Seasonal Variability of Saturn's Tropospheric Temperatures, Winds and Para-H$_2$ from Cassini Far-IR Spectroscopy

TL;DR

This study uses Cassini's far-IR spectra to analyze Saturn's tropospheric temperatures, winds, and para-H$_2$ over a third of a Saturnian year, revealing seasonal and localized variations with implications for climate models.

Contribution

It provides the first near-continuous record of Saturn's tropospheric temperature and para-H$_2$ distribution over a seasonal cycle, highlighting the impact of seasonal lag and localized heating.

Findings

Temperatures become almost symmetric about the equator by 2014.

Localized tropospheric heating varies with season, declining in autumn and growing in spring.

Para-H$_2$ distribution shows subtle seasonal changes influenced by advection and subsidence.

Abstract

Far-IR 16-1000 $\mu$m spectra of Saturn's hydrogen-helium continuum measured by Cassini's Composite Infrared Spectrometer (CIRS) are inverted to construct a near-continuous record of upper tropospheric (70-700 mbar) temperatures and para-H$_2$ fraction as a function of latitude, pressure and time for a third of a Saturnian year (2004-2014, from northern winter to northern spring). The thermal field reveals evidence of reversing summertime asymmetries superimposed onto the belt/zone structure. The temperature structure that is almost symmetric about the equator by 2014, with seasonal lag times that increase with depth and are qualitatively consistent with radiative climate models. Localised heating of the tropospheric hazes (100-250 mbar) create a distinct perturbation to the temperature profile that shifts in magnitude and location, declining in the autumn hemisphere and growing in the spring. Changes in the para-H$_2$ ($f_p$) distribution are subtle, with a 0.02-0.03 rise over the spring hemisphere (200-500 mbar) perturbed by (i) low-$f_p$ air advected by both the springtime storm of 2010 and equatorial upwelling; and (ii) subsidence of high-$f_p$ air at northern high latitudes, responsible for a developing north-south asymmetry in $f_p$. Conversely, the shifting asymmetry in the para-H$_2$ disequilibrium primarily reflects the changing temperature structure (and the equilibrium distribution of $f_p$), rather than actual changes in $f_p$ induced by chemical conversion or transport. CIRS results interpolated to the same point in the seasonal cycle as re-analysed Voyager-1 observations show qualitative consistency, with the exception of the tropical tropopause near the equatorial zones and belts, where downward propagation of a cool temperature anomaly associated with Saturn's stratospheric oscillation could potentially perturb tropopause temperatures, para-H$_2$ and winds. [ABRIDGED]