Comparing Results from Two Uniform Phase Curve Surveys

TL;DR

This paper compares two recent Spitzer phase curve studies, analyzing their consistency in exoplanet parameter estimates and highlighting the importance of verifying system parameters with Kepler's law.

Contribution

It provides a detailed comparison of two independent phase curve analyses, revealing population-level agreement and individual discrepancies, and emphasizes the need for parameter consistency checks.

Findings

Studies produce similar population-level results.

Individual planet parameters can vary significantly.

Discrepancies in system parameters may stem from data reduction or selection methods.

Abstract

We present a comparison of the two most recent and comprehensive Spitzer phase curve studies - Dang et al. (2025) and Swain et al. (2025) - which report analyses of the Spitzer 4.5 $\mu$m phase curves. The studies employ different approaches for correcting instrument systematics and they also use different approaches for selecting the optimal exoplanet system parameters. To evaluate the level of consistency between the two studies, we compared the constraints on the ratio of planet-to-star radii ($R_P/R_\star$), eclipse depth ($F_P/F_\star$), phase curve amplitude ($A$), and phase curve offset ($\phi$). We find that the two studies produce similar results at the population level although results for individual planets can vary, especially for phase curve offset values. We examined the difference of planet system parameters to see if inconsistencies in individual planet results were due to data reduction methods or system parameter choices. We also examined whether the system parameters used by both studies were consistent with Kepler's third law. During this comparison, we identified one case where stellar mass, planet semi-major axis, and orbital period did not follow Kepler's law even though the values were all compiled from the same publication. To assess whether this kind of discrepancy was recurrent, we recalculated the orbital periods using Kepler's third law and compared them with the values listed in the NASA Exoplanet Archive. Our detailed analysis of archival system parameters strongly suggests that testing reported/selected parameters for consistency with Kepler's third law is worthwhile.