A Tale of Two Peas-In-A-Pod: The Kepler-323 and Kepler-104 Systems

Abstract

In order to understand the relationship between planet multiplicity, mass, and composition, we present newly measured masses of five planets in two planetary systems: Kepler-323 and Kepler-104. We used the HIRES instrument at the W.M. Keck Observatory to collect 79 new radial velocity measurements (RVs) for Kepler-323, which we combined with 48 literature RVs from TNG/HARPS-N. We also conducted a reanalysis of the Kepler-104 system, using 44 previously published RV measurements. Kepler-323 b and c have masses of 2.0+1.2-1.1 M and 6.51.6 M, respectively, whereas the three Kepler-104 planets are more massive (10.02.8 M, 7.1+3.8-3.5 M, and 5.5+4.6-3.5 M for planets b, c, and d, respectively). The Kepler-104 planets have densities consistent with rocky cores overlaid with gaseous envelopes (4.1+1.2-1.1 g/cc, 2.9+1.7-1.5 g/cc, and 1.6+1.5-1.1 g/cc respectively), whereas the Kepler-323 planets are consistent with having rocky compositions (4.5+2.8-2.4 g/cc and 9.9+2.7-2.5 g/cc). The Kepler-104 system has among the lowest values for gap complexity (C = 0.004) and mass partitioning (Q = 0.03); whereas, the Kepler-323 planets have a mass partitioning similar to that of the Inner Solar System (Q = 0.28 and Q = 0.24, respectively). For both exoplanet systems, the uncertainty in the mass partitioning is affected equally by (1) individual mass errors of the planets and (2) the possible existence of undetected low-mass planets, meaning that both improved mass characterization and improved sensitivity to low-mass planets in these systems would better elucidate the mass distribution among the planets.