# Four Sub-Saturns with Dissimilar Densities: Windows into Planetary Cores   and Envelopes

**Authors:** Erik A. Petigura, Evan Sinukoff, Eric Lopez, Ian J. M. Crossfield,, Andrew W. Howard, John M. Brewer, Benjamin J. Fulton, Howard T. Isaacson,, David R. Ciardi, Steve B. Howell, Mark E. Everett, Elliott P. Horch, Lea, Hirsch, Lauren M. Weiss, Joshua E. Schlieder

arXiv: 1702.00013 · 2017-03-15

## TL;DR

This study analyzes four sub-Saturn-sized exoplanets to understand their mass, composition, and orbital characteristics, revealing diversity in their core and envelope masses, and correlations with host star metallicity.

## Contribution

It provides new mass measurements for four sub-Saturns, highlighting their diversity and the correlation between planet mass and host star metallicity, with implications for planet formation theories.

## Key findings

- Sub-Saturns show large diversity in mass at similar sizes.
- Strong correlation between planet mass and host star metallicity.
- Weak correlation between envelope fraction and temperature.

## Abstract

We present results from a Keck/HIRES radial velocity campaign to study four sub-Saturn-sized planets, K2-27b, K2-32b, K2-39b, and K2-108b, with the goal of understanding their masses, orbits, and heavy element enrichment. The planets have similar sizes $(R_P = 4.5-5.5~R_E)$, but have dissimilar masses $(M_P = 16-60~M_E)$, implying a diversity in their core and envelope masses. K2-32b is the least massive $(M_P = 16.5 \pm 2.7~M_E)$ and orbits in close proximity to two sub-Neptunes near a 3:2:1 period commensurability. K2-27b and K2-39b are significantly more massive at $M_P = 30.9 \pm 4.6~M_E$ and $M_P = 39.8 \pm 4.4~M_E$, respectively, and show no signs of additional planets. K2-108b is the most massive at $M_P = 59.4 \pm 4.4~M_E$, implying a large reservoir of heavy elements of about $\approx50~M_E$. Sub-Saturns as a population have a large diversity in planet mass at a given size. They exhibit remarkably little correlation between mass and size; sub-Saturns range from $\approx 6-60~M_E$, regardless of size. We find a strong correlation between planet mass and host star metallicity, suggesting that metal-rich disks form more massive planet cores. The most massive sub-Saturns tend to lack detected companions and have moderately eccentric orbits, perhaps as a result of a previous epoch of dynamical instability. Finally, we observe only a weak correlation between the planet envelope fraction and present-day equilibrium temperature, suggesting that photo-evaporation does not play a dominant role in determining the amount of gas sub-Saturns accrete from their protoplanetary disks.

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Source: https://tomesphere.com/paper/1702.00013