Accurate characterization of the stellar and orbital parameters of the exoplanetary system WASP-33 b from orbital dynamics

Abstract

By using the most recently published Doppler tomography measurements and accurate theoretical modeling of the oblateness-driven orbital precessions, we tightly constrain some of the physical and orbital parameters of the planetary system hosted by the fast rotating star WASP-33. In particular, the measurements of the orbital inclination i p to the plane of the sky and of the sky-projected spin-orbit misalignment λ at two epochs about six years apart allowed for the determination of the longitude of the ascending node and of the orbital inclination I to the apparent equatorial plane at the same epochs. As a consequence, average rates of change exp,~ I exp of this two orbital elements, accurate to a ≈ 10-2~ deg~ yr-1 level, were calculated as well. By comparing them to general theoretical expressions J2,~ IJ2 for their precessions induced by an oblate star whose symmetry axis is arbitrarily oriented, we were able to determine the angle i between the line of sight the star's spin S and its first even zonal harmonic J2 obtaining i = 142+10-11~ deg,~J2 = (2.1+0.8-0.5)× 10-4. As a by-product, the angle between S and the orbital angular momentum L is as large as about ≈ 100 deg (2008 = 99+5-4~ deg,~2014 = 103+5-4~ deg), and changes at a rate = 0.7+1.5-1.6~ deg~ yr-1. The predicted general relativistic Lense-Thirring precessions, or the order of ≈ 10-3~ deg~ yr-1, are, at present, about one order of magnitude below the measurability threshold.