蜜桃影像 scientist鈥檚 research answers big question about our system鈥檚 largest planet
Rod Boyce
907-474-7185
May 3, 2024
New discoveries about Jupiter could lead to a better understanding of Earth鈥檚 own space environment and influence a long-running scientific debate about the solar system鈥檚 largest planet.
鈥淏y exploring a larger space such as Jupiter, we can better understand the fundamental physics governing Earth鈥檚 magnetosphere and thereby improve our space weather forecasting,鈥 said Peter Delamere, a professor at the 蜜桃影像 Geophysical Institute and the 蜜桃影像 College of Natural Science and Mathematics.
鈥淲e are one big space weather event from losing communication satellites, our power grid assets, or both,鈥 he said.
Space weather refers to disturbances in the Earth's magnetosphere caused by interactions between the solar wind and the Earth's magnetic field. These are generally associated with solar storms and the sun鈥檚 coronal mass ejections, which can lead to magnetic fluctuations and disruptions in power grids, pipelines and communication systems.
Delamere and a team of co-authors detailed their findings about Jupiter鈥檚 magnetosphere in a recent paper in . Geophysical Institute research associate professor Peter Damiano, 蜜桃影像 graduate student researchers Austin Smith and Chynna Spitler, and former student Blake Mino are among the co-authors.
Delamere鈥檚 research shows that our solar system鈥檚 largest planet has a magnetosphere consisting of largely closed magnetic field lines at its polar regions but including a crescent-shaped area of open field lines. The magnetosphere is the shield that some planets have that deflects much of the solar wind.
The debate over open versus closed at the poles has raged for more than 40 years.
An open magnetosphere refers to a planet having some open-ended magnetic field lines near its poles. These are previously closed lines that have been broken apart by the solar wind and left to extend into space without re-entering the planet.
This creates regions on Jupiter where the solar wind, which carries some of the sun鈥檚 magnetic field lines, directly interacts with the planet鈥檚 ionosphere and atmosphere.
Solar particles moving toward a planet on open field lines do not cause the aurora, which largely occurs on closed field lines. However, the energy and momentum of solar wind particles on open field lines does transfer to the closed system.
Earth has a largely open magnetosphere at its poles, with aurora occurring on closed field lines.. It is the transferred energy on those open lines that can disrupt power grids and communications.
In order to study Jupiter鈥檚 magnetosphere, Delamere ran a variety of models using data acquired by the NASA Juno spacecraft, which entered Jupiter鈥檚 orbit in 2016 and has an elliptical polar orbit.
鈥淲e never had data from the polar regions, so Juno has been transformative in terms of the planet鈥檚 auroral physics and helping further the discussion about its magnetic field lines,鈥 Delamere said.
The debate began with the 1979 flybys of Jupiter by NASA鈥檚 and . That data led many to believe that the planet had a generally open magnetosphere at its poles. Other scientists argued that , which is much different from Earth鈥檚, indicated the planet had a mostly closed magnetosphere at the poles. Delamere, a longtime researcher of Jupiter鈥檚 magnetic field, published a paper supporting that view in 2010.
In 2021, he was a co-author on a that suggested through modeling that Jupiter鈥檚 magnetosphere had two regions of open magnetic field lines at its poles. The model shows one set of open-ended field lines emerging from the poles and trailing outward behind the planet in the magnetotail, the narrow teardrop-shaped portion of the magnetosphere pointing away from the sun. The other set emerges from Jupiter鈥檚 poles and goes off to the sides into space, carried by the solar wind.
鈥淭he Zhang result provided a plausible explanation for the open field line regions,鈥 Delamere said. 鈥淎nd this year we provided the compelling evidence in the Juno data to support the model result.
鈥淚t is a major validation of the Zhang paper,鈥 he said.
Delamere said it鈥檚 important to study Jupiter to better understand Earth.
鈥In the big picture, Jupiter and Earth represent opposite ends of the spectrum 鈥 open versus closed field lines,鈥 he said. 鈥淭o fully understand magnetospheric physics, we need to understand both limits.鈥
Other contributors are from the University of Colorado Boulder, Johns Hopkins University, Andrews University, Embry-Riddle Aeronautical University, University of Hong Kong, University of Texas San Antonio, Southwest Research Institute and O.J. Brambles Consulting in the United Kingdom.
Delamere will present the research in July at the Conference on Magnetospheres of the Outer Planets at the University of Minnesota.
ADDITIONAL CONTACT: Peter Delamere, padelamere@alaska.edu
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