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SIMULATING SHOCKS IN SOLAR FLARES Matthew Thornton “If there is a solar flare or a nuclear war, a thousand cans of pickled turnips aren’t going to save.

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Presentation on theme: "SIMULATING SHOCKS IN SOLAR FLARES Matthew Thornton “If there is a solar flare or a nuclear war, a thousand cans of pickled turnips aren’t going to save."— Presentation transcript:

1 SIMULATING SHOCKS IN SOLAR FLARES Matthew Thornton “If there is a solar flare or a nuclear war, a thousand cans of pickled turnips aren’t going to save you.” -Sarah Lotz, The Three

2 Flares are among the most energetic solar events

3 “…reconnection is essentially a topological restructuring of a magnetic field caused by a change in the connectivity of its field lines.” (Priest & Forbes, 2000) Project simulates flare energy release due to reconnection Longcope & Klimchuk 2015 (submitted) Magnetic energy Kinetic energy Thermal energy

4 We focus on what happens to a single flux tube after reconnection Longcope & Klimchuck, 2015 (Submitted)

5 PREFT uses a Lagrangian grid method Define a grid which moves with the fluid We measure things as an observer sitting on a fluid element Cells contain approx. equal masses of fluid Good method for modelling 1D flows Takagi, S. et al, 2011

6 We solve the MHD energy and momentum equations iteratively adiabatic work divergence of the heat flux radiative losses viscous heating ad hoc source Conduction coefficient: Longcope & Klimchuck, 2015 (Submitted)

7 A typical PREFT run

8 Some results: increasing tube length -> more loop energy

9 Varying ξ -1 sharpens fronts and raises peak temperatures

10 References Lang, K. R. (2001). The Cambridge Encylcopedia of the Sun. Cambridge: Cambridge University Press. Longcope, D., & Klimchuk. (2015 ). How gas-dynamic flare models powered by Petshek reconnection differ from those with ad hoc energy sources. (Submitted). Priest, E., & Forbes, T. (2000). Magnetic Reconnection: MHD Theory and Applications. Cambridge: Cambridge University Press. Takagi, S.; et. al. (2011). A review of full eulerian methods for fluid structure interaction problems. J. Appl. Mech.

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