Relaxation 1D magnetized, collisionless plasma systems
POSTER
Abstract
One-dimensional magnetized plasma systems are ubiquitous in the Universe. In Cartesian geometry, magnetic field reversals and current sheets are abundant in planetary magnetospheres and solar wind turbulence. In cylindrical geometry, flux tubes and flux ropes are present as solar coronal loops and astrophysical jets. Although these systems are often regarded as equilibrium solutions, in reality they are more likely to start from disequilibrated states. Here we present the relaxation process of such magnetized, collisionless plasma systems, by classifying single-particle orbits and analyzing phase-space particle dynamics. The process is verified by particle-in-cell simulations and comparisons to spacecraft observations.
*This research was supported by an appointment to the JRG Program at the APCTP through the Science and Technology Promotion Fund and Lottery Fund of the Korean Government. This work was also supported by the POSCO Science Fellowship by the POSCO TJ Park Foundation.
Publication: Y. D. Yoon et al., "Collisionless relaxation of disequilibrated current sheet and implications for bifurcated structures," Nature Communications 12, 3774 (2021)
Y. D. Yoon et al., "Equilibrium selection via current sheet relaxation and guide field amplification," under review in Nature Communications
Presenters
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Young Dae Yoon
- Asia-Pacific Center for Theoretical Physics