The water abundance in Jupiter’s equatorial zone

Cheng Li ,Sidharth Misra ,S J Bolton ,T Guillot ,Shannon Brown ,S M Levin ,S Gulkis ,Glenn S Orton ,Liming Li ,Hunter Waite ,J K Arballo ,M A Janssen ,Amadeo Bellotti ,Jonathan I Lunine ,Amorée Hodges ,Andrew P Ingersoll ,M Allison ,Virgil Adumitroaie ,Fabiano Oyafuso ,S K Atreya ,Paul G Steffes ,Daniel Santos-Costa ,Zhimeng Zhang

doi:10.1038/s41550-020-1009-3

Abstract

Oxygen is the most common element after hydrogen and helium in Jupiter's atmosphere, and may have been the primary condensable (as water ice) in the protoplanetary disk. Prior to the Juno mission, in situ measurements of Jupiter's water abundance were obtained from the Galileo Probe, which dropped into a meteorologically anomalous site. The findings of the Galileo Probe were inconclusive because the concentration of water was still increasing when the probe died. Here, we initially report on the water abundance in the equatorial region, from 0 to 4 degrees north latitude, based on 1.25 to 22 GHz data from Juno Microwave radiometer probing approximately 0.7 to 30 bars pressure. Because Juno discovered the deep atmosphere to be surprisingly variable as a function of latitude, it remains to confirm whether the equatorial abundance represents Jupiter's global water abundance. The water abundance at the equatorial region is inferred to be $2.5_{-1.6}^{+2.2}\times10^3$ ppm, or $2.7_{-1.7}^{+2.4}$ times the protosolar oxygen elemental ratio to H (1$\sigma$ uncertainties). If reflective of the global water abundance, the result suggests that the planetesimals formed Jupiter are unlikely to be water-rich clathrate hydrates.

Highlights

We analyze the first eight of Juno’s orbits around Jupiter, with each perijove probing a cross-section of Jupiter's atmosphere at a different longitude and spanning latitudes from the north pole to the south pole
Compared to the simulated brightness temperatures of a reference adiabatic atmosphere, the observed nadir brightness temperatures are warmer than expected at all channels everywhere except within a narrow latitudinal range of a few degrees located near the equator
The consistency between multiple perijoves confirms that the uniformity of ammonia in the Equatorial Zone (EZ) is independent of longitude

Summary

Introduction

We analyze the first eight of Juno’s orbits around Jupiter (designated as PJ1, PJ3, PJ4, PJ5, PJ6, PJ7, PJ8 and PJ9), with each perijove probing a cross-section of Jupiter's atmosphere at a different longitude and spanning latitudes from the north pole to the south pole (no MWR data were obtained during PJ2). Despite an approximate 45-degree separation in longitude between each of the PJ1 to PJ9 orbits, the observed nadir brightness temperatures show extremely good consistency, especially at latitudes near the equator, at mid-latitudes, and at pressure levels larger than 10 bars.

Results

Conclusion