Contributions of Jupiter's Deep‐Reaching Surface Winds to Magnetic Field Structure and Secular Variation
Persistent URL: http://resolver.sub.uni-goettingen.de/purl?gldocs-11858/11786
![]() |
View/
|
NASA's Juno mission delivered gravity data of exceptional quality. They indicate that the zonal winds, which rule the dynamics of Jupiter's cloud deck, must slow down significantly beyond a depth of about 3,000 km. Since the underlying inversion is highly non‐unique additional constraints on the flow properties at depth are required. These could potentially be provided by the magnetic field and its Secular Variation (SV) over time. However, the role of these zonal winds in Jupiter's magnetic field dynamics is little understood. Here we use numerical simulations to explore the impact of the zonal winds on the dynamo field produced at depth. We find that the main effect is an attenuation of the non‐axisymmetric field, which can be quantified by a modified magnetic Reynolds number Rm that combines flow amplitude and electrical conductivity profile. Values below Rm = 3 are required to retain a pronounced non‐axisymmetric feature like the Great Blue Spot (GBS), which seems characteristic for Jupiter's magnetic field. This allows for winds reaching as deep as 3,400 km. A SV pattern similar to the observation can only be found in some of our models. Its amplitude reflects the degree of cancellation between advection and diffusion rather than the zonal wind velocity at any depth. It is therefore not straightforward to make inferences on the deep structure of cloud‐level winds based on Jupiter's SV.
We study the magnetic field variations caused by Jupiter's deep‐reaching surface winds for various flow and electrical conductivity models
Zonal winds reaching deeper than 3,400 km would yield a very axisymmetric surface field and are thus unrealistic
It seems questionable that Jupiter's secular variation carries any useful information on the zonal winds