Local Electron Thermal Transport in the MST Reversed-Field Pinch

Local Electron Thermal Transport in the MST Reversed-Field Pinch T.M. Biewer,, J.K., B.E. Chapman, N.E. Lanier,, S.R. Castillo, D.J. Den Hartog,, and C.B. Forest University of Wisconsin-Madison Recent diagnostic developments, including an upgrade of the MST Thomson scattering system, have facilitated the first local power balance analysis of electron thermal transport in the MST. Experiments have focused on acquiring profile data for T e and n e under standard and enhanced confinement () operating modes. Analysis shows that the thermal conductivity is lower during, and that the profile remains flat through the plasma core, decreasing sharply in the edge where the gradient of T e is largest. Power deposition is calculated from the MSTFIT reconstructed current density profile and estimates of the neoclassical (Hirshman( Hirshman- Sigmar) resistivity (trapped particle corrections to resistivity are found to be significant for 2D RFP equilibria.) A Monte Carlo uncertainty analysis is done for all results of the transport analysis. This work was supported by the U.S. D.O.E. APS DPP 1999, UW-Madison Plasma Physics November 16th, 1999 Seattle, WA

Motivation Ongoing improvements to the diagnostic arsenal of the Madison Symmetric Torus have initiated new investigations into the plasma physics of MST transport. The use of Pulsed Poloidal Current Drive () in the past has demonstrated improved confinement in the MST, based on central electron temperature measurements and a hypothesized profile shape. Recent upgrades of the Thomson scattering system have facilitated measurements of the T e profile in the MST out to r/a=.88. Addition of an NIR Bremstrahlung array has allowed an estimation of Z eff in the MST. We assume Z eff =2. These measurements, when coupled with density profiles from FIR Interferometry and MSTFIT reconstructed equilibria, have made it possible to calculate many transport quantities, including the electron thermal conductivity Χ e and the energy confinement time τ E. Monte Carlo analysis is used to ascribe error bands for transport quantities, rather than attempting to nonlinearly propagate the experimental uncertainty in the measured data. APS DPP 1999, UW-Madison, Plasma Physics November 16th, 1999 Seattle, WA

What is Pulsed Poloidal Current Drive? Loop Voltage (V) soft X-ray ratio (~Te) Toroidal Gap Voltage (V) Reversal Parameter, F F=Bt(a)/<Bt> standard discharge 23-oct-1998 #6 discharge 23-oct-1998 #51 During a "normal" plasma discharge a series of 5 voltage pulses are applied to the MST shell to produce a magnetic field which is in the opposite sense to the established toroidal magnetic field, forcing flux out of the MST. This opposing B is thought to cause a poloidally driven edge current. is observed to improve machine performance. It is believed that magnetic modes in the MST derive their free energy from the gradient in the current profile, which is steepest at the edge. By inductively driving current in the edge, could reduce the gradient and remove free energy from the magnetic modes, resulting in decreased magnetic fluctuations and hence improved particle and energy confinement. t (s) from begining of discharge

MST Thomson Scattering Diagnostic 5J single-pulse/single-point ruby laser TS system: ensembling of shots (over multiple days) is necessary to construct spacial profiles AND time evolution. z r correction lenses movable fiber bundle spectrometer to beam dump edge ruby laser path MCP & electronics MST toriodal centerline 1.5 m r/a=.9 viewing dump central ruby laser path r/a=.6 T A A B B T T f=15 mm conv. lens steering mirrors r/a 1.8.6.4.2 21 12 24 9 27 6 3 3 33 chords used Thomson Scattering Views view r/a φ 1.627-18.46 2.455-16.93 3.283-13.53 4.115 5.8 123.91 6.244 147.6 7.415 151.39 8.587 153.19 9.882 22.28 1.769 31.41 11.681 43.26 12.63 57.76 13.625 73.61 14.666 88.59 15.746 11.1 16.854 11.82 15 view 1 5.2.4.6.8 1 r/a error bars indicate radial range of scattering volume on each view

Far Infrared Interferometer Diagnostic H α and Electron Density Profile Measurements on MST 9 Chord H Array Waveguides Signal Beam 11 Chord Far Infrared Interferometer Reference Beam Wire Mesh BeamSplitters Twin Far Infrared Lasers 25mW Each 432 m Plasma Vacuum Duct CO 2 Pumping Laser 125 W Continuous =1.6 m Schottky Detectors The 11 Chord Far Infrared(FIR) Laser Interferometer provides electron density measurements with 4 µs time resolution. The 9 Chord H Array α along with the data obtained from the FIR interferometer allow measurements of the neutral Hydrogen density.

MSTFIT and Monte Carlo Error Analysis MSTFIT is a fully toroidal (2D) equilibrium reconstruction code that utilizes measured data to constrain the reconstruction. Plasma Parameters: F, θ, and I p are entered along with edge magnetic probe signals to manage the reconstruction of equilibrium quantities. Once an equilibrium is found, it becomes easier to invert chord averaged quantities, such as FIR measured electron density. The inversions are done in flux coordinate geometry, which can differ significantly from machine geometry. Diagnostic data such as T e, T i, n e, dt e /dt, dn e /dt, and Z eff are then combined with reconstructed quantities to ultimately calculate profiles of transport coefficients. By randomly varying the measured quantities within their error bars and collecting the calculated transport quantities, a Monte Carlo type "error band" is derived. APS DPP 1999, UW-Madison, Plasma Physics November 16th, 1999 Seattle, WA

MSTFIT is a fully toroidal, 2D equilbrium reconstruction code

Measured Profiles Ip~2 ka 6 5 First 6 point electron temperature profiles measured on the MST. 4 T e (ev) 3 2 1 15 6 chord, ensembled Thomson scattering Biewer.1.2.3.4.5 Thomson Scattering measurements are assembled over multiple days and are susceptible to changes in machine conditions. inferred T i (ev) 1 5 The assumptions that Ti=1/4 Te for and Ti=1/2 Te for discharges are supported by measurements from majority and minority impurity diagnostics. 1.2 1 19.1.2.3.4.5 n e (m -3 ) 1 1 19 8 1 18 6 1 18 4 1 18 FIR Interferomety measured density profiles are Abel inverted using MSTFIT, a fully toroidal equilibrium reconstruction code. 2 1 18 Abel Inverted 11 chord Far Infrared Interferometry Lanier.1.2.3.4.5

Measured Profiles Ip~4 ka 8 7 6 First 6 point electron temperature profiles measured on the MST. 5 T e (ev) 4 3 2 1 25 6 chord, ensembled Thomson scattering Biewer.1.2.3.4.5 Thomson Scattering measurements are assembled over multiple days and are susceptible to changes in machine conditions. inferred T i (ev) 2 15 1 5 The assumptions that Ti=1/4 Te for and Ti=1/2 Te for discharges are supported by measurements from majority and minority impurity diagnostics. n e (m -3 ) 1.4 1 19.1.2.3.4.5 1.2 1 19 1 1 19 8 1 18 6 1 18 FIR Interferomety measured density profiles are Abel inverted using MSTFIT, a fully toroidal equilibrium reconstruction code. 4 1 18 2 1 18 Abel Inverted 11 chord Far Infrared Interferometry Lanier.1.2.3.4.5

1.5 1 6 Reconstructed Profiles Ip~2 ka current density (A/m 2 ) 1 1 6 5 1 5 The current density on axis clearly increases, whereas in the edge there is little apparent change..1.2.3.4.5.6 trapped particle fraction.5.4.3.2 MSTFIT predicts that a substantial fraction of the particles are magnetically trapped in the MST during both and discharges. q dq/dr.1.3.2.1 -.5-1.1.2.3.4.5 -.1 -.2.5 -. 1.56.1.2.3.4.5.1.2.3.4.5 5 Bp Bt Btot Bp Bt Btot.25.2.15.1.5 1.55 1.54 1.53 1.52 1.51 B (T) R surf (m) The application of clearly shifts the flux reversal surface inward, as shown by observing the zero crossing of the toroidal magnetic field. Also, leads to an increase in the amount of magnetic sheer at the edge of the plasma. -1.5.1.2.3.4.5.1.2.3.4.5 1.5

2.5 1 6 Reconstructed Profiles Ip~4 ka current density (A/m 2 ) 2 1 6 1.5 1 6 1 1 6 5 1 5.6.1.2.3.4.5 The current density on axis clearly increases, whereas in the edge there is little apparent change. trapped particle fraction.5.4.3.2 MSTFIT predicts that a substantial fraction of the particles are magnetically trapped in the MST during both and discharges..1 q dq/dr.3.2.1.1.2.3.4.5 -.1 -.2.5 1.56 -.1.1.2.3.4.5.1.2.3.4.5 -.5-1 Bp Bt Btot Bp Bt Btot.5.4.3.2.1 1.55 1.54 1.53 1.52 1.51 B (T) R surf (m) The application of clearly shifts the flux reversal surface inward, as shown by observing the zero crossing of the toroidal magnetic field. Also, leads to an increase in the amount of magnetic sheer at the edge of the plasma. -1.5.1.2.3.4.5.1.2.3.4.5 1.5

resistivity H-S (ohm-m) eta*j 2 (W/m 3 ) 1-5 1-6 1-7 1-8 1.2 1 6 1 1 6 8 1 5 6 1 5 4 1 5 2 1 5 Calculated Profiles Ip~2 ka.1.2.3.4.5.1.2.3.4.5 Neoclassical effects become very important when modeling in 2D. Using Hirshman-Sigmar resistivity (rather than Spitzer) in "" reconstructions matches the measured and calculated ohmic input power with a conservative estimate of Zeff=2. I.e. No need of "anomalous" resistivty to account for MHD dynamo action. Normalizing to total input power shows that power deposition is enhanced in the edge during as compared to dischages at this current. etaj 2 /etaj 2 tot 3.5 3 2.5 2 1.5 1.5.1.2.3.4.5 3 1 6 4 P ohmic (W) 2.5 1 6 2 1 6 1.5 1 6 1 1 6 5 1 5 P ohmic ηj 2 dv.1.2.3.4.5 Stored Thermal Energy, W (J) 35 3 25 2 15 1 W 3 2 (n et e + n i T i )dv 5.1.2.3.4.5

resistivity H-S (ohm-m) eta*j 2 (W/m 3 ) 1-5 1-6 1-7 1-8 1.6 1 6 1.4 1 6 1.2 1 6 1 1 6 8 1 5 6 1 5 Calculated Profiles Ip~4 ka.1.2.3.4.5 Neoclassical effects become very important when modeling in 2D. Using Hirshman-Sigmar resistivity (rather than Spitzer) in "" reconstructions matches the measured and calculated ohmic input power with a conservative estimate of Zeff=2. I.e. No need of "anomalous" resistivty to account for MHD dynamo action. Normalizing to total input power shows that the power deposition profile is nearly identical during and dischages at this current. 2.5 2 4 1 5 2 1 5.1.2.3.4.5 etaj 2 /etaj 2 tot 1.5 1.5.1.2.3.4.5 5 1 6 1 1 4 4 1 6 8 P ohmic (W) 3 1 6 2 1 6 P ohmic ηj 2 dv 1 1 6.1.2.3.4.5 Stored Thermal Energy, W (J) 6 4 2 W 3 2 (n et e + n i T i )dv.1.2.3.4.5

2 ka Main Results 4 ka Pohmic 2.45 +/-.22 1.7 +/-.8 MW Pohmic 4.34 +/-.16 1.99 +/-.12 MW W 2. +/-.1 4.2 +/-.2 kjw 4.4 +/-.2 8.8 +/-.4 kj dw/dt 383.1 +/- 28.6 kwdw/dt 133.1 +/- 38.1 kw τe.81 +/-.1 6.45 +/- 1.28 ms βpol 6.36 +/-.33 13.28 +/-.66 % τe 1.2 +/-.7 4.83 +/-.65 ms βpol 3.29 +/-.11 7.52 +/-.38 % 1 E = W P ohmic W t 1 p = 1 V (n e T e + n i T i )dv 1 2 B p 2 1 1 X e (m 2 /s) 1 X e (m 2 /s) 1 1 1.1.1.2.3.4.5 1 HS j 2 3 dv + Χ e t 2 n e T e dv n e T e 4 2 5 R r 2 D meas. T e n e.1.1.2.3.4.5 D Class. = HS(n e T e + n i T i ) 2.5 m 2 / s for comparison: B tot T e D Bohm = 1 m 2 / s 16eB tot D meas.

Conclusions For the first time, 6 point profiles of T e have been measured during in the MST. Low Χ e in the edge is coincident with enhanced magnetic shear in the edge. During the flux surface where toroidal magnetic field reverses direction is forced inward (i.e. F is deepened), leading to a steepening of the q profile, particularly in the edge. It is unnecessary to invoke any anomalous resistivity during "standard" MST discharges if the fraction of trapped particles is taken into account, along with a neoclassical (as per Hirshman and Sigmar) assessment of resistivity. With a very reasonable estimation of Z eff =2 the reconstructed input power matches the measured input power. The energy confinement time greatly improves during, presumably due to the reduction of magnetic fluctuations.» τ E ~6 ms (if Z eff ~2) from 1 ms β p reaches 13% during low current. APS DPP 1999, UW-Madison, Plasma Physics November 16th, 1999 Seattle, WA