The Molecular Composition of Shadowed Protosolar Disk Midplanes beyond the Water Snowline

TL;DR

This study investigates how shadowed regions beyond the water snowline in protosolar-like disks influence the chemical composition of ices and gases, revealing enhanced organic and hydrocarbon ices and potential tracers for shadowed regions.

Contribution

It provides detailed predictions of molecular abundance variations and identifies N/O ratios and N$_{2}$H$^{+}$ emission as tracers of shadowed disk regions, advancing understanding of disk chemistry.

Findings

Shadowed regions have 5-10 times more ices of organics and hydrocarbons.

Hydrogenation of CO ice dominates complex organic molecule formation.

N/O ratio variations serve as effective tracers of shadowed regions.

Abstract

The disk midplane temperature is potentially affected by the dust traps/rings. The dust depletion beyond the water snowline will cast a shadow. In this study, we adopt a detailed gas-grain chemical reaction network, and investigate the radial gas and ice abundance distributions of dominant carbon-, oxygen-, and nitrogen-bearing molecules in disks with shadow structures beyond the water snowline around a protosolar-like star. In shadowed disks, the dust grains at around $3-8$ au are predicted to have more than around $5-10$ times amounts of ices of organic molecules such as H$_{2}$CO, CH$_{3}$OH, and NH$_{2}$CHO, saturated hydrocarbon ices such as CH$_{4}$ and C$_{2}$H$_{6}$, in addition to H$_{2}$O, CO, CO$_{2}$, NH$_{3}$, N$_{2}$, and HCN ices, compared with those in non-shadowed disks. In the shadowed regions, we find that hydrogenation (especially of CO ice) is the dominant formation mechanism of complex organic molecules. The gas-phase N/O ratios show much larger spatial variations than the gas-phase C/O ratios, thus the N/O ratio is predicted to be a useful tracer of the shadowed region. N$_{2}$H$^{+}$ line emission is a potential tracer of the shadowed region. We conclude that a shadowed region allows the recondensation of key volatiles onto dust grains, provides a region of chemical enrichment of ices that is much closer to the star than within a non-shadowed disk, and may explain to some degree the trapping of O$_{2}$ ice in dust grains that formed comet 67P/Churyumov-Gerasimenko. We discuss that, if formed in a shadowed disk, Jupiter does not need to have migrated vast distances.