External photoevaporation of protoplanetary discs in Cygnus OB2: linking discs to star formation dynamical history

Abstract

Many stars form in regions of enhanced stellar density, wherein the influence of stellar neighbours can have a strong influence on a protoplanetary disc (PPD) population. In particular, far ultraviolet (FUV) flux from massive stars drives thermal winds from the outer edge of PPDs, accelerating disc destruction. In this work, we present a novel technique for constraining the dynamical history of a star forming environment using PPD properties in a strongly FUV irradiated environment. Applying recent models for FUV induced mass loss rates to the PPD population of Cygnus OB2, we constrain how long ago primordial gas was expelled from the region; 0.5 Myr ago if the Shakura & Sunyaev α-viscosity parameter is α = 10-2 (corresponding to a viscous timescale of τvisc ≈ 0.5 Myr for a disc of scale radius 40 au around a 1\, M star). This value of α is effectively an upper limit, since it assumes efficient extinction of FUV photons throughout the embedded phase. With this gas expulsion timescale we are able to produce a full dynamical model that fits kinematic and morphological data as well as disc fractions. We suggest Cygnus OB2 was originally composed of distinct massive clumps or filaments, each with a stellar mass 104 \, M. Finally we predict that in regions of efficient FUV induced mass loss, disc mass Mdisc as a function of stellar host mass mstar follows a power law with Mdisc mstarβ, where β 2.7 (depending on disc initial conditions and FUV exposure). This is steeper than observed correlations in regions of moderate FUV flux (1 < β <1.9), and offers a promising diagnostic to establish the influence of external photoevaporation in a given region.