From Misaligned Sub-Saturns to Aligned Brown Dwarfs: The Highest M p/M* Systems Exhibit Low Obliquities, Even around Hot Stars
Abstract
We present a pattern emerging from stellar obliquity measurements in single-star systems: planets with high planet-to-star mass ratios (M p/M*> 2×10-3) -- such as super-Jupiters, brown dwarf companions, and M-dwarfs hosting Jupiter-like planets -- tend to be aligned, even around hot stars. This alignment represents a 3.7σ deviation from the obliquity distribution observed in systems with lower mass ratios (M p/M*< 2×10-3), which predominantly include Jupiters and sub-Saturns. The only known outlier system, XO-3, exhibits misalignment confirmed via our newly collected Rossiter-McLaughlin effect measurement (λ=41.8+2.1-2.0 degrees). However, the relatively large Gaia Renormalized Unit Weight Error (RUWE) of XO-3 suggests that it may harbor an undetected binary companion, potentially contributing to its misalignment. Given that tidal realignment mechanisms are weak for hot stars, the observed alignment in high M p/M* systems is likely primordial rather than resulting from tidal interactions. One possible explanation is that only dynamically isolated planets can continue accreting gas and evolve into super-Jupiters while maintaining their primordial alignment. Conversely, planets formed in compact configurations may be unable to grow beyond the gap-opening mass, for which our work suggests an empirical boundary M p/M*= 2×10-3, identified between aligned high M p/M* systems and misaligned low M p/M* systems, with dynamical instabilities contributing to the diverse spin-orbit misalignments observed in the latter.
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