G.R. Longhurst scite author profile

Invited Review Paper -R2 CEI SUN 3 0 O S T ITritium retention inside the vacuum vessel has emerged as a potentially serious constraint in the operation of the International Thermonuclear Experimental Reactor (ITER). In this paper we review recent tokamak and laboratory data on hydrogen, deuterium and tritium retention for materials and conditions which are of direct relevance to the design of ITER. These data, together with significant advances in understanding the underlying physics, provide the basis for modelling predictions of the tritium inventory in ITER.We present the derivation, and discuss the results, of current predictions both in terms of implantation and codeposition rates, and critically discuss their uncertainties and sensitivity to important design and operation parameters such as the plasma edge conditions, the surface temperature, the presence of mixed-materials, etc. These analyses are consistent with recent tokamak findings and show that codeposition of tritium occurs on the divertor surfaces primarily with carbon eroded from a limited area of the divertor near the strike zones. This issue remains an area of serious concern for ITER. The calculated codeposition rates for ITER are relatively high and the in-vessel tritium inventory limit could be reached, under worst assumptions, in approximately a week of continuous operation.We discuss the implications of these estimates on the design, operation and safety of ITER and present a strategy for resolving the issues. We conclude that as long as carbon is used in ITER, the efficient control and removal of the codeposited tritium is essential. There is a critical need to develop and test in-situ cleaning techniques and procedures that are beyond the current experience of present-day tokamaks. We review some of the principal methods that are being investigated and tested, in conjunction with the R&D work still required to extrapolate their applicability to ITER. Finally, unresolved issues are identified and recommendations are made on potential R&D avenues for their resolution.

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Deuterium Transport and Trapping in Polycrystalline Tungsten

Anderl

et al. 1992

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Storage and Assay of Tritium in STAR

Longhurst¹

2005

Fusion Sci. Technol

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Hydrogen isotope retention in beryllium for tokamak plasma-facing applications

Anderl

Causey

Davis

et al. 1999

Journal of Nuclear Materials

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G.R. Longhurst

The ARIES-AT advanced tokamak, Advanced technology fusion power plant

In-vessel tritium retention and removal in ITER

Deuterium Transport and Trapping in Polycrystalline Tungsten

Storage and Assay of Tritium in STAR

Hydrogen isotope retention in beryllium for tokamak plasma-facing applications

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