Planet-star interactions with precise transit timing. III. Entering the regime of dynamical tides

TL;DR

This study uses precise transit timing to investigate dynamical tides in hot Jupiter systems, finding no significant orbital decay and providing insights into stellar interior models and tidal dissipation mechanisms.

Contribution

It offers new precise transit timing data for five hot Jupiters, constrains orbital decay rates, and tests theoretical models of dynamical tide dissipation in stellar interiors.

Findings

No significant orbital decay detected in five hot Jupiter systems.

Dynamical tides likely do not operate in host stars of some systems, aligning with stellar interior models.

KELT-1 b may serve as a laboratory for studying tidal dissipation in convective layers.

Abstract

Hot Jupiters on extremely short-period orbits are expected to be unstable to tidal dissipation and spiral toward their host stars. That is because they transfer the angular momentum of the orbital motion through tidal dissipation into the stellar interior. Although the magnitude of this phenomenon is related to the physical properties of a specific star-planet system, statistical studies show that tidal dissipation might shape the architecture of hot Jupiter systems during the stellar lifetime on the main sequence. The efficiency of tidal dissipation remains poorly constrained in star-planet systems. Stellar interior models show that the dissipation of dynamical tides in radiation zones could be the dominant mechanism driving planetary orbital decay. These theoretical predictions can be verified with the transit timing method. We acquired new precise transit mid-times for five planets. They were previously identified as the best candidates for which orbital decay might be detected. Analysis of the timing data allowed us to place tighter constraints on the orbital decay rate. No statistically significant changes in their orbital periods were detected for all five hot Jupiters in systems HAT-P-23, KELT-1, KELT-16, WASP-18, and WASP-103. For planets HAT-P-23 b, WASP-18 b, and WASP-103 b, observations show that the mechanism of the dynamical tides dissipation probably does not operate in their host stars, preventing them from rapid orbital decay. This finding aligns with the models of stellar interiors of F-type stars, in which dynamical tides are not fully damped due to convective cores. For KELT-16 b, the span of transit timing data was not long enough to verify the theoretical predictions. KELT-1 b was identified as a potential laboratory for studying the dissipative tidal interactions of inertial waves in a convective layer.