Abstract
A review of experimental studies carried out at the NRC “Kurchatov Institute” on plasma-facing thermonuclear fusion reactor materials is presented in the paper. An experimental method was developed to produce high-level radiation damage in materials simulating the neutron effect by surrogate irradiation with high-energy ions. Plasma-surface interaction is investigated on materials irradiated to high levels of radiation damage in high-flux deuterium plasma. The total fluence of accelerated ions (3–30 MeV, 4He2+, 12C3+, 14N3+, protons) on the samples was 1021–1023 m−2. Experiments were carried out on graphite materials, tungsten, and silicon carbide. Samples have been obtained with a primary defect concentration from 0.1 to 100 displacements per atom, which covers the predicted damage for the ITER and DEMO projects. Erosion dynamics of the irradiated materials in steady-state deuterium plasma, changes of the surface microstructure, and deuterium retention were studied using SEM, TEM, ERDA, TDS, and nuclear backscattering techniques. The surface layer of the materials (3 to hundreds µm) was investigated, and it was shown that the changes in the crystal structure, the loss of their symmetry, and diffusion of defects to grain boundaries play an important role. The most significant results are presented in the paper as an overview of our previous work for many years (carbon and tungsten materials) as well as the relatively recent results (silicon carbide).
Highlights
Thermonuclear reactor based on deuterium-tritium (DT) fusion reaction is aimed to produce plasma with parameters providing high enough particle energy and density for the reaction to take place
The analysis showed that the production of defects in the material by fast protons induces important changes in the surface structure at plasma erosion regime
The experimental investigation of plasma-facing materials suggested for use in reactors with DT fusion reaction is presented in this review
Summary
Thermonuclear reactor based on deuterium-tritium (DT) fusion reaction is aimed to produce plasma with parameters providing high enough particle energy and density for the reaction to take place. Fission neutrons from a fast reactor may be taken In this case, a long irradiation time of about a oneyear-scale period is needed to accumulate radiation damage at a high enough level [4]. Charged particles accelerated to high energies present an efficient means for the production of displacement damage for a reasonable experimental time period at the levels being of interest for fusion research. This method is widely used in fusionoriented investigations [7,8,9,10,11,12,13,14].
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