论文信息 - Hydrogen retention and carbon deposition in plasma facing components and the shadowed area of JT-60U

Hydrogen retention and carbon deposition in plasma facing components and the shadowed area of JT-60U

In JT-60U, erosion/deposition analyses of the plasma facing wall have shown that local carbon transport in the inboard direction was appreciable in addition to long-range transport. The total deposition and erosion rates in the divertor region were ∼1 × 1021 C atoms s−1 and ∼−6 × 1020 C atoms s−1, respectively. About 40% of the deposition in the divertor region likely originates from the main chamber wall. At the plasma facing surfaces of the divertor region, the highest hydrogen concentration in the (H + D)/C ratio and the retention amount were found to be ∼0.13 and ∼1 × 1023 atoms m−2, respectively. In the plasma-shadowed area underneath the divertor region with a vacuum vessel baking temperature of 420 K, redeposited layers of ∼2 µm thickness were found with a high hydrogen concentration of ∼0.75 in (H + D)/C, which was nearly the same level as that observed in JET. Large deuterium retention was also observed at the main chamber wall covered with boron layers. Their H + D retention and (H + D)/C were ∼1 × 1023 atoms m−2 and ∼0.16, respectively, for the vacuum vessel temperature of 570 K. Such a high deuterium retention is most likely caused by D retained in the boron layers. Nevertheless, the integration of this retention over the whole main chamber wall results in significant inventory and needs further investigation.

[1] K. Sugiyama,et al. Hydrogen isotope behavior in the first wall of JT-60U after deuterium plasma operation , 2007 .

[2] K. Krieger,et al. Ion beam analysis of H and D retention in the near surface layers of JT-60U plasma facing wall tiles , 2007 .

[3] Kenji Okuno,et al. Hydrogen isotopes retention in JT-60U , 2007 .

[4] H. Kubo,et al. Long-term erosion and re-deposition of carbon in the divertor region of JT-60U , 2006 .

[5] N. Asakura,et al. Thermal properties of redeposition layers in the JT-60U divertor region , 2006 .

[6] T. Hino,et al. Hydrogen isotope distributions and retentions in the inner divertor tile of JT-60U , 2005 .

[7] Y. Gotoh,et al. Retention of Hydrogen Isotopes in Divertor Tiles Used in JT-60U , 2005 .

[8] A. Sagara,et al. Characterization of dust collected from NSTX and JT-60U , 2005 .

[9] H. Hiratsuka,et al. Wall Conditioning and Experience of the Carbon-Based First Wall in JT-60U , 2002 .

[10] G. Matthews,et al. Erosion/Deposition Issues at JET , 2001 .

[11] D. Whyte,et al. Similarities in divertor erosion/redeposition and deuterium retention patterns between the tokamaks ASDEX Upgrade, DIII-D and JET , 1999 .

[12] A. T. Peacock,et al. Dust and flakes in the JET MkIIa divertor, analysis and results , 1999 .

[13] H. Takeuchi,et al. Ripple induced fast ion loss and related effects in JT-60U , 1995 .