An Aligned Very-Low-Mass Star Orbiting an M dwarf and Obliquity Patterns Across Giant Planets, Brown Dwarfs, and Binary Stars

Abstract

Stellar obliquity serves as a key diagnostic for tracing the dynamical evolution of bound systems-from giant planets and brown dwarfs to stellar binaries-revealing whether these diverse populations share analogous histories. Here, we report the first obliquity measurement for a double M dwarf system, determined via the Rossiter-McLaughlin effect. The spin axis of the primary star, TOI-5375 (M=0.620.02\,M), is well aligned with the orbit of its low-mass stellar companion (Mc=84.81.5\, MJ, P=1.72\,days) with a projected obliquity of λ=-13.5-13.8+12.4\, and a true 3D obliquity of =37.5-13.4+10.6\,. The result indicates that the system either formed with a primordially aligned configuration or has undergone tidal realignment. We further investigate obliquity patterns across giant planets, brown dwarfs and binary stars. It turns out that a few obliquity trends observed in giant planets also tentatively exhibit in the latter two higher-mass populations: 1) well-aligned orbits are preferentially found around cooler host stars (T eff≤ 6250\,K); 2) wide-orbit (a/R≥ 10) companions are predominantly aligned; 3) no significant correlation shows up between obliquity and orbital eccentricity in any of the companion classes. By modeling |λ| with a two-component Gaussian distribution, we find that the low-|λ| components of binary stars and brown dwarfs are more concentrated near zero than giant planets while the high-|λ| components of brown dwarfs and binaries remain unclear due to the small sample size.