THE LEECH EXOPLANET IMAGING SURVEY: CHARACTERIZATION OF THE COLDEST DIRECTLY IMAGED EXOPLANET, GJ 504 b, AND EVIDENCE FOR SUPERSTELLAR METALLICITY

As gas giant planets and brown dwarfs radiate away the residual heat from their formation, they cool through a spectral type transition from L to T, which encompasses the dissipation of cloud opacity and the appearance of strong methane absorption. While there are hundreds of known T-type brown dwarfs, the first generation of directly imaged exoplanets were all L. type. Recently, Kuzuhara et al. announced the discovery of GJ 504 b, the first T dwarf exoplanet. GJ 504 b provides a unique opportunity to study the atmosphere of a new type of exoplanet with a similar to 500 K temperature that bridges the gap between the first directly imaged planets (similar to 1000 K) and our own solar system's Jupiter (similar to 130 K). We observed GJ 504 b in three narrow L-band filters (3.71, 3.88, and 4.00 mu m), spanning the red end of the broad methane fundamental absorption feature (3.3 mu m) as part of the LBTI Exozodi Exoplanet Common Hunt (LEECH) exoplanet imaging survey. By comparing our new photometry and literature photometry with a grid of custom model atmospheres, we were able to fit GJ 504 b's unusual spectral energy distribution for the first time. We find that GJ 504 b is well. fit by models with the following parameters: T-eff - 544 +/- 10 K, g < 600 m s(-2), [M/H] - 0.60 +/- 0.12, cloud opacity parameter of f(sed) - 2-5, R = 0.96 +/- 0.07 R-Jup, and log(L) = -6.13 +/- 0.03 L-circle dot, implying a hot start mass of 3-30M(jup) for a conservative age range of 0.1-6.5 Gyr. Of particular interest, our model fits suggest that GJ 504 b has a superstellar metallicity. Since planet formation can create objects with nonstellar metallicities, while binary star formation cannot, this result suggests that GJ 504 b formed like a planet, not like a binary companion.