Theory and Modeling

1. Theory and Modeling Allan Reiman NCSX Research Forum Dec. 7, 2006

2. Theory projects being pursued, and some plans for the future. Introduction • Most theoretical work supported by broader contracts rather than by projects (unlike experimental work). Not well represented here. • Long term plans to be discussed in more detail at follow-up national stellarator theory teleconference on Dec. 14. • Equilibrium • Stability • Transport • Edge Modeling AHR 12/7/06

3. Calculation of equilibrium is a necessary first step before doing further analysis. • STELLOPT optimizer for stellarator design (Hirshman et al, ORNL) adapted for equilibrium reconstruction (Zarnstorff, PPPL) • V3FIT collaboration on equilibrium reconstruction uses VMEC equilibrium code. Jim Hanson (Auburn), Hirshman & Lazarus (ORNL), Lao (GA) • HINT2 code (Suzuki & Hayashi, NIFS, Japan) and PIES code (PPPL) can handle equilibria with magnetic islands and/or stochastic regions. Fraction of good flux surfaces versuscalculated by PIES for two values of control coil current for W7AS. The circles indicate PIES calculations done for experimentally achieved . AHR 12/7/06

4. Improvement of 3D equilibrium codes is continuing. • PIES (Monticello, Reiman, Raburn - PPPL). • Comparing predictions with W7AS data, improving physics model in response to observations (e.g. pressure in stochastic region). • Speed up via algorithm improvement, parallelization, development of PIES-Lite for rapid evaluation. • Plan to incorporate neoclassical effects, flow-shielding. • Development of new codes • Hirshman et al (ORNL): VMEC with islands. • Hegna et al (Univ. Wisconsin), initiating new project, to address stochastic regions. • Over long run will also want to incorporate flow and kinetic effects. AHR 12/7/06

5. Instability: Under what circumstances does it limit  or restrict desirable operating space? • Linear, global MHD stability codes: Terpsichore (Cooper, Lausanne), CAS3D (C. Nűhrenberg, Germany). • Terpsichore optimized to be very fast. • CAS3D generalized to handle conducting walls with arbitrary holes (Merkel). Kinetic effects being introduced. • Ideal ballooning • New suites of codes developed by Sanchez and Hirshman (Spain and ORNL), Ware (Univ. Montana), Hegna, Hudson et al (Univ. Wisconsin, PPPL). Marginal stability diagram for NCSX VMEC surface s = 0.6, β = 4.2%(——), β = 9.5%(· · · · · ·) and β = 14.0%(- - - -) (Hudson, Hegna, Nakajima). AHR 12/7/06

6. Instability: Effects of nonlinearity, additional physics being studied. • Ballooning • Ray tracing to make connection to global modes. (Ware, Hudson, Hegna). • Work on kinetic effects also in initial stage. • Nonlinear 3D MHD • DNS code, H. Miura et al (NIFS, Japan). • Extended-MHD: M3D. Strauss (NYU), Sugiyama (MIT), Hudson (PPPL) • Energetic particle driven modes • Spong (ORNL): STELLGAP global eigenmode calculation. • High mode number kinetic, Gorelenkov (PPPL). In development. • Nonlinear: Fu, M3D (PPPL) Saturated pressure in LHD at =1.5%. Ichiguchi et al, NORM 3D reduced MHD code. AHR 12/7/06

7. Transport: How is it affected by interaction between 3D neoclassical effects and turbulence? • Mynick, Boozer et al using simplified models to study physics of neoclassical-turbulence interaction. • Gyrokinetic flux tube codes have been extended to stellarators (US, IPP, NIFS). • Jenko (IPP, Germany) collaborating with Mynick & Boozer on physics studies • Collaborative computational gyrokinetic studies planned (IPP, NIFS, U. MD., U. Wisc., PPPL) Diffusion coefficient vs. amplitude of turbulence. Monte-Carlo calculations with model turbulent spectrum. (Mynick and Boozer). AHR 12/7/06

8. Development of Transport Codes Continuing • Global gyrokinetic GTC code to be extended to stellarators, first for neoclassical calculations, later for turbulent transport (PPPL). • Global gyrokinetic TORB in development at Greifswald (SORGE et al) • DKES/PENTA codes (Spong et al, ORNL): calculate Er, bootstrap current, plasma flow • Longer term will also need computation of transport with magnetic islands. Ion flow velocity streamlines on a flux surface for NCSX (Spong et al). AHR 12/7/06

9. Edge Modeling • Livermore field line tracing code. Kaiser et al. • Uses either MFBE/VMEC or PIES with Drevlak postprocessor for field. • Tool for generating DEGAS 2 geometries from VMEC equilibria under development. • EMC/EIRENE code to be imported from Germany. • E3D code under development at Greifswald (Schneider et al). Calculated heat deposition on a proposed NCSX divertor plate. (Kaiser et al) AHR 12/7/06

10. Solid theoretical understanding will be necessary if we are to impact design of Demo reactor following ITER. • Three-dimensionality complicates calculation of equilibrium, stability, transport, and edge modeling. • New computational tools under development will address needs of NCSX project. • New physics issues arise in 3D: equilibrium islands; effect of 3D shaping on linear & nonlinear stability; interaction between turbulent & neoclassical transport effects; stochastic field lines at edge; etc. • Issues are being addressed, and NCSX experiments will help us develop an understanding of them. • Computational tools and physics understanding will also be applicable to 3D issues in tokamaks. AHR 12/7/06