The evolution of magnetic tower jets in the laboratory

2); 4); A. Ciardi (1; A. Frank (3; A. Marocchino (2); Astronomy; C.J. Jennings (6); C. Stehle (1) ((1) LUTH; D.J.Ampleford (6); E.G. Blackman (3

arxiv: astro-ph/0611441 · v1 · submitted 2006-11-14 · 🌌 astro-ph

The evolution of magnetic tower jets in the laboratory

A. Ciardi (1 , 2) , S.V. Lebedev (2) , A. Frank (3 , 4) , E.G. Blackman (3 , J.P. Chittenden (2) , C.J. Jennings (6)

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D.J.Ampleford (6) S. N. Bland (2) S. C. Bott (2) J. Rapley (2) G. N. Hall (2) F. A. Suzuki-Vidal (2) A. Marocchino (2) T. Lery (5) C. Stehle (1) ((1) LUTH Observatoire de Paris France. (2) The Blackett Laboratory Imperial College UK. (3) Department of Physics Astronomy University of Rochester USA. (4) Laboratory for Laser Energetics USA. (5) Dublin Institute for Advanced Studies Ireland. (6) Sandia National Laboratory USA.)

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classification 🌌 astro-ph

keywords magneticcavitycurrentsevolutionfieldjetslaboratoryplasma

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The evolution of laboratory produced magnetic jets is followed numerically through three-dimensional, non-ideal magnetohydrodynamic simulations. The experiments are designed to study the interaction of a purely toroidal field with an extended plasma background medium. The system is observed to evolve into a structure consisting of an approximately cylindrical magnetic cavity with an embedded magnetically confined jet on its axis. The supersonic expansion produces a shell of swept-up shocked plasma which surrounds and partially confines the magnetic tower. Currents initially flow along the walls of the cavity and in the jet but the development of current-driven instabilities leads to the disruption of the jet and a re-arrangement of the field and currents. The top of the cavity breaks-up and a well collimated, radiatively cooled, 'clumpy' jet emerges from the system.

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The evolution of magnetic tower jets in the laboratory

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