Accretion Properties of PDS 70b with MUSE

Abstract

We report a new evaluation of the accretion properties of PDS~70b obtained with VLT/MUSE. The main difference from previous studies in Haffert et al. (2019) and Aoyama & Ikoma (2019) is in the mass accretion rate. Simultaneous multiple line observations, such as Hα and Hβ, can better constrain the physical properties of an accreting planet. While we clearly detected Hα emissions from PDS~70b, no Hβ emissions were detected. We estimate the line flux of Hβ with a 3-σ upper limit to be 2.3~×~10-16~erg~s-1~cm-2. The flux ratio F Hβ/F Hα for PDS~70b is <~0.28. Numerical investigations by Aoyama et al. (2018) suggest that F Hβ/F Hα should be close to unity if the extinction is negligible. We attribute the reduction of the flux ratio to the extinction, and estimate the extinction of Hα (A Hα) for PDS~70b to be >~2.0~mag using the interstellar extinction value. %The expected A Hα value in the gap of the protoplanetary disk at the PDS~70b location is 2.4~mag, which is consistent with the estimated extinction. By combining with the Hα linewidth and the dereddening line luminosity of Hα, %we derive the PDS~70b dynamical mass and mass accretion rate to be 12~~3~M Jup and ~5~×~10-7~M Jup~yr-1, respectively. we derive the PDS~70b mass accretion rate to be ~5~×~10-7~M Jup~yr-1. The PDS~70b mass accretion rate is an order of magnitude larger than that of PDS~70. We found that the filling factor f f (the fractional area of the planetary surface emitting Hα) is 0.01, which is similar to the typical stellar value. The small value of f f indicates that the Hα emitting areas are localized at the surface of PDS~70b.