A new pathway to SO$_2$: Revealing the NUV driven sulfur chemistry in hot gas giants

TL;DR

This study explores the photochemical pathways leading to SO$_2$ formation in hot gas giant atmospheres, emphasizing the role of stellar UV flux and revealing multiple formation mechanisms affecting observational interpretations.

Contribution

It identifies two distinct SO$_2$ formation pathways driven by different stellar UV wavelengths and highlights the importance of stellar flux ratios in SO$_2$ observability.

Findings

SO$_2$ forms via two pathways initiated by different UV wavelengths.

Stellar flux in 200-350 nm range influences SO$_2$ detectability.

Diverse chemical pathways impact interpretation of SO$_2$ observations.

Abstract

Context. Photochemistry is a key process driving planetary atmospheres away from local thermodynamic equilibrium. Recent observations of the H$_2$ dominated atmospheres of hot gas giants have detected SO$_2$ as one of the major products of this process. Aims. We investigate which chemical pathways lead to the formation of SO$_2$ in an atmosphere, and we investigate which part of the flux from the host star is necessary to initiate SO$_2$ production. Methods. We use the publicly available S-N-C-H-O photochemical network in the VULCAN chemical kinetics code to compute the disequilibrium chemistry of an exoplanetary atmosphere. Results. We find that there are two distinct chemical pathways that lead to the formation of SO$_2$. The formation of SO$_2$ at higher pressures is initiated by stellar flux >200 nm, whereas the formation of SO$_2$ at lower pressures is initiated by stellar flux <200 nm. In deeper layers of the atmosphere, OH is provided by the hydrogen abstraction of H$_2$O, and sulfur is provided by the photodissociation of SH and S$_2$, which leads to a positive feedback cycle that liberates sulfur from the stable H$_2$S molecule. In higher layers of the atmosphere, OH is provided by the photodissociation of H$_2$O, and sulfur can be liberated from H$_2$S by either photodissociation of SH and S$_2$, or by the hydrogen abstraction of SH. Conclusions. We conclude that the stellar flux in the 200-350 nm wavelength range as well as the ratio of NUV/UV radiation are important parameters determining the observability of SO$_2$. In addition we find that there is a diversity of chemical pathways to the formation of SO$_2$. This is crucial for the interpretation of SO$_2$ detections and derived elemental abundance ratios and overall metallicities.