Juno Reveals Deep 3d Structure Massive9 min readReading Time: 6 minutes
The Juno spacecraft has revealed a deep 3D structure of Jupiter’s massive storm, the Great Red Spot. The results were published in the journal Nature on July 12, 2018.
The Great Red Spot is a giant storm that has been raging on Jupiter for centuries. It is about twice the size of Earth and has been monitored by spacecraft for over 40 years. The new study used data from the Juno spacecraft to create a three-dimensional map of the storm.
The map revealed that the Great Red Spot is not a simple, round storm. It is actually a complex storm that is three layers deep. The top layer is a round core, the middle layer is a doughnut-shaped vortex, and the bottom layer is a turbulent atmosphere.
The study also found that the Great Red Spot is not static. It is constantly changing, with new features appearing and disappearing.
The Juno spacecraft will continue to study the Great Red Spot and other features of Jupiter’s atmosphere. The data will help us learn more about the dynamics of Jupiter’s atmosphere and how it has changed over time.
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What did Juno discover deep inside Jupiter?
On July 4, 2016, the Juno spacecraft entered into a polar orbit around Jupiter, and began to send back unprecedented amounts of data about the gas giant. The Juno mission is the result of a collaboration between NASA and the European Space Agency (ESA), and is the first space probe to orbit Jupiter since the Galileo probe in 1995.
One of the primary goals of the Juno mission is to understand the origins and evolution of Jupiter. In order to do this, Juno has been equipped with a suite of instruments that allow it to probe deep into Jupiter’s atmosphere.
One of Juno’s first major discoveries was that Jupiter’s atmosphere is much more complex than scientists had thought. Juno was able to identify ammonia clouds, water vapor clouds, and ammonia storms. Additionally, Juno was able to determine the depth of Jupiter’s atmosphere, and found that it extends more than 1,000 kilometers below the planet’s surface.
Juno also discovered that Jupiter’s magnetic field is much stronger than scientists had thought. The probe was able to measure the magnetic field at different depths, and found that it is strongest near the planet’s poles. This discovery helps to explain why the auroras near Jupiter’s poles are so much brighter than auroras elsewhere in the solar system.
Finally, Juno was able to determine that Jupiter’s core is made of rock and ice. The probe was able to measure the seismic waves that are generated by Jupiter’s core, and determined that the core is about the size of Earth. This discovery confirms that Jupiter is a gas giant, and that it does not have a solid core like Earth does.
The Juno mission has already yielded a wealth of information about Jupiter, and it is likely that even more discoveries will be made in the coming months and years. Juno is providing scientists with a much better understanding of Jupiter’s origins and evolution, and is helping to unlock the secrets of the largest planet in the solar system.
How is Juno able to look deep into Jupiter’s interior?
Since launching on August 5, 2011, Juno has been on a seven year journey to orbit Jupiter. On July 4, 2016, the spacecraft finally arrived at its destination and began its mission to study the giant planet in great detail. One of the things Juno is able to do is look deep into Jupiter’s interior, to learn more about the planet’s structure and how it formed.
To do this, Juno uses a technique called gravitational mapping. This involves measuring the gravitational field of a planet as it moves around it. By doing this, scientists can create a map of the planet’s interior. This is possible because different parts of a planet have different densities, which affects the gravitational field.
Juno is able to look deep into Jupiter’s interior because it is in a polar orbit around the planet. This means that it travels over the poles of Jupiter, which gives it a good view of the planet’s interior. It also means that Juno is able to travel very close to Jupiter, which allows it to measure the planet’s gravitational field more accurately.
The data that Juno collects will help scientists learn more about Jupiter’s structure and how it formed. Juno will also be able to tell us more about the planet’s atmosphere, including the role of the Great Red Spot.
What did the Juno probe discover?
In July of 2016, the Juno probe made a historic rendezvous with the planet Jupiter. After a five-year journey through space, Juno became the first spacecraft to enter into orbit around Jupiter. The probe has since been sending back data about the gas giant, revealing new insights into the planet’s formation and evolution.
One of the most significant discoveries made by Juno is that Jupiter’s core is much smaller than previously thought. Previous missions to Jupiter had suggested that the core was about the size of Earth. However, Juno’s data indicates that the core is only about 10% the size of Earth. This suggests that Jupiter formed differently than other planets in the solar system, and that its atmosphere is much more volatile than previously believed.
Juno has also revealed that Jupiter’s magnetic field is much stronger than previously thought. The probe’s measurements indicate that the magnetic field is about 20 times stronger than Earth’s. This may be due to the presence of a large quantity of metallic hydrogen in Jupiter’s atmosphere.
The Juno probe is also providing new insights into the dynamics of Jupiter’s atmosphere. The probe’s measurements have shown that the atmosphere is much more turbulent than previously thought. This could be due to the fact that Jupiter is constantly rotating, giving rise to strong winds that can reach speeds of up to 400 miles per hour.
Overall, the Juno probe has provided scientists with a wealth of new information about Jupiter. The probe’s data is helping to rewrite our understanding of the planet’s formation and evolution, and is giving us a better understanding of the dynamics of its atmosphere.
What type of space probe is Juno?
Juno is a space probe that was designed and built by the Jet Propulsion Laboratory to study Jupiter. Juno is the second spacecraft to orbit Jupiter, after the Galileo orbiter. It was launched on August 5, 2011, from Cape Canaveral Air Force Station on a five-year journey to Jupiter. After a one-way trip of 5.5 years, Juno arrived in orbit around Jupiter on July 4, 2016.
Juno is a solar-powered spacecraft. It is three meters wide and two meters high, and has three solar arrays that generate about 1,600 watts of power. Juno is also fitted with a titanium armored vault to protect its electronics from the high levels of radiation near Jupiter.
Juno’s science instruments include a microwave radiometer to measure Jupiter’s atmospheric temperature, a gravimeter to measure the planet’s gravitational field, a magnetometer to measure the magnitude and direction of the planet’s magnetic field, and a photometer to measure the amount of sunlight reflected by Jupiter’s clouds.
Juno’s closest approach to Jupiter will be about 2,500 kilometers above the planet’s cloud tops. It will orbit Jupiter 37 times over the course of 20 months, traveling from pole to pole and scanning the planet’s atmosphere in a search for clues about its origins and evolution.
Where is Juno probe now?
After a five-year journey, Juno spacecraft entered Jupiter’s orbit on July 4, 2016. But where is Juno probe now?
JunoCam, the probe’s camera, has been capturing some stunning images of Jupiter and its moons. The probe has also been collecting data about the gas giant’s atmosphere and interior.
Recently, however, Juno has been in a holding pattern as mission controllers wait for the right moment to fire its engines and put it into its final orbit.
According to NASA, the maneuver will take place in early October. Once in its final orbit, Juno will be able to complete its primary mission, which is to study Jupiter’s interior.
The probe will also continue to send back valuable data about the gas giant, its atmosphere, and its moons.
So far, Juno has sent back some amazing images of Jupiter, including a view of the gas giant’s north pole that is unlike anything we’ve seen before.
Thanks to Juno, we’re getting a much better understanding of Jupiter and its role in the solar system. Stay tuned for more amazing discoveries from this probe!
What did Juno accomplish?
What did Juno accomplish? Juno was a spacecraft that was sent to Jupiter in order to study the planet and its moons. The spacecraft was launched on August 5, 2011, and it arrived at Jupiter on July 4, 2016.
Juno’s main objectives were to study Jupiter’s atmosphere, interior, and magnetosphere. The spacecraft also studied Jupiter’s moons Europa, Ganymede, and Callisto.
The results of Juno’s mission have given us a better understanding of Jupiter’s formation and evolution. Juno also confirmed that Jupiter’s core is made of rock, and it found that the planet’s atmosphere is much less dense than previously thought.
Juno’s mission was a success, and it provided us with valuable information about Jupiter and its moons.
Has Juno crashed into Jupiter?
Since its launch in 2011, the Juno spacecraft has been on a long journey to Jupiter. This week, there were concerns that Juno had crashed into the planet, but NASA has now confirmed that the spacecraft is still in orbit around Jupiter.
Juno was launched on August 5, 2011, and it took five years for the spacecraft to reach Jupiter. On July 4, 2016, Juno made its first close approach to the planet, and it began a long orbit around Jupiter.
This week, there were concerns that Juno had crashed into Jupiter, but NASA has now confirmed that the spacecraft is still in orbit around Jupiter. The concerns arose after amateur astronomers noticed that two of Juno’s nine solar panels were not illuminated, which could have been a sign that the spacecraft had crashed into Jupiter.
However, NASA has now confirmed that Juno is still in orbit around Jupiter, and the spacecraft is in good condition. Juno’s mission is to study Jupiter’s atmosphere, interior, and magnetosphere, and the spacecraft is expected to continue to orbit Jupiter for the next five years.