Gravitational instabilities in a protosolar-like disc I: dynamics and chemistry

TL;DR

This study uses 3D radiative hydrodynamics to explore how gravitational instabilities in a young, protosolar-like disc influence its physical and chemical evolution, revealing permanent chemical changes and potential observational tracers.

Contribution

It provides the first detailed 3D simulation of chemical and physical evolution in a gravitationally unstable, low-mass protoplanetary disc, highlighting the impact of shocks on chemistry.

Findings

Shocks enhance desorption rates, altering gas-phase abundances.

Certain species like CN trace spiral structures in the disc.

Shock heating causes permanent changes in HNO, CN, and NH3 abundances.

Abstract

To date, most simulations of the chemistry in protoplanetary discs have used 1+1D or 2D axisymmetric $\alpha$-disc models to determine chemical compositions within young systems. This assumption is inappropriate for non-axisymmetric, gravitationally unstable discs, which may be a significant stage in early protoplanetary disc evolution. Using 3D radiative hydrodynamics, we have modelled the physical and chemical evolution of a 0.17 M$_{\odot}$ self-gravitating disc over a period of 2000 yr. The 0.8 M$_{\odot}$ central protostar is likely to evolve into a solar-like star, and hence this Class 0 or early Class I young stellar object may be analogous to our early Solar System. Shocks driven by gravitational instabilities enhance the desorption rates, which dominate the changes in gas-phase fractional abundances for most species. We find that at the end of the simulation, a number of species distinctly trace the spiral structure of our relatively low-mass disc, particularly CN. We compare our simulation to that of a more massive disc, and conclude that mass differences between gravitationally unstable discs may not have a strong impact on the chemical composition. We find that over the duration of our simulation, successive shock heating has a permanent effect on the abundances of HNO, CN and NH$_3$, which may have significant implications for both simulations and observations. We also find that HCO$^+$ may be a useful tracer of disc mass. We conclude that gravitational instabilities induced in lower mass discs can significantly, and permanently, affect the chemical evolution, and that observations with high-resolution instruments such as ALMA offer a promising means of characterising gravitational instabilities in protosolar discs.