Researchers develop a successful and validated new model of coronal mass ejections to improve space weather forecasting.
press released on Mar.1, 2016
Caption: A coronal mass ejection event showing a representation of the flux rope anchored at the sun and the propagation of the magnetic flux rope through space toward Earth. The white shaded lines indicate the magnetic field lines. Red shade indicates high speed stream in the front of the CME.
Nagoya, Japan - Coronal mass ejections (CMEs) are massive expulsions of magnetic flux into space from the solar corona, the ionized atmosphere surrounding the sun. Magnetic storms arising from CMEs pose radiation hazards that can damage satellites and that can negatively impact communications systems and electricity on Earth. Accurate predictions of such events are invaluable in space weather forecasting.
A new and robust simulation code for CME events was developed based on the realistic description of the mechanisms behind CME generation and their propagation through space. An article recently published in Space Weather presents their results from the method, which was successfully validated using observational data from a series of CME events reaching the Earth's position around Halloween of 2003.
"Our model is able to simulate complex 'flux ropes', taking into account the mechanisms behind CME generation derived from real-time solar observations. With this model, we can simulate multiple CMEs propagating through space. A part of the magnetic flux of the original flux rope inside the CME directed southward was found to reach the Earth, and that can cause a magnetic storm," explains lead author Daikou Shiota of the Nagoya University Institute of Space and Earth Environmental Research. The new model represents a significant step in space weather research. "The inclusion of the flux rope mechanism helps us predict the amplitude of the magnetic field within a CME that reaches the Earth's position, and accurately predicts its arrival time," Shiota says.
A series of CMEs occurring in late-October 2003 released large flares of magnetic energy that reached the Earth several days later, causing radio blackouts and satellite communications failures. Data from these events were used to validate the approach taken in the new model.
"In our validation, we were able to predict the arrival of a huge magnetic flux capable of causing one of the largest magnetic storms in the last two decades," says coauthor Ryuho Kataoka of the National Institute of Polar Research and the Department of Polar Science, SOKENDAI (Graduate University for Advanced Studies). "Because our model does not simulate the solar coronal region, its computational speed is fast enough to operate under real-time forecasting conditions. This has various applications in ensemble space weather forecasting, radiation belt forecasting, and for further study of the effects of CME-generated solar winds on the larger magnetic structure of our solar system." Shiota says.
This is a new generation of a well-developed complex flux rope within a CME model, and it provides a valuable step towards enhanced operational space weather forecasting. These findings will significantly contribute to accurately predicting magnetic fields in space and enhancing our understanding of the mechanisms behind CME events.
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The article "Magnetohydrodynamic simulation of interplanetary propagation of multiple coronal mass ejections with internal magnetic flux rope (SUSANOO-CME)" was published in Space Weather, at doi:10.1002/2015SW001308
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Authors: Designated Assistant Prof. Daikou Shiota, Institute for Space and Earth Environmental Research, Nagoya University, and Associate Prof. Ryuho Kataoka, National Institute of Polar Research
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Institute for Space-Earth Environmental Research (ISEE), Nagoya University
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Funding: This work was carried out as a computational joint research program at the Institute for Space and Earth Environmental Research (ISEE), Nagoya University. This research partially used computational resources of the Earth Simulator provided by JAMSTEC. This work is supported by the GEMSIS project at ISEE/Nagoya University, by JSPS KAKENHI grant 26800255 15H05815 andby the National Institute of Polar Research through General Collaboration Project (27-6).