Multi-band Spectral and Astrometric Characterization of the HIP 99770 b Planet with SCExAO/CHARIS and Gaia

We present and analyze follow-up, higher resolution (R ∼ 70) H and K band integral field spectroscopy of the superjovian exoplanet HIP 99770 b with SCExAO/CHARIS. Our new data recover the companion at a high SNR in both bandpasses and more than double the astrometric baseline for its orbital motion. Jointly modeling HIP 99770 b’s position and the star’s astrometry from Hipparcos and Gaia yields orbital parameters consistent with those from the discovery paper, albeit with smaller errors, and a slight preference for a smaller semimajor axis (∼15.7–15.8 au) and a larger eccentricity (∼0.28–0.29), disfavoring a circular orbit. We revise its dynamical mass slightly downwards to 15.0− 4.4 + 4.5 M _Jup for a flat prior and 13.1− 5.2 + 4.8 M _Jup for a more standard log-uniform mass prior, where the inclusion of its relative radial-velocity measurement is primarily responsible for these changes. We find consistent results for HIP 99770 b’s dynamical mass, including recent VLTI/GRAVITY astrometry, albeit with a slightly smaller, better constrained eccentricity of e ∼ 0.22− 0.13 + 0.10. HIP 99770 b is a ∼1300 K object at the L/T transition with a gravity intermediate between that of the HR 8799 planets and older, more massive field brown dwarfs with similar temperatures but with hints of equilibrium chemistry. HIP 99770 b is particularly well suited for spectroscopic follow-up with Roman Coronagraph Instrument during the technology demonstration phase at 730 nm to further constrain its metallicity and chemistry; JWST thermal infrared observations could likewise explore the planet’s carbon chemistry, metallicity, and clouds.