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Characterizing outer companions to hot Jupiters plays a crucial role in deciphering their origins. We present the discovery of a long-period giant planet, HD 118203 c (m₂=11. 9^+0. 69-₀. ₆₃\ M₉, a₂=5. 36^+0. 09-₀. ₁₀ AU, e₂=0. 26^+0. 03-₀. ₀₂) exterior to previously known close-in eccentric hot Jupiter HD 118203 b (P₁=6. 135\ days, m₁=2. 140. 12\ M₉, r₁=1. 140. 029\ R₉, e₁=0. 310. 007) based on twenty-year radial velocity observations. Using Rossiter-McLaughlin (RM) observations from the Keck Planet Finder (KPF), we measured a low sky-projected obliquity ₁=-11^. 7^+7. 6-₁₀ for HD 118203 b and detected stellar oscillations in the host star, confirming its evolved status. Combining the RM observation with the stellar inclination measurement, we constrained the true obliquity of HD 118203 b as ₁<33^. 5\ (2), indicating the orbit normal of the hot Jupiter nearly aligned with the stellar spin axis. Furthermore, by combining radial velocities and Hipparcos-Gaia astrometric acceleration, we constrained the line-of-sight mutual inclination between the hot Jupiter and the outer planet to be 9^. 8^+16. 2-₉. ₃ at 2 level. HD 118203 is the first hot Jupiter system where both the true obliquity of the hot Jupiter and the mutual inclination between inner and outer planets have been determined. Our results are consistent with a system-wide alignment, with low mutual inclinations between the outer giant planet, the inner hot Jupiter, and the host star. This alignment, along with the moderate eccentricity of HD 118203 c, implies that the system may have undergone coplanar high-eccentricity tidal migration. Under this framework, our dynamical analysis suggests an initial semi-major axis of 0. 3 to 3. 2 AU for the proto-hot Jupiter.
Zhang et al. (Wed,) studied this question.