Solitary waves in translation
Swooping through space are solitary waves, which in theory do not change form or lose energy as they go along. These waves, which exist on Earth in different media, have been detected and explained for the first time in space thanks to Cluster data.
In theory, these solitary waves, called solitons, propagate endlessly maintaining their shape and form as well as velocity, which means that they do not lose energy with time.
The phenomenon was first noticed in a water canal in England in 1834 by John Scott Russel, who named it a ‘wave of translation’. In water, solitons can be created when a sudden impulse hits the medium and propagates along it. This is made possible by a delicate balance of physical parameters that reinforces the wave without additional energy input externally. Today, optic fibres carry large amounts of information over very long distances making use of soliton waves. This provides crystal-clear international phone calls and fast internet connections.
On 30 March 2002, at a distance of
“Knowing the positions and separation of the spacecraft at that time, we have found that the wave was 6-7 km in size and moved in towards the magnetosphere at roughly 8 to 9 km/s. We couldn’t have done this without multiple spacecraft,” said Raoul Trines of the Rutherford Appleton Laboratory, UK, lead author of the study.
This phenomenon is very difficult to study on Earth because the soliton-like structures that are observed tend to be much smaller in size, similar to the size of the instruments that are used to probe them. Thus, the instruments can disturb the phenomenon itself. Given the fact that the soliton detected in space was very large, the disturbance caused to the wave as the satellites probed it was negligible.
The observations performed by the Cluster satellites were found to be in good agreement with computer simulations, confirming earlier theoretical predictions of their existence.
“Thanks to its multiple spacecraft, Cluster has the unique capability to differentiate spatial variations from temporal variations. This makes it the first mission to confirm the theoretical prediction of solitons in space,” said Philippe Escoubet, ESA’s Cluster and Double Star Project Scientist. “This result is truly one of the mission’s scientific highlights,” he added.
Notes for editors:
This article is based on the paper ‘Spontaneous Generation of Self-Organized Solitary Wave Structures at Earth's Magnetopause’ by R. Trines, R. Bingham, M. Dunlop, A. Vaivads, J. Davies, J. Mendonça, L. Silva, and P. Shukla, published on 16 November 2007 in the Physical Review Letters.
For more information:
Dr Raoul Trines, Rutherford Appleton Laboratory, United Kingdom
Email: R.M.G.Trines @ rl.ac.uk
Philippe Escoubet, ESA Cluster and Double Star Project Scientist
Email: Philippe.Escoubet @ esa.int
Arnaud Masson, ESA Cluster Scientist
Email: Arnaud.Masson @ esa.int