Exploring Jupiter's Magnetic Field
NASA's Juno spacecraft will make its long anticipated arrival at Jupiter on July 4. Coming face-to-face with the gas giant, Juno will begin to unravel some of the greatest mysteries surrounding our solar system's largest planet, including the origin of its massive magnetosphere.
Magnetospheres are the result of a collision between a planet's
intrinsic magnetic field and the supersonic solar wind. Jupiter's
magnetosphere -- the volume carved out in the solar wind where the
planet's magnetic field dominates --extends up to nearly 2 million miles
(3 million kilometers). If it were visible in the night sky, Jupiter's
magnetosphere would appear to be about the same size as Earth's full
moon. By studying Jupiter's magnetosphere, scientists will gain a better
understanding about how Jupiter's magnetic field is generated.
They
also hope to determine whether the planet has a solid core, which will
tell us how Jupiter formed during the earliest days of our solar system.
In order to look inside the planet, the science team equipped Juno
with a pair of magnetometers. The magnetometers, which were designed and
built by an in-house team of scientists and engineers at NASA's Goddard
Space Flight Center in Greenbelt, Maryland, will allow scientists to
map Jupiter's magnetic field with high accuracy and observe variations
in the field over time.
"The best way to think of a magnetometer is like a compass," said
Jack Connerney, deputy principal investigator and head of the
magnetometer team at Goddard. "Compasses record the direction of a
magnetic field. But magnetometers expand on that capability and record
both the direction and magnitude of the magnetic field."
The magnetometer sensors rest on a boom attached to one of the solar
arrays, placing them about 40 feet (12 meters) from the body of the
spacecraft. This helps ensure that the rest of the spacecraft does not
interfere with the magnetometer.
However, the sensor orientation changes in time with the mechanical
distortion of the solar array and boom resulting from the extremely cold
temperatures of deep space. This distortion would limit the accuracy of
the magnetometer measurements if not measured.
To ensure that the magnetometers retain their high accuracy, the team
paired the instruments with a set of four cameras. These cameras
measure the distortion of the magnetometer sensors in reference to the
stars to determine their orientation.
"This is our first opportunity to do very precise, high-accuracy
mapping of the magnetic field of another planet," Connerney said. "We
are going to be able to explore the entire three-dimensional space
around Jupiter, wrapping Jupiter in a dense net of magnetic field
observations completely covering the sphere."
One of the mysteries the team hopes to answer is how Jupiter's
magnetic field is generated. Scientists expect to find similarities
between Jupiter's magnetic field and that of Earth.
Magnetic fields are produced by what are known as dynamos --
convective motion of electrically conducting fluid inside planets. As a
planet rotates, the electrically susceptible liquid swirls around and
drives electric currents, inducing a magnetic field. Earth's magnetic
field is generated by liquid iron in the planet's core.
"But with Jupiter, we don't know what material is producing the
planet's magnetic field," said Jared Espley, Juno program scientist for
NASA Headquarters, Washington. "What material is present and how deep
down it lies is one of the questions Juno is designed to answer."
The observations made by Juno's magnetometers will also add to our
understanding of Earth's dynamo, the source of our planet's magnetic
field, which lies deep beneath a magnetized layer of rocks and iron.
Imagine Earth's crust strewn with refrigerator magnets as you try to
peer beneath the surface to observe the dynamo. The magnetization of
Earth's crust will skew your measurements of the magnetic field.
"One of the reasons that the Juno mission is so exciting is because
we can map Jupiter's magnetic field without having to look through the
crustal magnetic fields, which behave like a jumble of refrigerator
magnets," Connerney said. "Jupiter has a gaseous envelope about it made
of hydrogen and helium that gives us a clear and unobstructed view of
the dynamo."
These observations will also add to the general understanding of how dynamos generate magnetic fields, including here on Earth.
"Any time we understand anything about another planet, we can take
that knowledge and apply it to our knowledge about our own planet,"
Espley said. "We'll be looking at Juno's observations in a big-picture
perspective."
NASA's Jet Propulsion Laboratory in Pasadena, California, manages the
Juno mission for the principal investigator, Scott Bolton, of 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 NASA's Science Mission Directorate. Lockheed
Martin Space Systems, Denver, built the spacecraft.
For more information about the Juno mission, visit: www.nasa.gov/juno
News Media Contact
DC Agle
Jet Propulsion Laboratory, Pasadena, Calif.
818-393-9011
agle@jpl.nasa.gov
Source: JPL-Caltech/News