A 20 MW/5GHz Lower Hybrid Current Drive (LHCD) system was initially due to be commissioned and used for the second mission of ITER, i.e. the Q=5 steady state target. Though not part of currently planned procurement phase, it is now under consideration for an earlier delivery. In this paper, both physics and technology conceptual designs are reviewed.
56 075020) is used to pave the way towards ITER divertor procurement and operation. It consists in implementing a divertor configuration and installing ITER-like actively cooled tungsten monoblocks in the Tore Supra tokamak, taking full benefit of its unique long-pulse capability. WEST is a user facility platform, open to all ITER partners. This paper describes the physics basis of WEST: the estimated heat flux on the divertor target, the planned heating schemes, the expected behaviour of the L-H threshold and of the pedestal and the potential W sources. A series of operating scenarios has been modelled, showing that ITER-relevant heat fluxes on the divertor can be achieved in WEST long pulse H-mode plasmas.
As a result of experimental observations of localized heat flux on components
magnetically connected to radiating waveguides in Tore Supra and in TdeV, the acceleration
of electrons near lower hybrid (LH) antennas has been investigated. A simple analytical model
has been developed to compute the dynamics of the particles in the near field approximation. Landau
damping of the very high N|| (20 < N|| < 100) component of the launched spectrum
on the thermal electrons of the scrape-off layer (SOL) is found to occur. Simulation of a typical LH pulse
in Tore Supra indicates that the electrons can be accelerated up to 2-3 keV. Modelling of the interaction of
this fast electron population with the edge plasma allows a calculation of the heat flux on plasma facing components
that are magnetically connected to the antenna. Model results and the results of experiments in Tore Supra and
TdeV are compared. The calculated heat fluxes are found to be fairly consistent when
the variation of convective heat flux at the grill aperture is taken into account. From this analysis, it is
concluded that, for an LH power density of 25 MW/m2, the resulting heat flux along the field lines
(3.5 MW/m2) is manageable for the components connected to the antenna, provided that good coupling can
be maintained at a low density in front of the grill.
The first EAST (Experimental Advanced Superconducting Tokamak) plasma ignited in 2006 with non-actively cooled steel plates as the plasma-facing materials and components (PFMCs) which were then upgraded into full graphite tiles bolted onto water-cooled copper heat sinks in 2008. The first wall was changed further into molybdenum alloy in 2012, while keeping the graphite for both the upper and lower divertors. With the rapid increase in heating and current driving power in EAST, the W/Cu divertor project was launched around the end of 2012, aiming at achieving actively cooled full W/Cu-PFCs for the upper divertor, with heat removal capability up to 10 MW m−2. The W/Cu upper divertor was finished in the spring of 2014, consisting of 80 cassette bodies toroidally assembled. Commissioning of the EAST upper W/Cu divertor in 2014 was unsatisfactory and then several practical measures were implemented to improve the design, welding quality and reliability, which helped us achieve successful commissioning in the 2015 Spring Campaign. In collaboration with the IO and CEA teams, we have demonstrated our technological capability to remove heat loads of 5000 cycles at 10 MW m−2 and 1000 cycles at 20 MW m−2 for the small scale monoblock mockups, and surprisingly over 300 cycles at 20 MW m−2 for the flat-tile ones. The experience and lessons we learned from batch production and commissioning are undoubtedly valuable for ITER (International Thermonuclear Experimental Reactor) engineering validation and tungsten-related plasma physics.
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