SSL (UC Berkeley): Prospective Codes to Transfer to the CCMC Developers: W.P. Abbett, D.J. Bercik, G.H. Fisher, B.T. Welsch, and Y. Fan (HAO/NCAR)

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SSL (UC Berkeley): Prospective Codes to Transfer to the CCMC Developers: W.P. Abbett, D.J. Bercik, G.H. Fisher, B.T. Welsch, and Y. Fan (HAO/NCAR)

ANMHD solves the 3D MHD equations in the anelastic approximation on a Cartesian grid. The anelastic approximation filters out fast acoustic waves in the solar interior. This allows efficient simulation of sub-surface convection. The serial version of the code has been in production mode since the code is well tested and very robust. ANMHD has been used to study: –The sub-surface evolution of active region magnetic fields –The convective dynamo –The properties of magneto- convection –The formation process of active regions at the base of the convection zone MOVIE MOVIE of a convective dynamo! Upper panel shows the evolution of a magnetized tube (left) or slab (right) interacting with convective turbulence Left panel shows entropy fluctuations in the convective interior and surface; right panel shows an active region emerging (gray-scale) and velocity (arrows, plus red/blue color map) near the surface

FLCT uses local correlation tracking to determine spatial displacements of image structure between two successive images. Local correlation tracking (LCT) can be applied to a pair of 2D images to infer horizontal flows that evolve one image to the next. IDL and C versions (tested on Linux, Solaris, and Windows) of the code are currently publicly available.* FLCT has been applied to: –Magnetograms –H-α images Inductive LCT (ILCT), an auxiliary routine, combines LCT results with vector magnetograms to derive three components of velocity. A version is being prepared for release. (*

AMPS (the adaptive MHD parallel solver) solves the 3D MHD equations with a sophisticated treatment of the energy equation AMPS is designed to study the evolution of magnetic fields from the solar convection zone to the upper atmosphere The semi-implicit algorithms allow for a simulation domain to include both the convectively unstable layers below the photosphere, and the solar corona The serial and MPI AMR (adaptive mesh refinement) versions are currently beta- testing AMPS is being used to study –Quiet Sun magnetic fields from the convection zone to the corona (e.g., pics to the right) –The emergence and decay of active region magnetic structures and the CME initiation process. Log density in a vertical slice from below the Quiet Sun photosphere into the corona. Flow field along a horizontal slice in the portion of the domain representing the convection zone. MPI block boundaries are shown. Top: Vertical flows along a horizontal slice Bottom: |B| along a horizontal slice below the photosphere in the convection zone. Same as left panel, but different slice

Under development: SANMHD --- solves the 3D MHD equations in the anelastic approximation in global, spherical geometry Funded by LWS and promised to CCMC The code has been in development since routines are being tested. Features: –Non-uniform radial grid –Spherical harmonic decomposition –Inclusion of a convective overshoot region at the base of the convection zone SANMHD will be used to study: –3D global flux transport models –The large scale dynamo in the solar interior –The global interaction of active region scale magnetic fields below the solar surface –The properties of global magnetoconvection –The formation process of active regions at the base of the convection zone –Fully convective stars, and stellar dynamos