Orbital misalignment of the super-Earth π Men c with the spin of its star

Abstract

Planet-planet scattering events can leave an observable trace of a planet's migration history in the form of orbital misalignment with respect to the the stellar spin axis, which is measurable from spectroscopic timeseries taken during transit. We present high-resolution spectroscopic transits observed with ESPRESSO of the close-in super-Earth π Men c. The system also contains an outer giant planet on a wide, eccentric orbit, recently found to be inclined with respect to the inner planetary orbit. These characteristics are reminiscent of past dynamical interactions. We successfully retrieve the planet-occulted light during transit and find evidence that the orbit of π Men c is moderately misaligned with the stellar spin axis with λ = -24.0 4.1 ( = 26.9 +5.8\,-4.7). This is consistent with the super-Earth π Men c having followed a high-eccentricity migration followed by tidal circularisation, and hints that super-Earths can form at large distances from their star. We also detect clear signatures of solar-like oscillations within our ESPRESSO radial velocity timeseries, where we reach a radial velocity precision of 20 cm/s. We model the oscillations using Gaussian processes and retrieve a frequency of maximum oscillation, max = 2771+65-60 μHz. These oscillations makes it challenging to detect the Rossiter-McLaughlin effect using traditional methods. We are, however, successful using the reloaded Rossiter-McLaughlin approach. Finally, in an appendix we also present updated physical parameters and ephemerides for π Men c from a Gaussian process transit analysis of the full TESS Cycle 1 data.