A pole-to-pole map of hydrocarbons in Saturn's upper stratosphere and mesosphere

TL;DR

This study provides the first pole-to-pole 2D map of hydrocarbons in Saturn's upper atmosphere, revealing seasonal and meridional variations, and highlights the importance of ion chemistry in modeling these distributions.

Contribution

It presents a comprehensive 2D mapping of hydrocarbons in Saturn's upper atmosphere and assesses the role of ion chemistry in photochemical models, based on Cassini UVIS and CIRS data.

Findings

Meridional trend in homopause pressure from 0.05 to 5 microbar.

Higher hydrocarbon abundances in the summer hemisphere.

Ion chemistry improves model agreement for benzene distribution.

Abstract

We analyze data from the final two years of the Cassini mission to retrieve the distributions of methane, ethane, acetylene, ethylene, and benzene in Saturn's upper stratosphere and mesosphere from stellar occultations observed by the Ultraviolet Imaging Spectrograph (UVIS), spanning pole-to-pole. These observations represent the first 2D snapshot with latitude and depth of Saturn's photochemical production region around northern summer solstice. Using UVIS occultations and CIRS limb scans, we derive temperature-pressure profiles and atmospheric structure models for each occultation latitude. W detect a strong meridional trend in the homopause pressure level, which ranges from approximately 0.05 microbar around the subsolar point to around 5 microbar at the poles, implying much weaker mixing at the poles than near the subsolar point. This trend could be explained by upwelling at low latitudes and downwelling at high latitudes, requiring vertical wind speeds under 2 cm/s. Photochemical product distributions follow this trend and also show a clear seasonal trend at pressures between 0.01 and 10 microbar, with higher abundances in the summer hemisphere. We compare the observed distributions with results from 1D seasonal photochemical models, with and without ion chemistry, to explore the impact of ion chemistry. We find that ion chemistry is particularly important for matching the observed C6H6 distribution, while its impact on other species is less pronounced. The best agreement between the models and the observations is obtained in the summer hemisphere. Disagreements between model and observations in the winter hemisphere and auroral region may be due to the lack of transport by global circulation and auroral electron and ion precipitation in our photochemical models. Finally, we compare C2H2 profiles from UVIS occultations with CIRS limb scans, finding good agreement where they overlap.