Fuel retention in impurity seeded discharges in JET after Be evaporation

S. Brezinsek; T. Loarer; K. Krieger; S. Jachmich; M. Tsalas; I. Coffey; H. G. Esser; T. Eich; W. Fundamenski; C. Giroud; S. Grünhagen; A. Huber; U. Kruezi; S. Knipe; G. P. Maddison; K. McCormick; A. G. Meigs; Ph Morgan; V. Philipps; G. Sergienko; R. Stagg; M. F. Stamp; F. L. Tabares

doi:10.1088/0029-5515/51/7/073007

Fuel retention in impurity seeded discharges in JET after Be evaporation

S. Brezinsek
, T. Loarer
, K. Krieger
, S. Jachmich
, M. Tsalas
, I. Coffey
, H. G. Esser
, T. Eich
, W. Fundamenski
, C. Giroud
, S. Grünhagen
, A. Huber
, U. Kruezi
, S. Knipe
, G. P. Maddison
, K. McCormick
, A. G. Meigs
, Ph Morgan
, V. Philipps
, G. Sergienko

R. Stagg, M. F. Stamp, F. L. Tabares

Laboratory for Plasma Physics

FORSCHUNGSZENTRUM JULICH GMBH
Commissariat à l'Énergie Atomique (CEA)
Max-Planck-Institut für Plasmaphysik
Association EURATOM-Hellenic Republic
Culham Centre for Fusion Energy
Laboratorio Nacional de Fusión

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

18 Zitate (Scopus)

Abstract

Preparatory experiments for the ITER-Like Wall in JET were carried out to simulate the massive Be first wall by a thin Be layer, induced by evaporation of about 2.0 g Be, and to study its impact on fuel retention and divertor radiation with reduced C content and N seeding. Residual gas analysis reveals a reduction of hydrocarbons by one order of magnitude and of O by a factor of 5 in the partial pressure owing to the evaporation. The evolution of wall conditions, impurity fluxes and divertor radiation have been studied in ELMy H-mode plasmas (B_t = 2.7 T, I_p = 2.5 MA, P_aux = 16 MW) whereas a non-seeded reference discharge was executed prior to the evaporation. The in situ measured Be flux at the midplane increased by about a factor of 40 whereas the C flux decreased by ∼50% in the limiter phase of the first discharge with respect to the reference, but erosion of the Be layer and partial coverage with C takes place quickly. To make best use of the protective Be layer, only the first four discharges were employed for a gas balance analysis providing a D retention rate of 1.94 × 10²¹ D s^-1 which is comparable to rates with C walls. But the Be evaporation provides a non-saturated surface with respect to D and short term retention is not negligible in the balance; the measured retention is overestimated with respect to steady-state conditions like that of the ILW. Moreover, C was only moderately reduced and co-deposition of fuel with eroded Be and C occurs. The lower C content leads to a minor reduction in divertor radiation as the reference phase prior to seeding indicates. N adds to the radiation of D and the remaining C, and the N content rises due to the legacy effect which has been quantified by gas balance to be 30% of the injected N. C radiation increases with exposure time, and both contributors cause an increase in the radiated fraction in the divertor from 50% to 70%. The radiation pattern suggests that N dominates the increase in the first discharges though C is still the dominating radiator. Therefore, the validity of a proxy of the Be first wall by a thin Be layer is limited and restricted to plasma operation directly after the Be evaporation.

Originalsprache	Englisch
Aufsatznummer	073007
Fachzeitschrift	Nuclear Fusion
Jahrgang	51
Ausgabenummer	7
DOIs	https://doi.org/10.1088/0029-5515/51/7/073007
Publikationsstatus	Veröffentlicht - Juli 2011

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10.1088/0029-5515/51/7/073007

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Brezinsek, S., Loarer, T., Krieger, K., Jachmich, S., Tsalas, M., Coffey, I., Esser, H. G., Eich, T., Fundamenski, W., Giroud, C., Grünhagen, S., Huber, A., Kruezi, U., Knipe, S., Maddison, G. P., McCormick, K., Meigs, A. G., Morgan, P., Philipps, V., ... Tabares, F. L. (2011). Fuel retention in impurity seeded discharges in JET after Be evaporation. Nuclear Fusion, 51(7), Artikel 073007. https://doi.org/10.1088/0029-5515/51/7/073007

@article{fe3c35a37da044d18e058e43ec292991,

title = "Fuel retention in impurity seeded discharges in JET after Be evaporation",

abstract = "Preparatory experiments for the ITER-Like Wall in JET were carried out to simulate the massive Be first wall by a thin Be layer, induced by evaporation of about 2.0 g Be, and to study its impact on fuel retention and divertor radiation with reduced C content and N seeding. Residual gas analysis reveals a reduction of hydrocarbons by one order of magnitude and of O by a factor of 5 in the partial pressure owing to the evaporation. The evolution of wall conditions, impurity fluxes and divertor radiation have been studied in ELMy H-mode plasmas (Bt = 2.7 T, Ip = 2.5 MA, Paux = 16 MW) whereas a non-seeded reference discharge was executed prior to the evaporation. The in situ measured Be flux at the midplane increased by about a factor of 40 whereas the C flux decreased by ∼50\% in the limiter phase of the first discharge with respect to the reference, but erosion of the Be layer and partial coverage with C takes place quickly. To make best use of the protective Be layer, only the first four discharges were employed for a gas balance analysis providing a D retention rate of 1.94 × 1021 D s-1 which is comparable to rates with C walls. But the Be evaporation provides a non-saturated surface with respect to D and short term retention is not negligible in the balance; the measured retention is overestimated with respect to steady-state conditions like that of the ILW. Moreover, C was only moderately reduced and co-deposition of fuel with eroded Be and C occurs. The lower C content leads to a minor reduction in divertor radiation as the reference phase prior to seeding indicates. N adds to the radiation of D and the remaining C, and the N content rises due to the legacy effect which has been quantified by gas balance to be 30\% of the injected N. C radiation increases with exposure time, and both contributors cause an increase in the radiated fraction in the divertor from 50\% to 70\%. The radiation pattern suggests that N dominates the increase in the first discharges though C is still the dominating radiator. Therefore, the validity of a proxy of the Be first wall by a thin Be layer is limited and restricted to plasma operation directly after the Be evaporation.",

author = "S. Brezinsek and T. Loarer and K. Krieger and S. Jachmich and M. Tsalas and I. Coffey and Esser, \{H. G.\} and T. Eich and W. Fundamenski and C. Giroud and S. Gr{\"u}nhagen and A. Huber and U. Kruezi and S. Knipe and Maddison, \{G. P.\} and K. McCormick and Meigs, \{A. G.\} and Ph Morgan and V. Philipps and G. Sergienko and R. Stagg and Stamp, \{M. F.\} and Tabares, \{F. L.\}",

year = "2011",

month = jul,

doi = "10.1088/0029-5515/51/7/073007",

language = "English",

volume = "51",

journal = "Nuclear Fusion",

issn = "0029-5515",

number = "7",

}

Brezinsek, S, Loarer, T, Krieger, K, Jachmich, S, Tsalas, M, Coffey, I, Esser, HG, Eich, T, Fundamenski, W, Giroud, C, Grünhagen, S, Huber, A, Kruezi, U, Knipe, S, Maddison, GP, McCormick, K, Meigs, AG, Morgan, P, Philipps, V, Sergienko, G, Stagg, R, Stamp, MF & Tabares, FL 2011, 'Fuel retention in impurity seeded discharges in JET after Be evaporation', Nuclear Fusion, Jg. 51, Nr. 7, 073007. https://doi.org/10.1088/0029-5515/51/7/073007

TY - JOUR

T1 - Fuel retention in impurity seeded discharges in JET after Be evaporation

AU - Brezinsek, S.

AU - Loarer, T.

AU - Krieger, K.

AU - Jachmich, S.

AU - Tsalas, M.

AU - Coffey, I.

AU - Esser, H. G.

AU - Eich, T.

AU - Fundamenski, W.

AU - Giroud, C.

AU - Grünhagen, S.

AU - Huber, A.

AU - Kruezi, U.

AU - Knipe, S.

AU - Maddison, G. P.

AU - McCormick, K.

AU - Meigs, A. G.

AU - Morgan, Ph

AU - Philipps, V.

AU - Sergienko, G.

AU - Stagg, R.

AU - Stamp, M. F.

AU - Tabares, F. L.

PY - 2011/7

Y1 - 2011/7

N2 - Preparatory experiments for the ITER-Like Wall in JET were carried out to simulate the massive Be first wall by a thin Be layer, induced by evaporation of about 2.0 g Be, and to study its impact on fuel retention and divertor radiation with reduced C content and N seeding. Residual gas analysis reveals a reduction of hydrocarbons by one order of magnitude and of O by a factor of 5 in the partial pressure owing to the evaporation. The evolution of wall conditions, impurity fluxes and divertor radiation have been studied in ELMy H-mode plasmas (Bt = 2.7 T, Ip = 2.5 MA, Paux = 16 MW) whereas a non-seeded reference discharge was executed prior to the evaporation. The in situ measured Be flux at the midplane increased by about a factor of 40 whereas the C flux decreased by ∼50% in the limiter phase of the first discharge with respect to the reference, but erosion of the Be layer and partial coverage with C takes place quickly. To make best use of the protective Be layer, only the first four discharges were employed for a gas balance analysis providing a D retention rate of 1.94 × 1021 D s-1 which is comparable to rates with C walls. But the Be evaporation provides a non-saturated surface with respect to D and short term retention is not negligible in the balance; the measured retention is overestimated with respect to steady-state conditions like that of the ILW. Moreover, C was only moderately reduced and co-deposition of fuel with eroded Be and C occurs. The lower C content leads to a minor reduction in divertor radiation as the reference phase prior to seeding indicates. N adds to the radiation of D and the remaining C, and the N content rises due to the legacy effect which has been quantified by gas balance to be 30% of the injected N. C radiation increases with exposure time, and both contributors cause an increase in the radiated fraction in the divertor from 50% to 70%. The radiation pattern suggests that N dominates the increase in the first discharges though C is still the dominating radiator. Therefore, the validity of a proxy of the Be first wall by a thin Be layer is limited and restricted to plasma operation directly after the Be evaporation.

AB - Preparatory experiments for the ITER-Like Wall in JET were carried out to simulate the massive Be first wall by a thin Be layer, induced by evaporation of about 2.0 g Be, and to study its impact on fuel retention and divertor radiation with reduced C content and N seeding. Residual gas analysis reveals a reduction of hydrocarbons by one order of magnitude and of O by a factor of 5 in the partial pressure owing to the evaporation. The evolution of wall conditions, impurity fluxes and divertor radiation have been studied in ELMy H-mode plasmas (Bt = 2.7 T, Ip = 2.5 MA, Paux = 16 MW) whereas a non-seeded reference discharge was executed prior to the evaporation. The in situ measured Be flux at the midplane increased by about a factor of 40 whereas the C flux decreased by ∼50% in the limiter phase of the first discharge with respect to the reference, but erosion of the Be layer and partial coverage with C takes place quickly. To make best use of the protective Be layer, only the first four discharges were employed for a gas balance analysis providing a D retention rate of 1.94 × 1021 D s-1 which is comparable to rates with C walls. But the Be evaporation provides a non-saturated surface with respect to D and short term retention is not negligible in the balance; the measured retention is overestimated with respect to steady-state conditions like that of the ILW. Moreover, C was only moderately reduced and co-deposition of fuel with eroded Be and C occurs. The lower C content leads to a minor reduction in divertor radiation as the reference phase prior to seeding indicates. N adds to the radiation of D and the remaining C, and the N content rises due to the legacy effect which has been quantified by gas balance to be 30% of the injected N. C radiation increases with exposure time, and both contributors cause an increase in the radiated fraction in the divertor from 50% to 70%. The radiation pattern suggests that N dominates the increase in the first discharges though C is still the dominating radiator. Therefore, the validity of a proxy of the Be first wall by a thin Be layer is limited and restricted to plasma operation directly after the Be evaporation.

UR - https://www.scopus.com/pages/publications/79960363468

U2 - 10.1088/0029-5515/51/7/073007

DO - 10.1088/0029-5515/51/7/073007

M3 - Article

AN - SCOPUS:79960363468

SN - 0029-5515

VL - 51

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 7

M1 - 073007

ER -

Fuel retention in impurity seeded discharges in JET after Be evaporation

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