Experiments in the JET tokamak equipped with the ITER-like wall (ILW) revealed that the inner
and outer target plate at the location of the strike points represent after one year of operation
intact tungsten (W) surfaces without any beryllium (Be) surface coverage. The dynamics of nearsurface retention, implantation, desorption and recycling of deuterium (D) in the divertor of
plasma discharges are determined by W target plates. As the W plasma-facing components
(PFCs) are not actively cooled, the surface temperature (Tsurface) is increasing with plasma
exposure, varying the balance between these processes in addition to the impinging deuteron
fluxes and energies. The dynamic behaviour on a slow time scale of seconds was quantified in a
series of identical L-mode discharges (JET Pulse Number (JPN) # - 81938 73) by intra-shot
gas analysis providing the reduction of deuterium retention in W PFCs by 1/3 at a base
temperature (Tbase) range at the outer target plate between 65 °C and 150 °C equivalent to a
Tsurface span of 150 °C and 420 °C. The associated recycling and molecular D desorption during
the discharge varies only at lowest temperatures moderately, whereas desorption between
discharges rises significantly with increasing Tbase. The retention measurements represent the
sum of inner and outer divertor interaction at comparable Tsurface. The dynamic behaviour on a
fast time scale of ms was studied in a series of identical H-mode discharges (JPN
# - 83623 83974) and coherent edge-localized mode (ELM) averaging. High energetic ELMs
of about 3 keV are impacting on the W PFCs with fluxes of 3 ´ 10 D s m 23 1 +- -2 which is about
four times higher than inter-ELM ion fluxes with an impact energy of about Eim = 200 eV. This
intra-ELM ion flux is associated with a high heat flux of about 60 MW m−2 to the outer target plate which causes Tsurface rise by Δ T = 100 K per ELM covering finally the range between
160 °C and 1400 °C during the flat-top phase. ELM-induced desorption from saturated nearsurface implantation regions as well as deep ELM-induced deuterium implantation areas under
varying baseline temperature takes place. Subsequent refuelling by intra-ELM deuteron fluxes
occurs and a complex interplay between deuterium fuelling and desorption can be observed in
the temporal ELM footprint of the surface temperature (IR thermography), the impinging
deuteron flux (Langmuir probes), and the Balmer radiation (emission spectroscopy) as
representative for the deuterium recycling flux. In contrast to JET-C, a pronounced second peak,
; 8 ms delayed with respect to the initial ELM crash, in the Dα radiation and the ion flux has
been observed. The peak can be related to desorption of implanted energetic intra-ELM D+
diffusing to the W surface, and performing local recycling.EURATOM 63305
