$ peak-to-peak flux variability). Finally, HATS-56b is a short period (4.32-day) highly inflated hot-Jupiter (1.7 $R_J$, 0.6 $M_J$), which is an excellent target for future atmospheric follow-up, especially considering the relatively bright nature ($V=11.6$) of its F dwarf host star. This latter exoplanet has another very interesting feature: the radial velocities show a significant quadratic trend. If we interpret this quadratic trend as arising from the pull of an additional planet in the system, we obtain a period of $P_c = 815^{+253}_{-143}$ days for the possible planet HATS-56c, and a minimum mass of $M_c\sin i_c = 5.11 \pm 0.94$ $M_J$. The candidate planet HATS-56c would have a zero-albedo equilibrium temperature of $T_\textrm{eq}=332\pm 50$ K, and thus would be orbiting close to the habitable zone of HATS-56. Further radial-velocity follow-up, especially over the next two years, is needed to confirm the nature of HATS-56c.

## Full text

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## Figures

27 figures with captions in the complete paper: https://tomesphere.com/paper/1812.07668/full.md

## References

61 references — full list in the complete paper: https://tomesphere.com/paper/1812.07668/full.md

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Source: https://tomesphere.com/paper/1812.07668