Magnetometer (Juno)


Magnetometer is the name of an instrument suite on the Juno orbiter for planet Jupiter. The MAG instrument includes both the Fluxgate Magnetometer and Advanced Stellar Compass instruments. There two sets of MAG instrument suites, and they are both positioned on the far end of three solar panel array booms. Each MAG instrument suite observes the same swath of Jupiter, and by having two sets of instruments, determining what signal is from the planet and what is from spacecraft is supported. Avoiding signals from the spacecraft is another reason MAG is placed at the end of the solar panel boom, about 10 m and 12 m away from the central body of the Juno spacecraft.
The MAG instrument is designed to detect the magnetic field of Jupiter, which is one of the largest structures in the Solar System. If one could see Jupiter's magnetic field from Earth, it would appear five times larger than the full moon in the sky despite being nearly 1700 times farther away. Jupiter's internal magnetic field prevents the solar wind, a stream of ionized particles emitted by the Sun, from interacting directly with its atmosphere, and instead diverts it away from the planet, effectively creating a cavity in the solar wind flow, called a magnetosphere, composed of a plasma different from that of the solar wind.
Mission goals:
Jupiter has the strongest and biggest magnetic fields known to exist in the solar system. Studying these fields is one of the goals of the Juno mission, and in particular the task rests on the Magnetometer instruments. MAG measures the field about 60 times per second, and records the direction and strength of the field. MAG collected data on Earth during its 9 October 2013 flyby en route to Jupiter.
Another advantage to studying Jupiter's field is that on Earth, crustal magnetism interferes with measurements of the field generated deep in the core, partially shielding it from measurements. On Earth the field is generated by spinning liquid iron, whereas on Jupiter is generated by hydrogen. Jupiter is mostly hydrogen, and as it compresses from gravity it turns conductive in a special form. However, it is not known if farther in where it should compress to metallic hydrogen, if that is conducting electricity also. That is one of the questions Juno may answer. In addition to studying Jupiter, the MAG also returned data on the Earth's magnetosphere.
The MAG instrument was delivered to Lockheed Martin Space Systems' facility in Denver, Colorado, USA for integration into the Juno spacecraft by NASA's Goddard Spaceflight Center in October 2010. MAG was overall designed and built at the NASA Goddard Space Flight Center in Greenbelt, Maryland. The Advanced Stellar Compass was built and contributed by the Technical University of Denmark.
The FGM and ASC were turned on in late August after Junos launch on 5 August 2011. The ASC allow a very precise determination of the magnetometers orientation in space. They are star trackers that take a picture of the sky, then compare those images to a catalog of star maps to allow the orientation to be determined.
The fluxgate magnetometer is similar to previous instruments flown on spacecraft like the Voyagers, Magsat, Active Magnetospheric Particle Tracer Explorers, Mars Global Surveyor, etc. This style of FGM uses twin wide-range, triaxial flux gate sensors mounted far away from the spacecraft body in which the magnetic flux is periodically switched. Two FGM's are used so the separate readings can be combined to make the magnetic field calculation. MAG has two vector fluxgate magnetometers supported by advanced star trackers. The star tracking system allows the orientation of the FGM to be calculated and determined more accurately enhancing the usefulness of the FGM readings.
Jupiter's magnetic fields were previously observed in the 1970s with Pioneer 10 and Pioneer 11, and Voyager 1 and Voyager 2. Magnetometers related to Juno include ones on MAVEN, MGS, Voyager, AMPTE, GIOTTO, CLUSTER, Lunar Prospector, MESSENGER, STEREO, and Van Allen Probes.
At one point, JPL was working on including a Scalar Helium Magnetometer on Juno, in addition to the FGM and ASC suite.

Results and papers

In 2017, a paper called The analysis of initial Juno magnetometer data using a sparse magnetic field representation included analysis of data from the Juno magnetometer which passed 10 times closer that previous probings. The nature of Jupiter's magnetic field was examined combining the latest results from MAG with a mathematical model called VIP4 spherical harmonic model for the magnetic field of Jupiter.