The 20-year Hubble study of Uranus provides valuable data to help you understand the atmospheric dynamics of this distant ice giant. This serves as a proxy for studying the deformation of similar sizes and compositions.
The image sequence shows changes in Uranus over the past four years when Hubble’s STIS instrument observed Uranus over 20 years. Over that period, astronomers saw Uranus season as the Antarctic region (left) entered winter shadows, and the Arctic region (right) brightened, and began to become more direct view as summer approached the north. The top row of visible light shows how Uranus’ colours look to the human eye, as can be seen by even amateur telescopes. In the second line, false-colored images of the planet are assembled from visible and near-infrared light observations. The color and brightness correspond to the amount of methane and aerosol. Both of these quantities were indistinguishable before STI first targeted Uranus in 2002. Generally, the green area has less methane than the blue area, and the red area does not show methane. The red area is in the limbs, where the stratosphere of Uranus is almost completely free of methane. The two bottom rows show the latitudinal structures of aerosols and methane, inferred from those visible from 1,000 different wavelengths (colors) to near-infrared. In the third row, bright areas show cloudy conditions, while dark areas show clearer conditions. In the fourth row, the bright areas show depleted methane, and the dark areas show the total amount of methane. At mid- and low-latitude latitudes, aerosol and methane depletion has a unique latitude structure that has changed little over 20 years of observation. However, in polar regions, aerosol and methane depletion behave very differently. In the third row, aerosols near the Arctic show a dramatic increase, becoming very dark in the early days of the Northern Spring and very bright in recent years. It appears that aerosols also disappear in their left limbs when solar radiation disappears. This is evidence that solar radiation alters aerosol haze in Uranus’s atmosphere. On the other hand, methane depletion appears to remain very high in both polar regions throughout the observation period. Image credits: NASA/ESA/Erich Karkoschka, LPL.
Uranus is a giant ice planet about four times the diameter of Earth.
It has a hydrogen and helium feel and has a bit of methane that gives it a blue tint.
Uranus lies to its side and rotates, its magnetic field is biased – it tilts at the center 60 degrees from its axis.
When Voyager 2 passed Uranus in 1986, it provided a close-up snapshot of the planet facing sideways. What it saw resembled a bland blue-green billiard ball.
In comparison, Hubble recorded the story of 20 years of seasonal changes from 2002 to 2022.
During that period, it was used by a team of astronomers led by Dr. Erich Karkoschka of the University of Arizona and Dr. Larry Slomovsky and Dr. Pat Free of the University of Wisconsin. Hubble Space Telescope Imaging Spectrometer (stis) Draw an accurate picture of Uranus’ atmosphere structure.
Researchers observed Uranus four times in 20 years: 2002, 2012, 2015, and 2022.
They found that unlike gas giants Saturn and Jupiter, methane was not evenly distributed on Uranus.
Instead, it is heavily depleted near the pole. This depletion remained relatively constant for 20 years.
However, the structure of aerosols and hazes changes dramatically, and brightens significantly in the Arctic region as the planet approaches the northern summer solstice in 2030.
Uranus takes Earth age just over 84 years to complete the single orbit of the Sun.
Therefore, for over 20 years, the team has seen the spring almost north to make the Northern Pole shine directly in 2030, before shining the equator of Uranus.
“Hubble’s observations suggest a complex atmospheric circulation pattern for Uranus during this period,” the scientists said.
“The data most sensitive to methane distribution shows polar inundation and upwelling in other regions.”
Source: www.sci.news