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In this paper we analyse and discuss the thermal energy loss dynamics before and during JET disruptions that
occurred between 2002 and 2004 in discharges which reached >4.5 MJ of thermal energy. We observe the slow
thermal energy transients with diamagnetic loops and the fast ones with electron cyclotron emission and soft x-ray
diagnostics. For most disruption types in JET, the plasma thermal energy at the time of the thermal quench is
substantially less than that of the full performance plasma, typically in the range of 10–50% depending on plasma
conditions and disruption type. The exceptions to this observation are disruptions in plasmas with a strong internal
transport barrier (ITB) and in discharges terminating in a pure vertical displacement event, in which the plasma
conserves a very high energy content up to the thermal quench. These disruption types are very sudden, leaving
little scope for the combined action of soft plasma landing strategies and intrinsic performance degradation, both
requiring >500 ms to be effective, to decrease the available thermal energy. The characteristic time for the loss of
energy from the main plasma towards the PFCs in the thermal quench of JET disruptions is in the range 0.05–3.0 ms.
The shortest timescales are typical of disruptions caused by excessive pressure peaking in ITB discharges. The
available thermal energy fraction and thermal quench duration observed in JET can be processed (with due caution)
into estimates for the projected PFC lifetime of the ITER target. |