Confirmation and characterization of the protoplanet HD100546 b - Direct evidence for gas giant planet formation at 50 au

Abstract

We present the first multi-wavelength, high-contrast imaging study confirming the protoplanet embedded in the disk around the Herbig Ae/Be star HD100546. The object is detected at L' ( 3.8\,μ m) and M' ( 4.8\,μ m), but not at Ks ( 2.1\,μ m), and the emission consists of a point source component surrounded by spatially resolved emission. For the point source component we derive apparent magnitudes of L'=13.920.10 mag, M'=13.330.16 mag, and Ks>15.430.11 mag (3σ limit), and a separation and position angle of (0.4570.014)" and (8.41.4), and (0.4720.014)" and (9.21.4) in L' and M', respectively. We demonstrate that the object is co-moving with HD100546 and can reject any (sub-)stellar fore-/background object. Fitting a single temperature blackbody to the observed fluxes of the point source component yields an effective temperature of Teff=932+193-202 K and a radius for the emitting area of R=6.9+2.7-2.9 R Jupiter. The best-fit luminosity is L=(2.3+0.6-0.4)· 10-4\,L Sun. We quantitatively compare our findings with predictions from evolutionary and atmospheric models for young, gas giant planets, discuss the possible existence of a warm, circumplanetary disk, and note that the de-projected physical separation from the host star of (532) au poses a challenge standard planet formation theories. Considering the suspected existence of an additional planet orbiting at 13--14 au, HD100546 appears to be an unprecedented laboratory to study the formation of multiple gas giant planets empirically.