Observations and numerical modelling of a convective disturbance in a large-scale cyclone in Jupiter's South Temperate Belt

TL;DR

This paper combines observational data and numerical modeling to analyze a convective disturbance in Jupiter's South Temperate Belt, revealing water moist convection as the storm's driving mechanism and its interaction with large-scale atmospheric features.

Contribution

It provides the first integrated observational and numerical study of a Jupiter storm complex, highlighting water moist convection's role and the interaction with large-scale cyclonic structures.

Findings

Water moist convection drives the initial storms.

Storms are confined within a cyclonic region near Oval BA.

Numerical simulations successfully reproduce observed phenomena.

Abstract

Moist convective storms in Jupiter develop frequently and can trigger atmospheric activity of different scales, from localized storms to planetary-scale disturbances including convective activity confined inside a larger meteorological system. In February 2018 a series of convective storms erupted in Jupiter's South Temperate Belt (STB) (planetocentric latitudes from -23$^{\circ}$ to -29.5$^{\circ}$). This occurred inside an elongated cyclonic region known popularly as the STB Ghost, close to the large anticyclone Oval BA, resulting in the clouds from the storms being confined to the cyclone. The initial storms lasted only a few days but they generated abundant enduring turbulence. They also produced dark features, possibly partially devoid of clouds, that circulated around the cyclone over the first week. The subsequent activity developed over months and resulted in two main structures, one of them closely interacting with Oval BA and the other one being expelled to the west. Here we present a study of this meteorological activity based on daily observations provided by the amateur community, complemented by observations obtained from PlanetCam UPV/EHU at Calar Alto Observatory, the Hubble Space Telescope and by JunoCam on the Juno spacecraft. We also perform numerical simulations with the EPIC General Circulation Model to reproduce the phenomenology observed. The successful simulations require a complex interplay between the Ghost, the convective eruptions and Oval BA, and they demonstrate that water moist convection was the source of the initial storms. A simple scale comparison with other moist convective storms that can be observed in the planet in visible and methane absorption band images strongly suggests that most of these storms are powered by water condensation instead of ammonia.