TY - JOUR
T1 - Investigation of H-mode density limit in mixed protium–deuterium plasmas at JET with ITER-like wall
AU - JET Contributors
AU - The EUROfusion Tokamak Exploitation Team
AU - Huber, A.
AU - Sergienko, G.
AU - Groth, M.
AU - Keeling, D.
AU - Wischmeier, M.
AU - Douai, D.
AU - Lerche, E.
AU - Perez von Thun, C.
AU - Brezinsek, S.
AU - Huber, V.
AU - Boboc, A.
AU - Brix, M.
AU - Carvalho, I. S.
AU - Chankin, A. V.
AU - Delabie, E.
AU - Jepu, I.
AU - Kachkanov, V.
AU - Kiptily, V.
AU - Kirov, K.
AU - Linsmeier, Ch
AU - Litherland-Smith, E.
AU - Lowry, C. G.
AU - Maggi, C. F.
AU - Mailloux, J.
AU - Meigs, A. G.
AU - Mertens, Ph
AU - Poradzinski, M.
AU - Zastrow, K. D.
AU - Zlobinski, M.
N1 - Publisher Copyright:
© 2024
PY - 2024/12
Y1 - 2024/12
N2 - Analysis of comparable discharges fuelled by either deuterium or protium reveals a clear relationship between the isotope mass and the H-mode density limit. Notably, the density limit is significantly lower in protium, showing a reduction of up to 35 % compared to identical deuterium plasma conditions. Within mixed H-mode density limit (HDL) plasmas, the maximum achievable density, or H-mode density limit, decreases with increasing protium concentration, denoted as cH. For instance, the highest corresponding maximum Greenwald fraction (fGW) of about 1.02 was observed in the pulse with the lowest cH value of 4.4 %. This fGW decreases to 0.96 at cH = 48 %. The average atomic mass, A¯, of the plasma species decreases in these pulses from the value of 1.96 (cH = 4.4 %) down to 1.52 (cH = 48 %). Interestingly, the maximum achievable density appears to be largely unaffected by the applied power value, regardless of whether deuterium or protium is used, as well as under mixed H/D fuelling conditions. Additionally, the measured Greenwald fractions are agreed with a heuristic model based on the SOL pressure threshold of an MHD instability, as proposed by Goldston. This comparison, especially concerning the model's dependence on isotopic mass, shows full consistency between the measured and predicted Greenwald fractions.
AB - Analysis of comparable discharges fuelled by either deuterium or protium reveals a clear relationship between the isotope mass and the H-mode density limit. Notably, the density limit is significantly lower in protium, showing a reduction of up to 35 % compared to identical deuterium plasma conditions. Within mixed H-mode density limit (HDL) plasmas, the maximum achievable density, or H-mode density limit, decreases with increasing protium concentration, denoted as cH. For instance, the highest corresponding maximum Greenwald fraction (fGW) of about 1.02 was observed in the pulse with the lowest cH value of 4.4 %. This fGW decreases to 0.96 at cH = 48 %. The average atomic mass, A¯, of the plasma species decreases in these pulses from the value of 1.96 (cH = 4.4 %) down to 1.52 (cH = 48 %). Interestingly, the maximum achievable density appears to be largely unaffected by the applied power value, regardless of whether deuterium or protium is used, as well as under mixed H/D fuelling conditions. Additionally, the measured Greenwald fractions are agreed with a heuristic model based on the SOL pressure threshold of an MHD instability, as proposed by Goldston. This comparison, especially concerning the model's dependence on isotopic mass, shows full consistency between the measured and predicted Greenwald fractions.
KW - Density limit
KW - Detachment
KW - Greenwald fraction
KW - H-mode
KW - ILW
KW - JET
UR - http://www.scopus.com/inward/record.url?scp=85208535268&partnerID=8YFLogxK
U2 - 10.1016/j.nme.2024.101806
DO - 10.1016/j.nme.2024.101806
M3 - Article
AN - SCOPUS:85208535268
SN - 2352-1791
VL - 41
JO - Nuclear Materials and Energy
JF - Nuclear Materials and Energy
M1 - 101806
ER -