A linear empirical threshold condition ω E×B /γ ITG > 0.68s − 0.095 has been found for the onset of the ion internal transport barriers in the JET optimised shear database. Here, s is the magnetic shear, ω E×B the flow shearing rate and γ ITG is an approximate of the linear growth rate of the ion temperature gradient instability. The present empirical threshold condition for the ITB formation will provide a first clear indication of the strong correlation of s and ω E×B at the ITB transition. The empirical analysis consists of ITB discharges from a wide plasma parameter range; the toroidal magnetic field varies between 1.8-4.0 T, the auxiliary heating power between 10-30 MW and the diamagnetic energy between 3-12 MJ. The predictive simulations of several ITB discharges with the empirical ITB threshold condition reproduce the experiments with time averaged prediction errors of the order of 10-25% in T i and T e profiles and 10-15% in n e profiles as well as the toroidal flow velocity with errors of the order of 10-20%. The simulated times of the onset of the ITB compared to the experimental ones are typically within 0.4 s and the simulated ITB widths within 0.1 in r/a throughout the whole simulations.
The coexistence of stimulated Raman forward and backward scattering of intense electromagnetic radiation, which can occur, for instance, in laser fusion plasmas, is investigated. The simultaneous Raman forward and backward scattering is shown to create an electrostatic field structure which is exceptionally efficient in producing highly relativistic electrons. The mechanism of the electron acceleration is analyzed both by Vlasov-Maxwell simulations with self-consistent fields and by test particle calculations with prescribed electrostatic fields. The Vlasov-Maxwell simulations reveal that the two plasma waves generated by the backward and forward scattering are spatially separated, and thus form a two-stage electron "accelerator."
Parasitic absorption of the short wavelength modes of the LH
spectrum is a probable reason for the hot spots seen in the grill region of several tokamaks.
Experiments suggest that the heat loads on the wall structures depend on the coupled power.
In this work, the parasitic absorption of LH power was studied with self-consistent
particle-in-cell simulations. The launched spectra were obtained from the SWAN coupling
code. The power and temperature dependences of the absorption in the near field of the
LH grill were investigated with a series of simulations. The parasitic absorption was
found to grow from 0.6 to 1.1% when the coupled power increased from 26 to 67 MW/m2.
When the edge temperature rose from 12.5 to 100 eV, the absorption increased from
0.4 to 1.7%. The maximum kinetic energies were between 0.6 and 1.8 keV.
Estimates for the heat loads and surface temperature of the grill limiter are
also obtained. The absorption leads to heat loads between 1.5 and 13 MW/m2
and surface temperatures of 510-2390° C.
The recent success in coupling lower hybrid (LH) waves in high performance plasmas at JET together with the first demonstration on FTU of the coupling capability of the new passive active multijunction launcher removed major concerns on the possibility of using LH on ITER. LH exhibits the highest experimental current drive (CD) efficiency at low plasma temperature thus making it the natural candidate for off-axis CD on ITER where current profile control will help in maintaining burning performance on a long-time scale. We review recent LH results: long internal transport barrier obtained in JET with current profile sustained and controlled by LH acting under real time feedback together with first LH control of flat q-profile in a hybrid regime with T e ∼ T i . Minutes long fully non-inductive LH driven discharges on Tore Supra (TS). High CD efficiency with electron cyclotron in synergy with LH obtained in FTU and TS opening the possibility of interesting scenarii on ITER for MHD stabilization. Preliminary results of LH modelling for ITER are also reported. A brief overview of ITER LH system is reported together with some indication
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