53rd Annual Meeting of the Division of Plasma Physics, November 14 - 18, 2011, Salt Lake City, Utah When the total flow will move approximately along the.

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Presentation transcript:

53rd Annual Meeting of the Division of Plasma Physics, November , 2011, Salt Lake City, Utah When the total flow will move approximately along the symmetry direction. For small values of E r PENTA predicts flows will move in the direction of symmetry. V || Calculated Using PENTA The magnitude of has a minima in the middle of the neutral beam changes direction across the view/beam intersection volume measured by the CHERS views of the core. New views are being developed to measure the Pfirsch-Schlüter flow to better resolve E r in the core. V┴V┴ V V || ζ Boozer |B| and Velocity in HSX θ Boozer Beam atoms charge exchange with plasma ions, causing spatially localized photon emission. The Doppler shift, Doppler broadening and strength of the emission are used to calculate velocity, temperature and density respectively. A series of shots are taken with the magnetic field in the clockwise direction and then the counter clockwise direction in order to reverse the flow. This essentially doubles the measured Doppler shift and eliminates uncertainty in the position of the unshifted wavelength. For typical HSX ion temperatures (~50eV) the ion-ion collision times are short. ( τ E C+6/p ~3.0ms and τ E p/C+6 ~40ms) Proton temperatures should be similar to the measured C +6 temperatures. Measuring and Predicting the Flow Velocity in the HSX Stellarator A. Briesemeister, K. Zhai, J. Radder, D.T. Anderson, F.S.B. Anderson, J.N. Talmadge HSX Plasma Laboratory, Univ. of Wisconsin, Madison, USA Flows Increase with ECRH References 1)D.A. Spong, Phys. Plasmas 12, (2005). 2)J. Lore, Phys. Plasmas (2010). 3)Hirshman et al., Phys. Fluids 29, 2951 (1986). 4)van Rij et al., Phys. Fluids B 1, 563 (1989). 5)S.P. Gerhardt et al., Phys. Plasmas 12, (2005). CHERS has been used to measure C +6 flow velocity, temperature and density. The PENTA code has been used to calculate the neoclassical value of the radial electric field and parallel flow. Ion flows are measured to increase with increasing electron heating power. PENTA predicts an increase in E r in the core and an increase in the pressure gradient driven flow in the outer half of the plasma for the higher power case. The flow direction is measured and predicted to be predominantly along the helical direction of symmetry in the outer half of the plasma where flows are predicted to be predominantly driven by the pressure gradient. Agreement is seen between measured and neoclassically predicted V || in the outer half of the plasma Flow direction and magnitude changes significantly within the core of the plasma, complicating interpretation of the CHERS measurements near the axis Improvements to the CHERS views are planned Overview Thanks to MST for loaning us the neutral beam. View 2 View 1 Neutral Beam View 1 View 2 30keV 4Amp 4ms hydrogen diagnostic neutral beam Two 0.75m Czerny-Turner spectrometers with EMCCDs 10 radial locations are viewed from two different directions. Flows will not have a component in the radial direction, so the flow velocity vector is uniquely determine by the two velocity measurements Charge Exchange Recombination Spectroscopy (CHERS) PENTA Calculations The PENTA code [1][2] is used to calculate neoclassical particle fluxes, radial electric field, and parallel flow velocities. Monoenergetic transport coefficients are calculated using the Drift Kinetic Equation Solver (DKES). DKES [3][4] uses a non-momentum conserving collision operator, which was previously assumed to be sufficiently accurate for calculations in stellarators, which do not posses a direction of symmetry. PENTA can reintroduce the effects of momentum conservation, making the calculations applicable to devices with a variety of levels of symmetry in their magnetic field structure. PENTA can also include the effects of multiple ion species. E r is Determined by the Ambipolarity Condition for Particle Flux Ion Flows Increased Electron root: Larger positive E r associated with reduced neoclassical transport Ion root: Smaller, sometimes negative E r Unstable root: Not a stable solution V || for the protons is predicted to have a similar dependence on all the thermodynamic drive terms: Particle Flux At r/a=0.22 T i was Similar T e Increased in the Core The electron temperature and temperature gradient in the core of the plasma increased with ECRH The density profile for the 100kW had a smaller gradient in the core, but a larger gradient near r/a=0.6 In both the 100kW and 50kW cases near the axis only an electron root is predicted, from r/a~0.2 to r/a~3 multiple roots are predicted, for the outer half of the plasma only the ion root is predicted. E r is predicted to be slightly lower in the 50kW case for most locations in the plasma HSX was optimized to have a direction of symmetry in its magnetic field strength. This has been predicted and measured to cause reduced flow damping in the n=4, m=1 helical direction [5]. Reduced Flow Damping Along the Helical Direction of Symmetry Leads to Parallel Flow For large perpendicular flow drives, such as the electron root radial electric field, ions which caused the plasma viscosity are de-trapped and parallel flow will be reduced For both the 100kW and the 50kW cases a small V || is predicted near the core as a result of the large electron root E r The peak flows are larger than the ion thermal velocity, no experimental evidence of supra-thermal flows has been found Flow Direction and Magnitude Predicted to Vary Significantly Near the Axis V || (km/s) Neutral Beam Density Typical Poloidal View Volume The magnitude of the plasma flow velocity components are plotted for the toroidal location where CHERS measurements are made. Flows shown were calculated using profiles for the 100kW case. The electron root was chosen in the multi root region The total V || is dominated by the Pfirsch-Schlüter component Reasonable Agreement seen Between Measured and Calculated V || The measured ion flow velocity was significantly faster in the case where 100kW of electron cyclotron resonance heating (ECRH) was used. All flows are intrinsic (no external momentum sources). Ion temperatures did not measurably change. E r Calculated Using PENTA B The Relationship Between V || and E r calculated for r/a=0.22 The Pressure Gradient Terms Are Significantly Larger Than E r in the Outer Half of the Plasma In the outer half of the plasma E r is small and in some regions negative, which in the absence of the pressure gradient terms would drive a negative parallel flow. Reasonable agreement is seen between the measured and calculated V || when all terms are included. Total V || Predicted Total Predicted Measured Flows Are Predominantly in the Helical Direction of Symmetry For small values of E r parallel flows will arise that cause the total flow direction to be along the direction of symmetry, on average. In the outer half of the plasma, where E r is predicted to be small, the direction is along direction of symmetry.