Million fold increase in the power of waves near Jupiter's moon Ganymede
- Date:
- August 7, 2018
- Source:
- GFZ GeoForschungsZentrum Potsdam, Helmholtz Centre
- Summary:
- Chorus waves are electromagnetic waves. Converted to sound they sound like singing and chirping birds at dawn. They can cause polar lights above the Earth as well as damage to satellites. Now, a team of researchers has found that such waves are intensified million-fold around Jupiter's moon Ganymede. This study provides important observational constraints for theoretical studies.
- Share:
Listening to electro-magnetic waves around the Earth, converted to sound, is almost like listening to singing and chirping birds at dawn with a crackling camp fire nearby. This is why such waves are called chorus waves. They cause polar lights but also high-energy 'killer' electrons that can damage spacecraft. In a recent study to be published in Nature Communications, the authors describe extraordinary chorus waves around other planets in our solar system.
The scientists led by Yuri Shprits of GFZ and the University of Potsdam report that the power of chorus waves is a million times more intense near the Jovian moon Ganymede, and 100 times more intense near the moon Europa than the average around these planets. These are the new results from a systematic study on Jupiter's wave environment taken from the Galileo Probe spacecraft.
"It's a really surprising and puzzling observation showing that a moon with a magnetic field can create such a tremendous intensification in the power of waves," says the lead author of the study Professor Yuri Shprits of GFZ/ University of Potsdam and who is also affiliated with UCLA.
Chorus waves are a special type of radio wave occurring at very low frequencies.
Unlike the Earth, Ganymede and Europa orbit inside the giant magnetic field of Jupiter and the authors believe this is one of the key factors powering the waves. Jupiter's magnetic field is the largest in the solar system, and some 20,000 times stronger than the Earth's.
"Chorus waves have been detected in space around the Earth but they are nowhere near as strong as the waves at Jupiter" says Professor Richard Horne of British Antarctic Survey who is a co-author on the study. "Even if small portion of these waves escapes the immediate vicinity of Ganymede, they will be capable of accelerating particles to very high energies and ultimately producing very fast electrons inside Jupiter's magnetic field."
Jupiter's moon Ganymede was first found to have a magnetic field by Professor Margaret Kivelson and her team at the University of California, Los Angeles, and strong plasma waves were first observed near Ganymede by Professor Don Gurnett and his team at the University of Iowa. However, until now it remained unclear if this were just accidental or whether such increases are systematic and significant.
At the Earth, chorus waves play a major role in producing high-energy 'killer' electrons that can damage spacecraft. The new observations raise the question as to whether they can do the same at Jupiter.
Observations of Jupiter's waves provides us unique opportunity to understand the fundamental processes that are relevant to laboratory plasmas and the quest for new energy sources, and processes of acceleration and loss around the planets in the solar system and in the distant corners of the Universe. Similar processes may occur in exoplanets orbiting other stars and the understanding obtained in this study may help us detect whether exoplanets have magnetic fields. This study will provide very important observational constraints for theoretical studies that will try to quantify the tremendous increase in wave power.
Story Source:
Materials provided by GFZ GeoForschungsZentrum Potsdam, Helmholtz Centre. Note: Content may be edited for style and length.
Journal Reference:
- Y. Y. Shprits, J. D. Menietti, A. Y. Drozdov, R. B. Horne, E. E. Woodfield, J. B. Groene, M. de Soria-Santacruz, T. F. Averkamp, H. Garrett, C. Paranicas, D. A. Gurnett. Strong whistler mode waves observed in the vicinity of Jupiter’s moons. Nature Communications, 2018; 9 (1) DOI: 10.1038/s41467-018-05431-x
Cite This Page: