Collaborative work by amateur and professional astronomers has helped to resolve a long-standing misunderstanding about the composition of Jupiter’s clouds. Instead of being formed of ammonia ice — the conventional view — it now appears they are likely to be composed of ammonium hydrosulphide mixed with smog.
The findings have been published in the Journal of Geophysical Research — Planets.
The new discovery was triggered by amateur astronomer, Dr Steven Hill, based in Colorado. Recently, he demonstrated that the abundance of ammonia and cloud-top pressure in Jupiter’s atmosphere could be mapped using commercially-available telescopes and a few specially coloured filters. Remarkably, these initial results not only showed that the abundance of ammonia in Jupiter’s atmosphere could be mapped by amateur astronomers, they also showed that the clouds reside too deeply within Jupiter’s warm atmosphere to be consistent with the clouds being ammonia ice.
In this new study, Professor Patrick Irwin from the University of Oxford’s Department of Physics applied Dr Steven Hill’s analytical method to observations of Jupiter made with the Multi Unit Spectroscopic Explorer (MUSE) instrument at the European Southern Observatory’s Very Large Telescope (VLT) in Chile. MUSE uses the power of spectroscopy, where Jupiter’s gases create telltale fingerprints in visible light at different wavelengths, to map the ammonia and cloud heights in the gas giant’s atmosphere.
By simulating how the light interacts with the gases and clouds in a computer model, Professor Irwin and his team found that the primary clouds of Jupiter — the ones we can see when looking through backyard telescopes — had to be much deeper than previously thought, in a region of higher pressure and higher temperature. Too warm, in fact, for the condensation of ammonia. Instead, those clouds have to be made of something different: ammonium hydrosulphide.
Previous analyses of MUSE observations had hinted at a similar result. However, since these analyses were made with sophisticated, extremely complex methods that can only be conducted by a few groups around the world, this result was difficult to corroborate. In this new work, Irwin’s team found that Dr Hill’s method of simply comparing the brightnesses in adjacent, narrow coloured filters gave the identical results. And since this new method is much faster and very simple, it is far easier to verify. Hence, the team conclude that the clouds of Jupiter really are at deeper pressures than the expected ammonia clouds at 700 mb and so cannot be composed of pure ammonia ice.
Professor Irwin said: “I am astonished that such a simple method is able to probe so deep in the atmosphere and demonstrate so clearly that the main clouds cannot be pure ammonia ice! These results show that an innovative amateur using a modern camera and special filters can open a new window on Jupiter’s atmosphere and contribute to understanding the nature of Jupiter’s long-mysterious clouds and how the atmosphere circulates.”
Dr Steven Hill, who has a PhD in Astrophysics from the University of Colorado and works in space weather forecasting, said, “I always like to push my observations to see what physical measurements I can make with modest, commercial equipment. The hope is that I can find new ways for amateurs to make useful contributions to professional work. But I certainly did not expect an outcome as productive as this project has been!”
The ammonia maps resulting from this simple analytical technique can be determined at a fraction of the computational cost of more sophisticated methods. This means they could be used by citizen scientists to track ammonia and cloud-top pressure variations across features in Jupiter’s atmosphere including Jupiter’s bands, small storms, and large vortices like the Great Red Spot.
John Rogers (British Astronomical Association), one of the study’s co-authors adds: “A special advantage of this technique is that it could be used frequently by amateurs to link visible weather changes on Jupiter to ammonia variations, which could be important ingredients in the weather.”
So why doesn’t ammonia condense to form a thick cloud? Photochemistry (chemical reactions induced by sunlight) is very active in Jupiter’s atmosphere and Professor Irwin and his colleagues suggest that in regions where moist, ammonia-rich air is raised upwards, the ammonia is destroyed and/or mixed with photochemical products faster than ammonia ice can form. Thus, the main cloud deck may actually be composed of ammonium hydrosulphide mixed with photochemical, smoggy products, which produce the red and brown colours seen in Jupiter images.
In small regions, where convection is especially strong, the updrafts may be fast enough to form fresh ammonia ice, and such regions have occasionally been seen by spacecraft such as NASA’s Galileo, and more recently by NASA’s Juno, where a few small high white clouds have been seen, casting their shadows down on the main cloud deck below.
Professor Irwin and his team also applied the method to VLT/MUSE observations of Saturn and have found similar agreement in the derived ammonia maps with other studies, including one determined from James Webb Space Telescope observations. Similarly, they have found the main level of reflection to be well below the expected ammonia condensation level, suggesting that similar photochemical processes are occurring in Saturn’s atmosphere.