The beryllium limiter experiment in ISX-B

Mioduszewski, P.K.; Edmonds, P.H.; Bush, C. E.; Carnevali, A.; Clausing, R.E.; Cook, T. B.; Emerson, L.C.; England, A.C.; Gabbard, W.A.; Heatherly, L.; Hutchinson, D. P.; Isler, R.C.; Kindsfather, R.R.; King, Philip; Langley, R.A.; Lazarus, E. A.; Ma, Chenhao; Murakami, M.; Neilson, G.H.; Roberto, J. B.; Simpkins, J. E.; Thomas, C. E.; Wootton, A. J.; Yokoyama, Kenji; Zuhr, R.A.; Behringer, K.; Dietz, J.; Källne, E.; Lomas, P.; Morgan, P. D.; Stott, P.E.; Tanga, A.; Sonnenberg, K.; Smith, Mark F.; Watkins, J.G.; Watson, R.D.; Whitley, J.B.; Goodall, Dominic; Peacock, N. J.; Clayton, R.; Seggern, J. von; Tschersich, K. G.

doi:10.1088/0029-5515/26/9/004

Cited by 44 publications

(9 citation statements)

References 22 publications

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“…However, beryllium has several negative features, including, a low melting temperature (1560 K), potential toxicity in manufacturing and relatively high physical sputtering rates. Nevertheless, two small tokamaks successfully tested beryllium (ISX-B [101], UNITOR [102]), and this led to extensive JET operation with beryllium limiters, divertor plates and evaporative gettering [100]. In fact, melting and evaporation of the beryllium limiters was extensive in all three cited tokamak experiments [100][101][102].…”

Section: Insert Tablementioning

confidence: 99%

“…Nevertheless, two small tokamaks successfully tested beryllium (ISX-B [101], UNITOR [102]), and this led to extensive JET operation with beryllium limiters, divertor plates and evaporative gettering [100]. In fact, melting and evaporation of the beryllium limiters was extensive in all three cited tokamak experiments [100][101][102]. One immediate and clearly beneficial effect of beryllium operation was the observation of strong oxygen gettering by the evaporated beryllium.…”

Section: Insert Tablementioning

confidence: 99%

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Plasma-material interactions in current tokamaks and their implications for next step fusion reactors

et al. 2001

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The major increase in discharge duration and plasma energy in a next step DT fusion reactor will give rise to important plasma-material effects that will critically influence its operation, safety and performance. Erosion will increase to a scale of several centimetres from being barely measurable at a micron scale in today's tokamaks. Tritium co-deposited with carbon will strongly affect the operation of machines with carbon plasma facing components. Controlling plasma-wall interactions is critical to achieving high performance in present day tokamaks, and this is likely to continue to be the case in the approach to practical fusion reactors. Recognition of the important consequences of these phenomena stimulated an internationally co-ordinated effort in the field of plasma-surface interactions supporting the Engineering Design Activities of the International Thermonuclear Experimental Reactor project (ITER), and significant progress has been made in better understanding these issues. The paper reviews the underlying physical processes and the existing experimental database of plasma-material interactions both in tokamaks and laboratory simulation facilities for conditions of direct relevance to next step fusion reactors. Two main topical groups of interaction are considered: (i) erosion/redeposition from plasma sputtering and disruptions, including dust and flake generation and (ii) tritium retention and removal. The use of modelling tools to interpret the experimental results and make projections for conditions expected in future devices is explained. Outstanding technical issues and specific recommendations on potential R&D avenues for their resolution are presented.

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confidence: 99%

Section: Insert Tablementioning

confidence: 99%

Plasma-material interactions in current tokamaks and their implications for next step fusion reactors

et al. 2001

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“…The droplets may or may not break up during their trajectory through the plasma although it appears that many droplets do break up [6]. (2) The mean diameter of the elongated droplets is 1 mm, and their corresponding mass, m, is 2 mg. (3) The effective length, L, for the current path is 10 mm. (4) The horizontal protrusion movement before detachment is 5 mm.…”

Section: Modelmentioning

confidence: 99%

“…This experiment was a collaborative effort involving both ORNL and JET personnel. The beryllium limiter has been described and discussed elsewhere [1,2], as have the plasma physics results [2,3], the movement of beryllium on the limiter [4,5], and the migration of beryllium to the tokamak walls [4,6].…”

Section: Introductionmentioning

confidence: 99%