Chemical Processes in Protoplanetary Disks

TL;DR

This study presents a detailed physical and chemical model of a protoplanetary disk around a T Tauri star, exploring chemical processes and molecular tracers with implications for observations.

Contribution

It introduces a combined high-resolution physical and chemical disk model incorporating gas-grain interactions and desorption mechanisms, highlighting the impact of photodesorption and X-ray desorption.

Findings

Photodesorption significantly increases gas-phase molecule abundances.

X-ray desorption homogenizes molecular abundances across the disk.

Grain-surface chemistry boosts complex organic molecule levels.

Abstract

We have developed a high resolution combined physical and chemical model of a protoplanetary disk surrounding a typical T Tauri star. Our aims were to use our model to calculate the chemical structure of disks on small scales (sub-milli-arcsecond in the inner disk for objects at the distance of Taurus, ~ 140 pc) to investigate the various chemical processes thought to be important in disks and to determine potential molecular tracers of each process. Our gas-phase network was extracted from the UMIST Database for Astrochemistry to which we added gas-grain interactions including freeze out and thermal and non-thermal desorption (cosmic-ray induced desorption, photodesorption and X-ray desorption) and a grain-surface network. We find that cosmic-ray induced desorption has the least effect on our disk chemical structure while photodesorption has a significant effect, enhancing the abundances of most gas-phase molecules throughout the disk and affecting the abundances and distribution of HCN, CN and CS, in particular. In the outer disk, we also see enhancements in the abundances of H2O and CO2. X-ray desorption is a potentially powerful mechanism in disks, acting to homogenise the fractional abundances of gas-phase species across the depth and increasing the column densities of most molecules although there remain significant uncertainties in the rates adopted for this process. The addition of grain-surface chemistry enhances the fractional abundances of several small complex organic molecules including CH3OH, HCOOCH3 and CH3OCH3 to potentially observable values (i.e. a fractional abundance of >~ 1.0E-11).