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Spontaneous rotation in stellarator and tokamak

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1 Spontaneous rotation in stellarator and tokamak
K.Ida National Institute for Fusion Science 2nd Coordinated Working Group Meeting (CWGM) IPP Greifswald June 4-6, 2007 1 Spontaneous rotation in stellarator and tokamak Non-diffusive term of momentum transport driving the spontaneous rotation Parameter dependence of the non-diffusive term Physics mechanism of spontaneous rotation and comparison with theory. 5 Summary

2 Spontaneous rotation in tokamak and stellarator plasmas
JFT-2M tokamak (Er<0) Wendelstain 7AS (Er < 0) spontaneous rotation in co-direction spontaneous rotation in ctr-direction For NBI plasma where the radial electric field is negative (Er<0) Tokamak plasmas : vf (co)< vf (ctr) [PRL74 (1995) 1990] Helical plasmas : vf(co)> vf (ctr) [EPS 18B I (1994) p392] The direction of spontaneous flow is opposite between tokamak and helical plasmas

3 Experimental study of non-diffusive momentum transport
Co-NBI Parallel to Ip Ctr-NBI Anti-parallel Plasma current : Ip JFT-2M Non-diffusive momentum transport is studied by switching the NBI direction during the discharge in JFT-2M tokamak [PRL74 (1995) 1990]

4 Dynamic momentum transport analysis
Momentum transport analysis shows the non-diffusive term (finite momentum flux at zero gradient)

5 Spontaneous rotation in the momentum transport
Momentum Flux GM = mini[- cf dvf /dr + VinwardVf ] GM = mini[- mD dvf /dr + mN (vth /Ti)(eEr) ] eEr = dTi/dr diffusive (shear viscosity) non-diffusive (driving term) K.Nagashima, Nucl Fusion 34 (1994) 449] L=mode Plasma in JFT-2M K.Ida Phys Rev Lett 74 (1995 ) 1990 J.Phys.Soc.Jpn 67 (1998) 4089 Finite dVf/dr can be non-zero for GM = 0 because of the existence of non-diffusive term Spontaneous rotation was observed as a non-diffusive term of momentum transport.

6 Magnitude of non-diffusive viscosity (q-dependence)
Spontaneous flow B (small q) q Ctr-NBI Co-NBI f q Spontaneous flow B (large q) Ctr-NBI Co-NBI f The non-diffusive term is proportinal to q value in JFT-2M [J. Phys. Soc. Jpn 67 (1998) 4089] Similar q dependence is observed in Alcator C-mod Dvf ~ (Wp/Ip) [J.E.Rice NF 41 (2001) 277]

7 Momentum transport in helical system
GM = mini[- m^D dvf /dr + mN (vth /Ti)(eEr) - m|| vf ] Anomalous perpendicular viscosity Non-diffusive term Neoclassical parallel viscosity Small ripple configuration  Vmes << Vcal(NC) Large ripple configuration  Vmes ~ Vcal(NC) In the configuration of small ripple the anomalous perpendicular viscosity is dominant in the plasma core ( r < 0.6) even in helical plasmas

8 Spontaneous toroidal rotation in CHS
Mod-B Er > 0 ExB force <B> Er < 0 Co-NBI + ECH co-NBI B The spontaneous toridal flow driven by ECH is proportional to the poloidal flow (radial electric field)

9 Sign of non-diffusive viscosity
● Helical (external current system) vq helical effect poloidal Er <0 B Er >0 vf Helical symmetry toroidal ●Tokamaks (internal current system) vq toroidal effect Er < 0 poloidal B Toroidal symmetry PPCF 44 (2002) 361 Er >0 vf toroidal Tokamak : negative Er  counter spontaneous flow V=1.3Er/Bq Helical : positive Er  counter spontaneous flow V=0.16Er/Bq

10 Why the spontaneous rotation depends on Er in tokamak
Why the non-diffusivr terms has Er dependence? GM = mini[- mD dvf /dr + mN (vth /Ti)(eEr) ] = - (1/r)∫ff r dr Non-diffusive term can be expressed as toroidal force which proportional to Er shear mN = csym(1/Bq )= csymqR/(rBf) ffspon = (csymeqR/Bf)(vth/Ti)(1/r)(dEr/dr) ~ (csymeqRvth/Ti)(dwExB/dr) In tokamak Toroidal momentum is produced by symmetry breaking of non-zero <k||> ref PoP 14 (2007) In stellarator Because of the asymmetry of magnetic field, Er and spontaneous flow are produced by ripple loss too.

11 Summary 1 The spontaneous rotation as a result of off-diagonal term of transport has been observed in tokamak and stellarators. 2 The non-diffusive term has q(=1/i) dependence and Er(=dPi/dr) dependence as csymqR/(rBf) (vth /Ti)(eEr) This is equivalent to the The toroidal force driven by the ExB velocity shear as ffspon ~ (csymeqRvth/Ti)(dwExB/dr) 3 The sign of spontaneous flow is determined by Er and symmetry of B. Tokamak (and core in helical?) : toroidal symmetry (gB>gsym =0)  csym>0 ctr-rotation for Er < 0 Driving : Symmetry breaking + Er driven by turbulence  Reynolds stress Drag : anomalous perpendicular viscosity Helical: (additional mechanisms becomes important) helical symmetry (gB< gsym)  csym< 0 co-rotation for Er < 0 near the plasma edge Driving; Asymmetry of magnetic field + Er driven helical ripple  thermodynamic force Drag : neoclassical parallel (toroidal) viscosity

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