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@ARTICLE{Wang:904083,
author = {Wang, L. and Xu, G. S. and Hu, J. S. and Li, K. D. and
Yuan, Q. P. and Liu, Jianwen and Ding, F. and Yu, Y. W. and
Luo, Z. P. and Xu, J. C. and Meng, L. Y. and Wu, K. and
Zhang, B. and Chen, M. W. and Deng, G. Z. and Liu, X. J. and
Yang, Z. S. and Liu, X. and Liu, S. C. and Ding, R. and Zuo,
G. Z. and Sun, Z. and Wu, J. H. and Cao, B. and Zhang, Y.
and Duan, Y. M. and Zhang, L. and Qian, X. Y. and Li, A. and
Chen, L. and Jia, M. N. and Si, H. and Xia, T. Y. and Sun,
Y. W. and Chen, Y. P. and Li, Q. and Luo, G. N. and Yao, D.
M. and Xiao, B. J. and Gong, X. Z. and Zhang, X. D. and Wan,
B. N. and Wang, H. Q. and Guo, H. Y. and Eldon, D. and
Garofalo, A. M. and Liang, Yunfeng and Xu, Shuai and Sang,
C. F. and Wang, D. Z. and Dai, S. Y. and Sun, J. Z. and
Ding, H. B. and Maingi, R. and Gan, K. F. and Zou, X. L. and
Du, H. L.},
title = {{P}rogress of {D}ivertor {H}eat and {P}article {F}lux
{C}ontrol in {EAST} for {A}dvanced {S}teady-{S}tate
{O}peration in the {L}ast 10 {Y}ears},
journal = {Journal of fusion energy},
volume = {40},
number = {1},
issn = {0164-0313},
address = {New York, NY},
publisher = {Springer Science + Business Media B.V.},
reportid = {FZJ-2021-05653},
pages = {3},
year = {2021},
note = {kein Zugriff auf Postprint},
abstract = {Active control of the excessively high heat and particle
fluxes on the divertor target plates is of fundamental
importance to the steady state operation of tokamaks,
especially for fusion reactors. A series of experiments have
been carried out on this critical issue to relieve the
plasma-wall interactions in the experimental advanced
superconducting tokamak (EAST) in the last ten years, not
only contributing to the long pulse operation of EAST
itself, but also providing physical understandings and
potential techniques to the next-generation devices like
ITER. We have characterized the power deposition pattern and
broadened the divertor footprint width effectively. The
plasma-wetted area is actively handled using either
3-dimentional edge magnetic topology or advanced plasma
equilibrium, thereby peak heat flux around the strike point
is reduced. Active control of detachment or radiation
compatible with core plasma performance has progressed
significantly in very recent years, with a series of active
feedback control modules developed and utilized
successfully, based on the divertor physics advances with
both experiments and simulation. The upper divertor of EAST
was upgraded from graphite to active water-cooling ITER-like
tungsten in 2014, exhibiting much enhanced heat removal
capability. As for the particle exhaust including both
fueling and impurity particles, in addition to wall
conditioning and impurity source control, the efficiency of
particle flux exhaust is optimized by making full use of the
divertor closure and the plasma drifts in both scrape-off
layer and divertor volume. These heat and particle exhaust
advances contribute greatly to a series of EAST achievements
like H-mode operation over 100 s. A brief near-term plan on
the integrated control of divertor plasma-wall interactions
in long-time scale will also be introduced, aiming to
provide favorable divertor operation solution for ITER and
CFETR.},
cin = {IEK-4},
ddc = {530},
cid = {I:(DE-Juel1)IEK-4-20101013},
pnm = {134 - Plasma-Wand-Wechselwirkung (POF4-134)},
pid = {G:(DE-HGF)POF4-134},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000636746300001},
doi = {10.1007/s10894-021-00290-9},
url = {https://juser.fz-juelich.de/record/904083},
}
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