Simulation of fast-mode magneto sonic waves excited by plasmid ejections

 

Liping Yang et al.  2015 ApJ  800 111 doi:10.1088/0004-637X/800/2/111

NUMERICAL SIMULATION OF FAST-MODE MAGNETOSONIC WAVES EXCITED BY PLASMOID EJECTIONS IN THE SOLAR CORONA

 

Liping Yang1,2, Lei Zhang1, Jiansen He1, Hardi Peter3, Chuanyi Tu1, Linghua Wang1, Shaohua Zhang4, and Xueshang Feng2

 

[email protected]

1School of Earth and Space Sciences, Peking University, 100871 Beijing, China 2 SIGMA Weather Group, State Key Laboratory for Space Weather, Center for Space Science and Applied Research, Chinese Academy of Sciences, 100190 Beijing, China 3 Max-Planck-Institut für Aeronomie, Max-Planck-Strasse, D-37191 Katlenburg-Lindau, Germany 4 Center of Spacecraft Assembly Integration and Test, China Academy of Space Technology, Beijing 100094, China

The Atmospheric Imaging Assembly instrument on board the Solar Dynamics Observatory  has directly imaged the fast-propagating magnetosonic waves (FMWs) successively propagating outward along coronal magnetic funnels. In this study we perform a numerical investigation of the excitation of FMWs in the interchange reconnection scenario, with footpoint shearing flow being used to energize the system and drive the reconnection. The modeling results show that as a result of magnetic reconnection, the plasma in the current sheet is heated up by Joule dissipation to ~10 MK and is ejected rapidly, developing the hot outflows. Meanwhile, the current sheet is torn into plasmoids, which are shot quickly both upward and downward. When the plasmoids reach the outflow regions, they impact and collide with the ambient magnetic field there, which consecutively launches FMWs. The FMWs propagate outward divergently away from the impact regions, with a phase speed of the Alfvén speed of ~1000 km s–1. In the k  – ω diagram of the Fourier wave power, the FMWs display a broad frequency distribution with a straight ridge that represents the dispersion relation. With the WKB approximation, at the distance of 15 Mm from the wave source region, we estimate the energy flux of FMWs to be E  ~ 7.0 × 106 erg cm–2 s–1, which is ~50 times smaller than the energy flux related to the tube-channeled reconnection outflow. These simulation results indicate that energetically and dynamically the outflow is far more important than the waves.

 

 

Keywords

magnetic reconnectionSun: coronawaves

 

Dates

Issue 2 (2015 February 20)

Received 2013 November 25, accepted for publication 2014 December 23

Published 2015 February 18