Shear modulation experiments with ECCD on TCV

Anomalous electron transport is determined by turbulence, which in turn is affected by magnetic shear. A novel application of electron cyclotron current drive (ECCD), aiming at localized shear modulation, has been applied on the TCV tokamak for experiments on shear-dependent electron transport. Pairs of EC beams, absorbed at the same radius, with one oriented for co- and the other for counter-injection, are modulated out of phase in order to force a local modulation of current-density at constant input power. Off-axis deposition (rho(dep) = 0.24) is performed to avoid the central region, where the low heat flux would make transport analysis difficult. In addition some sawteeth control is achieved in this way. A significant impact on local shear is achieved with I-ECCD approximate to 0. 1 I-OH, even when the modulation period is much shorter than the current diffusion time across the whole plasma radius. The main result is that although source (heat and particle) terms are constant, both electron density and temperature are modulated during alternated ECCD. Once equilibrium effects are taken into account for appropriate mapping of Thomson scattering measurements onto flux coordinates, modulation of T-e and electron pressure, peaked on-axis, is confirmed at all radii internal to EC deposition. The best confinement occurs for co-injection, in which case a local decrease (approximate to 55%) in the magnetic shear causes a decrease in the electron thermal diffusivity of a similar amount (approximate to 65%).

Influence of non-Maxwellian velocity distributions during ECRH and ECCD on electron temperature measurements by Thomson scattering

Roland Behn, Igor Klimanov, Petri Nikkola, Olivier Sauter

Deposition of electron cyclotron waves at high-power densities for heating and current drive in a tokamak plasma generates a population of fast electrons and therefore the velocity distribution of the electron population will deviate from a Maxwellian. Apart from the formation of a high energy tail, modifications to the low-energy part of the distribution function have also been observed. This may have consequences for electron temperature measurements by incoherent Thomson scattering, which usually assumes a Maxwellian distribution function to interpret the scattered light spectrum. In order to investigate and quantify such perturbations, a few typical cases of electron cyclotron heating (ECH) and current drive (ECCD) experiments on the Tokamak a Configuration Variable (TCV) have been analysed in detail. The experimental results from the TCV Thomson scattering system have been compared with simulated data assuming different velocity distribution functions. These were obtained either as results of numerical modelling, using the Fokker-Planck code CQL3D, or in the form of a model bi-Maxwellian distribution function based on information from electron cyclotron emission measurements. In some of the investigated cases the deviations from an ideal Maxwellian were significant and systematic errors in the T-e measurements from Thomson scattering could be identified. In particular, for a case with an injected power of 1.35 MW for ECCD, the discrepancies in T, measurements based on different parts of the scattered light spectrum, i.e. different electron velocity classes, were found to be as large as 25-30%. The use of a bi-Maxwellian model distribution function with three free parameters has permitted us to identify the parameter range in which systematic errors exceed the experimental uncertainties of Thomson scattering measurements on TCV.

2005

Reconstruction of the electron distribution function during ECRH/ECCD and magnetic reconnection events in a tokamak plasma

Igor Klimanov

The performance of tokamaks is usually described in terms of plasma temperature, density and confinement time. The term temperature implies that the plasma is in thermal equilibrium and its particles have maxwellian (normal) velocity distribution. However, in several conditions, the plasma contains a significant number of suprathermal or 'fast' particles, whose energy is several times higher than thermal energy. The number of such particles can be significantly higher than that corresponding to the maxwellian distribution. Such electrons produced by different acceleration mechanisms in the TCV tokamak have been analyzed in the course of this thesis. This thesis consists of three parts. The first part describes the design, construction and implementation of a new 24-channel Electron Cyclotron Emission (ECE) radiometer, viewing the plasma from the Low Field Side (LFS) in the frequency range 65-100 GHz. The new LFS ECE radiometer, together with the existing 24-channel ECE radiometer viewing the plasma from the High Field Side (HFS) in the frequency range 78-114 GHz are the main diagnostics used in the analysis. The second part includes the development of a numerical code to simulate the ECE signals. The code is based on the WKB approach and solves the equation of radiation transport to calculate ECE signals using a numerically defined Electron Distribution Function (EDF). A method to reconstruct EDF from HFS and LFS ECE, based on the ECE code, is presented. The third part discusses the experimental data obtained on the TCV tokamak. In regimes with Electron Cyclotron Current Drive (ECCD), a quantitative explanation of the anomalously high absorption of the RF power at 118 GHz and a validation of the power balance analysis based on Thomson scattering measurements are provided. An analysis of the EDF during sawtooth instability shows that suprathermal electrons are generated in ohmic, Electron Cyclotron Heated (ECH) and ECCD plasmas. In ECH plasmas, typical energies and densities are found to be E = 15–30 keV and nst = 2·1017 m–3. This corresponds to 30-40 % of the energy lost during the crash, which proves that acceleration of electrons is an important mechanism for the dissipation of energy released during magnetic reconnection in a tokamak plasma. The observed fast electron dynamics suggests a high radial diffusion in the plasma during and just after the sawtooth crash (Dst = 25 m2/s), which dominates over the classical slowing down process.

EPFL2006

Influence of non-Maxwellian velocity distributions during ECRH and ECCD on electron temperature measurements by Thomson scattering

Roland Behn, Igor Klimanov, Petri Nikkola, Olivier Sauter

2005

Reconstruction of the electron distribution function during ECRH/ECCD and magnetic reconnection events in a tokamak plasma

Igor Klimanov

EPFL2006