Revisiting the exoplanet radius valley with host stars from SWEET-Cat

Abstract

The radius valley,a deficit of planets near 2 R, was observed among exoplanets of radius 5 R with periods < 100 days by NASA's Kepler mission. It separates super-Earths (rocky, 1.9 R) from sub-Neptunes (volatile-rich, 2 R) and may arise from formation conditions or atmospheric loss. Disentangling these mechanisms has led to numerous studies of population-level trends, although the resulting interpretations remain sensitive to sample selection and the robustness of host-star parameters. We re-examine its existence, depth, and dependence on period, flux, stellar mass, and age. Using SWEET-Cat and MAISTEP tool, we derived stellar parameters for 1,221 main-sequence stars (1,405 planets), with effective temperatures 4400--7500 K and radii 0.62--2.75 R, achieving 2\% precision in radius and mass. Planetary radii were recomputed from radius ratios, yielding 5\% median uncertainty. The valley is partially filled near 2 R and depends on period, flux, and stellar mass, with slopes -0.12+0.02-0.01, 0.10+0.02-0.03, and 0.19+0.09-0.07. Sub-Neptunes show a stronger stellar mass-dependent trend than super-Earths (0.17+0.04-0.04 vs 0.11+0.05-0.05). With stellar age, the super-Earth/sub-Neptune ratio rises from 0.51+0.11-0.08 (<3 Gyr) to 0.64+0.11-0.11 (3 Gyr), and the valley becomes shallower and shifts to larger radii. A 4D fit shows consistent slopes with 2D analyses and a weaker age trend (0.07+0.03-0.04). These results suggest prolonged atmospheric loss, which is consistent with a core-powered mass loss scenario and emphasize the need for improved determinations, a goal expected to be achieved by future missions like PLATO.