CKS IX: Revisiting the Minimum-Mass Extrasolar Nebula with Precise Stellar Parameters

Abstract

We investigate a possible correlation between the solid surface density of the minimum-mass extrasolar nebulae (MMEN) and the host star mass M and metallicity [Fe/H]. Leveraging on the precise host star properties from the California- Kepler-Survey (CKS), we found that = 50+33-20 ~g~cm-2 (a/1AU)-1.750.07 (M/M)1.040.22 100.220.05 [Fe/H] for Kepler-like systems (1-4R; a<1AU). The strong M dependence is reminiscent of previous dust continuum results that the solid disk mass scales with M. The weaker [Fe/H] dependence shows that sub-Neptune planets, unlike giant planets, form readily in lower-metallicity environment. The innermost region (a< 0.1AU) of a MMEN maintains a smooth profile despite a steep decline of planet occurrence rate: a result that favors the truncation of disks by co-rotating magnetospheres with a range of rotation periods, rather than the sublimation of dusts. The of Kepler multi-transiting systems shows a much stronger correlation with M and [Fe/H] than singles. This suggests that the dynamically hot evolution that produced single systems also partially removed the memory of formation in disks. Radial-velocity planets yielded a MMEN very similar to CKS planets; transit-timing-variation planets' postulated convergent migration history is supported by their poorly constrained MMEN. We found that lower-mass stars have a higher efficiency of forming/retaining planets: for sun-like stars about 20\% of the solid mass within 1AU are converted/preserved as sub-Neptunes, compared to 70\% for late-K-early-M stars. This may be due to the lower binary fraction, lower giant-planet occurrence or the longer disk lifetime of lower-mass stars.