Using EUV driven external photoevaporation to test viscous evolution of protoplanetary discs

TL;DR

This paper proposes a new observational method to distinguish between viscous and MHD wind-driven evolution of protoplanetary discs by analyzing the correlation between mass accretion rates and external photoevaporative mass-loss rates.

Contribution

It demonstrates that a near one-to-one correlation between accretion and photoevaporative mass-loss rates indicates viscous evolution, providing a robust diagnostic tool for disc evolution mechanisms.

Findings

Viscous discs show a strong correlation between $ m ext{M}_{ m acc}$ and $ m ext{M}_{ m pe}$.

MHD wind-driven discs do not exhibit this correlation.

The diagnostic can be applied with current observational data, despite some limitations.

Abstract

Protoplanetary discs are thought to evolve either through angular momentum transport driven by viscous processes or through angular momentum removal induced by magnetohydrodynamic (MHD) winds. One proposed method to distinguish between these two evolutionary pathways is by comparing mass accretion rates and disc sizes, but observational constraints complicate this distinction. In this study, we investigate how extreme ultraviolet (EUV) external photoevaporation affects the evolution of protoplanetary discs, particularly in environments such as the Orion Nebula Cluster. Using a combination of analytical derivations and 1D numerical simulations, we explore the impact of externally induced mass-loss on disc structure and accretion dynamics. We demonstrate that, in the viscous scenario, there exists a clear, near one-to-one correlation between the mass-loss rate due to external photoevaporative outflows and the mass accretion rate onto the central star. In contrast, MHD wind-driven discs do not exhibit such trend, leading to a distinct evolutionary path. External photoevaporative mass-loss rates and mass accretion rates can both be accurately measured for a population of discs, without a strong model dependence. Thus, our findings provide a robust observational test to distinguish between viscous and MHD wind-driven disc evolution, offering a new approach to constraining angular momentum transport mechanisms in protoplanetary discs. Applying this diagnostic observationally requires joint measurements of $\dot{M}_{\rm acc}$ and $\dot{M}_{\rm pe}$ for the same objects, which are currently scarce in bright HII regions due to contamination and sensitivity limitations.