Abstract
We simulate the coupled stellar and tidal evolution of short-period binary stars (orbital period Porb ≲ 8 days) to investigate the orbital oscillations, instellation cycles, and orbital stability of circumbinary planets (CBPs). We consider two tidal models and show that both predict an outward-then-inward evolution of the binary’s semi-major axis abin and eccentricity ebin. This orbital evolution drives a similar evolution of the minimum CBP semi-major axis for orbital stability. By expanding on previous models to include the evolution of the mass concentration, we show that the maximum in the CBP orbital stability limit tends to occur 100 Myr after the planets form, a factor of 100 longer than previous investigations. This result provides further support for the hypothesis that the early stellar-tidal evolution of binary stars has removed CBPs from short-period binaries. We then apply the models to Kepler-47 b, a CBP orbiting close to its host stars’ stability limit, to show that if the binary’s initial ebin ≳ 0.24, the planet would have been orbiting within the instability zone in the past and probably wouldn’t have survived. For stable, hypothetical cases in which the stability limit does not reach a planet’s orbit, we find that the amplitudes of abin and ebin oscillations can damp by up to 10% and 50%, respectively. Finally, we consider equal-mass stars with Porb = 7.5 days and compare the HZ to the stability limit. We find that for stellar masses ≲0.12 M⊙, the HZ is completely unstable, even if the binary orbit is circular. For ebin ≲ 0.5, that limit increases to 0.17 M⊙, and the HZ is partially destabilized for stellar masses up to 0.45 M⊙. These results may help guide searches for potentially habitable CBPs, as well as characterize their evolution and likelihood to support life after they are found.
Highlights
The discovery of circumbinary planets (CBPs) has opened up the possibility that we may discover some that support liquid surface water and detectable biosignatures
We examine the results of several suites of simulations that elucidated how the coupled stellar–tidal evolution of binary stars can impact the evolution of their planets
We have explored the time evolution of CBPs orbiting low-mass short-period binary stars to further explore how tidal effects and
Summary
The discovery of circumbinary planets (CBPs) has opened up the possibility that we may discover some that support liquid surface water and detectable biosignatures. The incident stellar radiation (instellation) on a CBP necessarily evolves due to the time-varying gravitational interactions of its two host stars, potentially affecting the longterm stability of liquid water on CBPs. The incident stellar radiation (instellation) on a CBP necessarily evolves due to the time-varying gravitational interactions of its two host stars, potentially affecting the longterm stability of liquid water on CBPs While this dynamical feature of CBPs is well known (e.g., Dole 1964; Kane & Hinkel 2013; Forgan 2016; Popp & Eggl 2017), past works have not considered how the long-term tidal evolution of the host binary stars can impact the orbital evolution and habitability of CBPs. In this paper, we perform simulations of a single planet orbiting two stars with a binary orbital period (Porb) less than ∼10 days, that is, where tidal forces are expected to strongly impact the binary orbit (Zahn & Bouchet 1989; Meibom & Mathieu 2005; Fleming et al 2018). We examine the orbital stability and long-term orbital oscillations of potentially habitable CBPs to determine the conditions that permit binary stars to host habitable CBPs, as well as to predict the properties and evolutionary histories of potentially habitable planets in those systems
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