A tension between dust and gas radii: the role of substructures and external photoevaporation in protoplanetary disks

TL;DR

This study investigates how substructures and external photoevaporation influence gas and dust disk sizes in protoplanetary disks, revealing challenges in simultaneously reproducing observed gas and dust size ratios.

Contribution

It introduces a population synthesis model considering substructures and external photoevaporation to explain observed disk size ratios, highlighting fine-tuning issues.

Findings

Substructures help reduce the discrepancy in gas-to-dust size ratios.

External photoevaporation alone does not fully resolve size ratio discrepancies.

Only specific initial conditions can reproduce observed gas and dust sizes simultaneously.

Abstract

Protoplanetary disk substructures are thought to play a crucial role in disk evolution and planet formation. Population studies of disks large-sample size surveys show that substructures, and their rapid formation, are needed to reproduce the observed spectral indices. Moreover, they enable the simultaneous reproduction of the observed spectral index and size-luminosity distributions. This study aims to investigate the necessity of substructures and predict their characteristics to reproduce gas-to-dust size ratios observed in the Lupus star-forming region. We performed a population synthesis study of gas and dust evolution in disks using a two-population model (two-pop-py) and the DustPy code. We considered the effects of viscous evolution, dust growth, fragmentation, transport, and external photoevaporation. The simulated population distributions were obtained by post-processing the resulting disk profiles of surface density, maximum grain size, and disk temperature. Although substructures help reduce the discrepancy between simulated and observed disk gas-to-dust size ratios; even when accounting for external photoevaporation, they do not fully resolve it. Only specific initial conditions in disks undergoing viscous evolution with external photoevaporation can reproduce the observations, highlighting a fine-tuning problem. While substructured disks reproduce dust size and spectral index, they tend to overestimate gas radii. The results ultimately highlight the main challenge of simultaneously reproducing gas and dust sizes. One possible explanation is that the outermost substructure is linked to the disk truncation radius, which determines the gas radius, or that substructures are frequent enough to always be near the gas outer radius.