The Spin-Orbit Misalignment of TOI-1842b: The First Measurement of the Rossiter-McLaughlin Effect for a Warm Sub-Saturn around a Massive Star

Abstract: The mechanisms responsible for generating spin-orbit misalignments in exoplanetary systems are still not fully understood. It is unclear whether these misalignments are related to the migration of hot Jupiters or are a consequence of general star and planet formation processes. One promising method to address this question is to constrain the distribution of spin-orbit angle measurements for a broader range of planets beyond hot Jupiters. In this work, we present the sky-projected obliquity ($\lambda=-68.1_{-14.7}^{+21.2} \,^{\circ}$) for the warm sub-Saturn TOI-1842b, obtained through a measurement of the Rossiter-McLaughlin effect using WIYN/NEID. Using the projected obliquity, the stellar rotation period obtained from the TESS light curve, and the projected rotation velocity from spectral analysis, we infer the 3D spin-orbit angle ($\psi$) to be $\psi=73.3^{+16.3}_{-12.9} \,^{\circ}$. As the first spin-orbit angle determination made for a sub-Saturn-mass planet around a massive ($M_{\rm *}=1.45 \,{\rm M_\odot}$) star, our result presents an opportunity to examine the orbital geometries for new regimes of planetary systems. When combined with archival measurements, our observations of TOI-1842b support the hypothesis that the previously established prevalence of misaligned systems around hot, massive stars may be driven by planet-planet dynamical interactions. In massive stellar systems, multiple gas giants are more likely to form and can then dynamically interact with each other to excite spin-orbit misalignments.