Editor’s Note: In these last two weeks of 2022, we’ll be looking at a few selections that we haven’t yet discussed on AAS Nova from among the most-downloaded articles published in AAS journals this year. The usual posting schedule will resume in January.
System Architecture and Planetary Obliquity: Implications for Long-term Habitability
Published September 2022
Main takeaway:
Pam Vervoort (University of California, Riverside) and collaborators used N-body simulations and climate models to study how the presence of a Jupiter-like planet affects the long-term habitability of an Earth-like planet in the same planetary system. The team’s simulations showed that if Jupiter’s orbit were more elliptical, more of Earth’s surface might be habitable than it is today.
Why it’s interesting:
With the number of confirmed exoplanets now above 5,000, many astronomers have switched from finding planets to characterizing them. Among the possible characterizations of an exoplanet is determining if it’s within its host star’s habitable zone. While the concept of the habitable zone is simple — and it’s straightforward to estimate if a planet is currently in a star’s habitable zone based on the luminosity of the star and the orbital distance of the planet — the actual location of a star’s habitable zone is expected to change over time. As stars age, their luminosity changes, and the dynamics of multi-planet systems can shift a planet’s orbital distance. Vervoort and collaborators’ simulations provide a way to estimate the impacts of some of these changes.
How a neighboring Jupiter-like planet affects habitability:
Sea ice cover, eccentricity (how elliptical the orbit is), and obliquity (how tilted the planet is), and fractional habitability of an Earth-like planet in a system with a Jupiter-like planet with varying orbital parameters. Click to enlarge. [Vervoort et al. 2022]
Citation
Pam Vervoort et al 2022 AJ 164 130. doi:10.3847/1538-3881/ac87fd