% IMPORTANT: The following is UTF-8 encoded. This means that in the presence
% of non-ASCII characters, it will not work with BibTeX 0.99 or older.
% Instead, you should use an up-to-date BibTeX implementation like “bibtex8” or
% “biber”.
@ARTICLE{Seon:837025,
author = {Seon, C. R. and Song, I. and Jang, J. and Lee, H. Y. and
Jeon, T. M. and Lee, H. G. and Pak, S. and Cheon, M. S. and
Choi, J. H. and Biel, W. and Bernascolle, P. and Barnsley,
R. and Kim, B. S. and Kim, H. S. and Choe, W. and Park, J.
S. and An, Y. H. and Hong, J. H.},
title = {{VUV} spectroscopy in impurity injection experiments at
{KSTAR} using prototype {ITER} {VUV} spectrometer},
journal = {Review of scientific instruments},
volume = {88},
number = {8},
issn = {1089-7623},
address = {[S.l.]},
publisher = {American Institute of Physics},
reportid = {FZJ-2017-06041},
pages = {083511 -},
year = {2017},
abstract = {The ITER vacuum ultra-violet (VUV) core survey spectrometer
has been designed as a 5-channel spectral system so that the
high spectral resolving power of 200–500 could be achieved
in the wavelength range of 2.4–160 nm. To verify the
design of the ITER VUV core survey spectrometer, a
two-channel prototype spectrometer was developed. As a
subsequent step of the prototype test, the prototype VUV
spectrometer has been operated at KSTAR since the 2012
experimental campaign. From impurity injection experiments
in the years 2015 and 2016, strong emission lines, such as
Kr xxv 15.8 nm, Kr xxvi 17.9 nm, Ne vii 46.5 nm, Ne vi 40.2
nm, and an array of largely unresolved tungsten lines (14-32
nm) could be measured successfully, showing the typical
photon number of 1013–1015 photons/cm2 s.},
cin = {IEK-4},
ddc = {530},
cid = {I:(DE-Juel1)IEK-4-20101013},
pnm = {174 - Plasma-Wall-Interaction (POF3-174)},
pid = {G:(DE-HGF)POF3-174},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000409178100035},
doi = {10.1063/1.4998970},
url = {https://juser.fz-juelich.de/record/837025},
}
guest ::