The hot Saturn population exhibits a boundary in mass-radius space, such that
no planets are observed at a density less than ∼0.1 g cm−3. Yet,
planet interior structure models can readily construct such objects as the
natural result of radius inflation. Here, we investigate the role XUV-driven
mass-loss plays in sculpting the density boundary by constructing interior
structure models that include radius inflation, photoevaporative mass loss and
a simple prescription of Roche lobe overflow. We demonstrate that planets
puffier than ∼0.1 g cm−3 experience a runaway mass loss caused by
adiabatic radius expansion as the gas layer is stripped away, providing a good
explanation of the observed edge in mass-radius space. The process is also
visible in the radius-period and mass-period spaces, though smaller,
high-bulk-metallicity planets can still survive at short periods, preserving a
partial record of the population distribution at formation.Comment: 10 pages, 5 figures, submitted to ApJ Letter