NASA’s Juno Mission Captures the Colorful and Chaotic Clouds of Jupiter

Posted by Guy Pirro 11/11/2024 06:37PM

Since it arrived at Jupiter in 2016, NASA’s Juno spacecraft has been probing beneath the dense, forbidding clouds encircling the giant planet – the first orbiter to peer so closely. It seeks answers to questions about the origin and evolution of Jupiter, our Solar System, and giant planets across the cosmos. During a recent close encounter with Jupiter, NASA’s Juno spacecraft captured this color-enhanced view of the giant planet’s northern hemisphere. It provides a detailed view of chaotic clouds and cyclonic storms in an area known to scientists as a folded filamentary region. In these regions, the zonal jets that create the familiar banded patterns in Jupiter’s clouds break down, leading to turbulent patterns and cloud structures that rapidly evolve over the course of only a few days. Gerald Eichstädt and Thomas Thomopoulos made this image using raw data from the JunoCam instrument, applying digital processing techniques to enhance color and clarity. (Image Credit: NASA , JPL, SwRI, MSSS, Image processing by Gerald Eichstadt and Thomas Thomopoulos, CC BY 3.0)

NASA’s Juno Mission Captures the Colorful and Chaotic Clouds of Jupiter

In 2021, NASA authorized a mission extension for its Juno spacecraft exploring Jupiter. The agency’s most distant planetary orbiter will now continue its investigation of the solar system’s largest planet until the spacecraft’s end of life. This expansion tasks Juno with becoming an explorer of the full Jovian system – Jupiter and its rings and moons – with multiple rendezvous planned for three of Jupiter’s most intriguing Galilean moons: Ganymede, Europa, and Io.

“Since its first orbit in 2016, Juno has delivered one revelation after another about the inner workings of this massive gas giant,” said principal investigator Scott Bolton of the Southwest Research Institute (SWRI) in San Antonio, Texas. “With the extended mission, we will answer fundamental questions that arose during Juno’s prime mission while reaching beyond the planet to explore Jupiter’s ring system and Galilean satellites.”

Proposed in 2003 and launched in 2011, Juno arrived at Jupiter on July 4, 2016. The prime mission was completed in July 2021. The extended mission involved at least 42 additional orbits, including close passes of Jupiter’s north polar cyclones; flybys of Ganymede, Europa, and Io, as well as the first extensive exploration of the faint rings encircling the planet.

“By extending the science goals of this important orbiting observatory, the Juno team will start tackling a breadth of science historically required of flagships,” said Lori Glaze, planetary science division director at NASA Headquarters in Washington. “This represents an efficient and innovative advance for NASA’s solar system exploration strategy.”

The data Juno collected has contributed to the goals of the next generation of missions to the Jovian system – NASA’s Europa Clipper and the ESA (European Space Agency) JUpiter ICy moons Explorer (JUICE) mission. Juno’s investigation of Jupiter’s volcanic moon Io addresses many science goals identified by the National Academy of Sciences (NAS) for a future Io explorer mission.

The extended mission’s science campaigns have expanded on discoveries Juno has already made about Jupiter’s interior structure, internal magnetic field, atmosphere (including polar cyclones, deep atmosphere, and aurora), and magnetosphere.

Juno has flown through the Europa and Io tori (i.e., ring-shaped clouds of ions) on multiple occasions, characterizing the radiation environment near these satellites to prepare the Europa Clipper and JUICE missions for optimizing observation strategies and planning, science priorities, and mission design. The extended mission also added planetary geology and ring dynamics to Juno’s extensive list of science investigations.

With this extension, Juno has, in effect, become its own follow-on mission according to Steve Levin, Juno project scientist at NASA’s Jet Propulsion Laboratory (JPL) in Southern California. “Close-up observations of the pole, radio occultations (i.e., a remote sensing technique to measure properties of a planetary atmosphere or ring systems) satellite flybys, and focused magnetic field studies combine to make a new mission -- the next logical step in our exploration of the Jovian system.”

The natural evolution of Juno’s orbit around the gas giant provides the wealth of new science opportunities that the extended mission capitalizes on. Every science pass sends the solar-powered spacecraft zooming low over Jupiter’s cloud tops, collecting data from a unique vantage point no other spacecraft has enjoyed.

The point during each orbit where Juno comes closest to the planet is called perijove (or PJ). Over the course of the mission, Juno’s perijoves have migrated northward, dramatically improving resolution over the northern hemisphere. The design of the extended mission takes advantage of the continued northward migration of these perijoves to sharpen its view of the multiple cyclones encircling the north pole while incorporating ring and Galilean moon flybys.

“The mission designers have done an amazing job crafting an extended mission that conserves the mission’s single most valuable onboard resource – fuel,” said Ed Hirst, the Juno project manager at JPL. “Gravity assists from multiple satellite flybys steer our spacecraft through the Jovian system while providing a wealth of science opportunities.” The satellite flybys also reduce Juno’s orbital period, which increases the total number of science orbits that can be obtained.”

The satellite encounters began with a low-altitude flyby of Ganymede on June 7, 2021 (PJ34), which reduces the orbital period from about 53 days to 43 days. That flyby set up a close flyby of Europa on Sept. 29, 2022 (PJ45), reducing the orbital period further to 38 days. A pair of close Io flybys, on Dec. 30, 2023 (PJ57) and Feb. 3, 2024 (PJ58), combined to reduce the orbital period to 33 days.

JPL, a division of Caltech in Pasadena, California, manages the Juno mission for the principal investigator, Scott J. Bolton, of the Southwest Research Institute in San Antonio. Juno is part of NASA’s New Frontiers Program, which is managed at NASA’s Marshall Space Flight Center in Huntsville, Alabama, for the agency’s Science Mission Directorate in Washington. Lockheed Martin Space in Denver built and operates the spacecraft.

At the time the raw image above was taken, the Juno spacecraft was about 18,000 miles (29,000 kilometers) above Jupiter’s cloud tops, at a latitude of about 68 degrees north of the equator.

JunoCam's raw images are available for the public to peruse and process into image products at:

https://missionjuno.swri.edu/junocam/processing

More information about NASA citizen science can be found at:

https://science.nasa.gov/citizenscience

For more information:

https://www.missionjuno.swri.edu/news/nasas-juno-mission-captures-the-colorful-and-chaotic-clouds

https://www.missionjuno.swri.edu/news/nasa-s-juno-mission-expands-into-the-future

https://science.nasa.gov/mission/juno

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