Measurement of Kinetic-Scale Current Filamentation Dynamics and Associated Magnetic Fields in Interpenetrating Plasmas

Measurement of Kinetic-Scale Current Filamentation Dynamics and Associated Magnetic Fields in Interpenetrating Plasmas

We present the first local, quantitative measurements of ion current filamentation and magnetic field amplification in interpenetrating plasmas, characterizing the dynamics of the ion Weibel instability. The interaction of a pair of laser-generated, counterpropagating, collisionless, supersonic plas...

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Veröffentlicht in:Physical review letters 2020-05, Vol.124 (21), p.1-215001, Article 215001
Hauptverfasser: Swadling, G. F., Bruulsema, C., Fiuza, F., Higginson, D. P., Huntington, C. M., Park, H-S., Pollock, B. B., Rozmus, W., Rinderknecht, H. G., Katz, J., Birkel, A., Ross, J. S.
Format: Artikel
Sprache:eng
Schlagworte:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
collisionles shock in plasma
Dynamic stability
high-energy-density plasmas
Ion currents
Kinetic energy
laboratory studies of space & astrophysical plasmas
laser inertial confinement
laser-induced magnetic fields in plasmas
Magnetic fields
optical plasma measurements
particle-in-cell methods
Plasma currents
plasma instabilities
plasma kinetic theory
plasma macroinstabilities
plasma production & heating by laser beams, laser-foil, laser cluster
plasma-beam interactions
Plasmas
Thomson scattering
time-resolved light scattering spectroscopy
Weibel instability
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Zusammenfassung:We present the first local, quantitative measurements of ion current filamentation and magnetic field amplification in interpenetrating plasmas, characterizing the dynamics of the ion Weibel instability. The interaction of a pair of laser-generated, counterpropagating, collisionless, supersonic plasma flows is probed using optical Thomson scattering (TS). Analysis of the TS ion-feature revealed anticorrelated modulations in the density of the two ion streams at the spatial scale of the ion skin depth c/ωpi=120  μm, and a correlated modulation in the plasma current. The inferred current profile implies a magnetic field amplitude ∼30±6  T, corresponding to ∼1% of the flow kinetic energy, indicating that magnetic trapping is the dominant saturation mechanism.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.124.215001