NASA’s Juno captured this view of Jupiter during the
mission’s 54th close flyby of the giant planet on Sept. 7. The image was made
with raw data from the JunoCam instrument that was processed to enhance details
in cloud features and colors.
Image data: NASA/JPL-Caltech/SwRI/MSSS Image
processing by Tanya Oleksuik CC BY NC SA 3.0
The finding offers deeper insights into the long-debated internal structure
of the gas giant.
Gravity data collected by NASA’s
Juno mission indicates Jupiter’s atmospheric winds penetrate the planet in a
cylindrical manner, parallel to its spin axis. A paper on the findings was
recently published in the journal Nature
Astronomy.
The violent nature of Jupiter’s
roiling atmosphere has long been a source of fascination for astronomers and
planetary scientists, and Juno has had a ringside seat to the goings-on since it entered orbit in 2016. During each of the spacecraft’s 55 to date, a
suite of science instruments has peered below Jupiter’s turbulent cloud deck to
uncover how the gas giant works from the inside out.
One way the Juno mission learns
about the planet’s interior is via radio science. Using NASA’s
Deep Space Network antennas, scientists track the spacecraft’s radio signal as Juno
flies past Jupiter at speeds near 130,000 mph (209,000 kph), measuring tiny
changes in its velocity – as small as 0.01 millimeter per second. Those changes
are caused by variations in the planet’s gravity field, and by measuring them,
the mission can essentially see into Jupiter’s atmosphere.
Such measurements have led to
numerous discoveries, including the existence of a dilute core deep within
Jupiter and the depth of the planet’s zones and belts, which extend from the cloud tops down approximately
1,860 miles (3,000 kilometers).
Doing the Math
To determine the location and cylindrical nature of the winds, the study’s authors applied a mathematical technique that models gravitational variations and surface elevations of rocky planets like Earth. At Jupiter, the technique can be used to accurately map winds at depth. Using the high-precision Juno data, the authors were able to generate a four-fold increase in the resolution over previous models created with data from NASA’s trailblazing Jovian explorers Voyager and Galileo.
This illustration depicts findings that Jupiter’s atmospheric winds penetrate the planet in a cylindrical manner and parallel to its spin axis. The most dominant jet recorded by NASA’s Juno is shown in the cutout: The jet is at 21 degrees north latitude at cloud level, but 1,800 miles (3,000 kilometers) below that, it’s at 13 degrees north latitude. NASA/JPL-Caltech/SSI/SWRI/MSSS/ASI/ INAF/JIRAM/Björn Jónsson CC BY 3.0
“We applied a constraining technique developed for sparse data sets on
terrestrial planets to process the Juno data,” said Ryan Park, a Juno scientist
and lead of the mission’s gravity science investigation from NASA’s Jet
Propulsion Laboratory in Southern California. “This is the first time such a
technique has been applied to an outer planet.”
The measurements of the gravity
field matched a two-decade-old model that determined Jupiter’s powerful
east-west zonal flows extend from the cloud-level white and red zones and belts
inward. But the measurements also revealed that rather than extending in every
direction like a radiating sphere, the zonal flows go inward, cylindrically,
and are oriented along the direction of Jupiter’s rotation axis. How Jupiter’s
deep atmospheric winds are structured has been in debated since the 1970s, and
the Juno mission has now settled the debate.
Follow the
Juno spacecraft with Eyes on the Solar System
“All 40 gravity coefficients measured by Juno matched our previous
calculations of what we expect the gravity field to be if the winds penetrate
inward on cylinders,” said Yohai Kaspi of the Weizmann Institute of Science in
Israel, the study’s lead author and a Juno co-investigator. “When we realized
all 40 numbers exactly match our calculations, it felt like winning the
lottery.”
Along with bettering the current
understanding of Jupiter’s internal structure and origin, the new gravity model
application could be used to gain more insight into other planetary
atmospheres.
Juno is currently in an extended
mission. Along with flybys of Jupiter, the solar-powered spacecraft has
completed a series of flybys of the planet’s icy moons Ganymede and Europa and
is in the midst of several close flybys of Io. The Dec. 30 flyby of Io will be
the closest to date, coming within about 930 miles (1,500 kilometers) of its
volcano-festooned surface.
“As Juno’s journey progresses,
we’re achieving scientific outcomes that truly define a new Jupiter and that
likely are relevant for all giant planets, both within our solar system and
beyond,” said Scott Bolton, the principal investigator of the Juno mission at
the Southwest Research Institute in San Antonio. “The resolution of the newly
determined gravity field is remarkably similar to the accuracy we estimated 20
years ago. It is great to see such agreement between our prediction and our
results.”
More About the Mission
NASA’s Jet Propulsion Laboratory, 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.
More information about Juno is
available at:
Source: NASA’s Juno Finds Jupiter’s Winds Penetrate in Cylindrical Layers - NASA
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