Journal
REMOTE SENSING
Volume 14, Issue 6, Pages -Publisher
MDPI
DOI: 10.3390/rs14061518
Keywords
giant planets; atmospheres; dynamics; atmospheres; structure; adaptive optics
Categories
Funding
- Space Telescope Science Institute [GO13937, GO16057, GO16084, GO16454]
- NASA Solar System Observing Grant [80NSSC21K0292]
- European Research Council Consolidator Grant (under the European Union's Horizon 2020 research and innovation programme) at the University of Leicester [723890]
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Observations of the giant planets have been limited to infrequent robotic spacecraft missions, but the Hubble Space Telescope and ground-based telescopes with adaptive optics have provided high-resolution imaging and long-term monitoring. These observations have allowed for in-depth studies of the clouds, winds, and atmospheric structure, as well as comparisons between different planets and regions. Temporal variations in various aspects of the atmospheres have been measured, and future facilities will further enhance our understanding of atmospheric evolution on these planets.
Each of the giant planets, Jupiter, Saturn, Uranus, and Neptune, has been observed by at least one robotic spacecraft mission. However, these missions are infrequent; Uranus and Neptune have only had a single flyby by Voyager 2. The Hubble Space Telescope, particularly the Wide Field Camera 3 (WFC3) and Advanced Camera for Surveys (ACS) instruments, and large ground-based telescopes with adaptive optics systems have enabled high-spatial-resolution imaging at a higher cadence, and over a longer time, than can be achieved with targeted missions to these worlds. These facilities offer a powerful combination of high spatial resolution, often <0.05, and broad wavelength coverage, from the ultraviolet through the near infrared, resulting in compelling studies of the clouds, winds, and atmospheric vertical structure. This coverage allows comparisons of atmospheric properties between the planets, as well as in different regions across each planet. Temporal variations in winds, cloud structure, and color over timescales of days to years have been measured for all four planets. With several decades of data already obtained, we can now begin to investigate seasonal influences on dynamics and aerosol properties, despite orbital periods ranging from 12 to 165 years. Future facilities will enable even greater spatial resolution and, combined with our existing long record of data, will continue to advance our understanding of atmospheric evolution on the giant planets.
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