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Clayton E. Myers July 9 , 2013

Line-Tied Magnetic Flux Ropes in the Laboratory: Equilibrium Force Balance & Eruptive Instabilities. Hinode. MRX. Clayton E. Myers July 9 , 2013. MRX Collaborators: M. Yamada, H. Ji, J. Yoo, and J. Jara-Almonte MHD Simulations: E. Belova

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Clayton E. Myers July 9 , 2013

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  1. Line-Tied Magnetic Flux Ropes in the Laboratory: Equilibrium Force Balance & Eruptive Instabilities Hinode MRX Clayton E. Myers July 9, 2013 MRX Collaborators: M. Yamada, H. Ji, J. Yoo, and J. Jara-Almonte MHD Simulations: E. Belova Technical Contributors: R. Cutler, P. Sloboda, and F. Scotti

  2. Overview • These are the first results from a new laboratory experiment that is designed to study quasi-statically driven flux ropes • Overarching physics question: • How do the parameters of the potential field arcade (i.e., its strength, orientation, and gradient) influence the flux rope evolution? • Primary topics: • Equilibrium force balance • Sigmoidal flux ropes • The kink & torus instabilities (eruptions)

  3. Other laboratory flux rope experiments Caltech • Several existing experiments have studied flux rope eruptions in the lab • Caltech & FlareLab dynamically inject poloidal flux at the footpoints • UCLA uses lasers to inject mass and current at the footpoints • These dynamically driven eruptions do not qualify as “storage-and-release” events FlareLab UCLA

  4. Line-tied magnetic flux rope experiments in MRX Line-Current Coil Line-Current Coil Electrodes Electrodes Electrodes The flux rope footpoints are line-tied to conducting electrodes The plasma current (twist) is injected quasi-statically (~100 μs) The plasma is low-β with significant stored magnetic energy The applied potential field arcade is highly tunable Glass Substrate Glass Substrate Arcade Coils Arcade Coils Vessel Length ~ 2 m Helmholtz Coils Helmholtz Coils

  5. Changing the orientation of the potential field arcade

  6. Changing the orientation of the potential field arcade • The orientation and the strength of the arcade are key knobs in determining the flux rope behavior • We can also vary the vertical gradient of the arcade to study the torus instability

  7. Distributed in situ magnetic diagnostics • On MRX, we deploy large arrays of internal magnetic probes to measure the spatial and temporal evolution of the plasma Visible Light Bx= toroidal field z z x y By= poloidal field

  8. Parallel potential arcade  quiescent flux ropes 1018 G 0° -17.6 kA 737 G 0° -18.6 kA 300 G 0° -20.8 kA Strength Angle Current Strength Angle Current Strength Angle Current = = = = = = = = =

  9. Parallel potential arcade  quiescent flux ropes 149 G 0° -20.5 kA Strength Angle Current = = = • Flux ropes that are formed within a parallel potential arcade are confined in a quasi-static equilibrium • Internal toroidal field is generated during the discharge • No dynamic eruptions are observed in this regime • The kink instability saturates at low amplitude, even in cases with large twist (due to line-tying effects)

  10. Minor radius force balance  internal toroidal field Linear flux rope Adapted from Friedberg Rev. Mod. Phys., 1982 • The “toroidal” current in the flux rope produces a pinch force • If the flux rope is low-β, the force balance must come from toroidal field pressure

  11. Major radius force balance  MHD simulations Applied Potential Field Perturbed/Plasma Field The HYM Code (E. Belova, PPPL)

  12. Major radius force balance from the simulations Key results: The induced toroidal field changes both the pressure and the tension within the flux rope These forces largely prevent dynamic behavior in parallel potential arcade flux ropes

  13. Oblique potential arcade  erupting flux ropes 323 G 22° -20.9 kA 305 G 11° -20.4 kA 309 G 0° -20.4 kA Strength Angle Current Strength Angle Current Strength Angle Current = = = = = = = = =

  14. Oblique potential arcade  erupting flux ropes 347 G 30° -21.8 kA Strength Angle Current = = =

  15. Oblique potential arcade  sigmoid formation • Parallel arcades produce parallel flux ropes that are confined by toroidal field forces • Oblique arcades produce sigmoidal flux ropes that can erupt • In a sigmoid, the flux rope apex runs perpendicular to the arcade, thereby avoiding the aforementioned toroidal field forces • Many open questions: • What determines the critical arcade orientation angle that leads to eruptions? • How much internal axial flux is carried within the sigmoid? Is there a laboratory knob for this? • What are the specific roles of the kink and torus instabilities in driving the observed eruptions? Adapted from Savcheva et al., ApJ 2012 MRX (Initial Breakdown Image)

  16. The next step: A new 2D in situ magnetic probe array • Five probes with 54 magnetic field measurements each (270 total channels) • Full coverage from z = 0 to the vessel wall (~64 cm) • Arbitrarily rotatable between discharges in order obtain 2D maps of the sigmoidal equilibrium features and erupting structures Perpendicular to the Arcade Parallel to the Arcade

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