Wall conditions in WEST during operations with a new ITER grade, actively cooled divertor

A. Gallo; Ph Moreau; D. Douai; T. Alarcon; K. Afonin; V. Anzallo; R. Bisson; J. Bucalossi; E. Caprin; Y. Corre; M. De Combarieu; C. Desgranges; P. Devynck; A. Ekedahl; N. Fedorczak; J. Gaspar; A. Grosjean; C. Guillemaut; R. Guirlet; J. P. Gunn; J. Hillairet; T. Loarer; P. Maget; P. Manas; J. Morales; F. P. Pellissier; E. Tsitrone; K. Krieger; A. Hakola; A. Widdowson

doi:10.1016/j.nme.2024.101741

Wall conditions in WEST during operations with a new ITER grade, actively cooled divertor

A. Gallo, Ph Moreau, D. Douai, T. Alarcon, K. Afonin, V. Anzallo, R. Bisson, J. Bucalossi, E. Caprin, Y. Corre, M. De Combarieu, C. Desgranges, P. Devynck, A. Ekedahl, N. Fedorczak, J. Gaspar, A. Grosjean, C. Guillemaut, R. Guirlet, J. P. GunnJ. Hillairet, T. Loarer, P. Maget, P. Manas, J. Morales, F. P. Pellissier, E. Tsitrone, K. Krieger, A. Hakola, A. Widdowson

BA4511 Fusion energy

Research output: Contribution to journal › Article › Scientific › peer-review

11 Citations (Scopus)

Abstract

Future fusion reactors like ITER and DEMO will have all-tungsten (W) walls and long pulses. These features will make wall conditioning more difficult than in most of the existing devices. The W Environment Steady-state Tokamak (WEST) is one of the few long pulse (364 s) fusion devices with actively cooled W plasma-facing components in the world. WEST is a unique test bed to study impurity migration and plasma density control via reactor relevant wall conditioning techniques. The phase II of WEST operations began in 2022, after the installation of a new lower divertor, now entirely equipped with actively cooled, ITER grade, W monoblocks. After pump down, we baked WEST between 90 °C and 170 °C for ∼2 weeks. After 82.5 h at 90 °C and 33 h at 170 °C, vacuum conditions were stable with a vessel pressure of 6x10-5 Pa and mass spectra dominated by H2 molecules. While at 170 °C, we performed ∼40 h of D2 glow discharge cleaning (GDC) and ∼5 h of glow discharge boronization (GDB), using a 15 %-85 % B2D6-He mix and a total boron mass of ∼12 g. This was the very first GDB at such high temperature for WEST. The whole wall conditioning sequence led to a ∼10 times reduction of the H2O signal as well as to a ∼3 times reduction of the O2 signal, according to mass spectra. Once back to 70 °C, the vessel pressure was 5.5x10-6 Pa and plasma restart was seamless with ∼30 s cumulated over the very first 5 pulses and an Ohmic radiated power fraction Frad = 0.6, showing successful conditioning of the new ITER grade divertor. The effect of the first, ‘hot’ GDB faded with a characteristic cumulative injected energy of 2.45 GJ and saturation towards Frad ∼0.8. After 1.4 h and 7.5 GJ of cumulative plasma time and injected energy, we carried out a second GDB, this time at 70 °C. This ‘cold’ GDB initially led to a much lower Ohmic Frad = 0.3–0.4 but the effect lasted ∼7 times less, with a characteristic cumulative injected energy of 0.37 GJ. At the end of the campaign, we cumulated ∼3h and ∼30 GJ through repetitive, minute long pulses without any boronization. Throughout this 4-weeks-long experiment, Frad in the 4 MW heating phase evolved only marginally (from 0.5 to 0.55). This increase is mostly due to the build-up of re/co-deposited layers on both lower divertor targets.

Original language	English
Article number	101741
Journal	Nuclear Materials and Energy
Volume	41
DOIs	https://doi.org/10.1016/j.nme.2024.101741
Publication status	Published - Dec 2024
MoE publication type	A1 Journal article-refereed

Funding

This work has been carried out within the framework of the EUROfusion Consortium, funded by the European Union via the Euratom Research and Training Programme (Grant Agreement No 101052200 \u2014 EUROfusion). Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Commission. Neither the European Union nor the European Commission can be held responsible for them.

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.nme.2024.101741

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Gallo, A., Moreau, P., Douai, D., Alarcon, T., Afonin, K., Anzallo, V., Bisson, R., Bucalossi, J., Caprin, E., Corre, Y., De Combarieu, M., Desgranges, C., Devynck, P., Ekedahl, A., Fedorczak, N., Gaspar, J., Grosjean, A., Guillemaut, C., Guirlet, R., ... Widdowson, A. (2024). Wall conditions in WEST during operations with a new ITER grade, actively cooled divertor. Nuclear Materials and Energy, 41, Article 101741. https://doi.org/10.1016/j.nme.2024.101741

@article{96e8f68aaa9d44fcb6bd8124cd985d8d,

title = "Wall conditions in WEST during operations with a new ITER grade, actively cooled divertor",

abstract = "Future fusion reactors like ITER and DEMO will have all-tungsten (W) walls and long pulses. These features will make wall conditioning more difficult than in most of the existing devices. The W Environment Steady-state Tokamak (WEST) is one of the few long pulse (364 s) fusion devices with actively cooled W plasma-facing components in the world. WEST is a unique test bed to study impurity migration and plasma density control via reactor relevant wall conditioning techniques. The phase II of WEST operations began in 2022, after the installation of a new lower divertor, now entirely equipped with actively cooled, ITER grade, W monoblocks. After pump down, we baked WEST between 90 °C and 170 °C for ∼2 weeks. After 82.5 h at 90 °C and 33 h at 170 °C, vacuum conditions were stable with a vessel pressure of 6x10-5 Pa and mass spectra dominated by H2 molecules. While at 170 °C, we performed ∼40 h of D2 glow discharge cleaning (GDC) and ∼5 h of glow discharge boronization (GDB), using a 15 \%-85 \% B2D6-He mix and a total boron mass of ∼12 g. This was the very first GDB at such high temperature for WEST. The whole wall conditioning sequence led to a ∼10 times reduction of the H2O signal as well as to a ∼3 times reduction of the O2 signal, according to mass spectra. Once back to 70 °C, the vessel pressure was 5.5x10-6 Pa and plasma restart was seamless with ∼30 s cumulated over the very first 5 pulses and an Ohmic radiated power fraction Frad = 0.6, showing successful conditioning of the new ITER grade divertor. The effect of the first, {\textquoteleft}hot{\textquoteright} GDB faded with a characteristic cumulative injected energy of 2.45 GJ and saturation towards Frad ∼0.8. After 1.4 h and 7.5 GJ of cumulative plasma time and injected energy, we carried out a second GDB, this time at 70 °C. This {\textquoteleft}cold{\textquoteright} GDB initially led to a much lower Ohmic Frad = 0.3–0.4 but the effect lasted ∼7 times less, with a characteristic cumulative injected energy of 0.37 GJ. At the end of the campaign, we cumulated ∼3h and ∼30 GJ through repetitive, minute long pulses without any boronization. Throughout this 4-weeks-long experiment, Frad in the 4 MW heating phase evolved only marginally (from 0.5 to 0.55). This increase is mostly due to the build-up of re/co-deposited layers on both lower divertor targets.",

author = "A. Gallo and Ph Moreau and D. Douai and T. Alarcon and K. Afonin and V. Anzallo and R. Bisson and J. Bucalossi and E. Caprin and Y. Corre and \{De Combarieu\}, M. and C. Desgranges and P. Devynck and A. Ekedahl and N. Fedorczak and J. Gaspar and A. Grosjean and C. Guillemaut and R. Guirlet and Gunn, \{J. P.\} and J. Hillairet and T. Loarer and P. Maget and P. Manas and J. Morales and Pellissier, \{F. P.\} and E. Tsitrone and K. Krieger and A. Hakola and A. Widdowson",

note = "Publisher Copyright: {\textcopyright} 2024",

year = "2024",

month = dec,

doi = "10.1016/j.nme.2024.101741",

language = "English",

volume = "41",

journal = "Nuclear Materials and Energy",

issn = "2352-1791",

publisher = "Elsevier",

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Gallo, A, Moreau, P, Douai, D, Alarcon, T, Afonin, K, Anzallo, V, Bisson, R, Bucalossi, J, Caprin, E, Corre, Y, De Combarieu, M, Desgranges, C, Devynck, P, Ekedahl, A, Fedorczak, N, Gaspar, J, Grosjean, A, Guillemaut, C, Guirlet, R, Gunn, JP, Hillairet, J, Loarer, T, Maget, P, Manas, P, Morales, J, Pellissier, FP, Tsitrone, E, Krieger, K, Hakola, A & Widdowson, A 2024, 'Wall conditions in WEST during operations with a new ITER grade, actively cooled divertor', Nuclear Materials and Energy, vol. 41, 101741. https://doi.org/10.1016/j.nme.2024.101741

TY - JOUR

T1 - Wall conditions in WEST during operations with a new ITER grade, actively cooled divertor

AU - Gallo, A.

AU - Moreau, Ph

AU - Douai, D.

AU - Alarcon, T.

AU - Afonin, K.

AU - Anzallo, V.

AU - Bisson, R.

AU - Bucalossi, J.

AU - Caprin, E.

AU - Corre, Y.

AU - De Combarieu, M.

AU - Desgranges, C.

AU - Devynck, P.

AU - Ekedahl, A.

AU - Fedorczak, N.

AU - Gaspar, J.

AU - Grosjean, A.

AU - Guillemaut, C.

AU - Guirlet, R.

AU - Gunn, J. P.

AU - Hillairet, J.

AU - Loarer, T.

AU - Maget, P.

AU - Manas, P.

AU - Morales, J.

AU - Pellissier, F. P.

AU - Tsitrone, E.

AU - Krieger, K.

AU - Hakola, A.

AU - Widdowson, A.

PY - 2024/12

Y1 - 2024/12

N2 - Future fusion reactors like ITER and DEMO will have all-tungsten (W) walls and long pulses. These features will make wall conditioning more difficult than in most of the existing devices. The W Environment Steady-state Tokamak (WEST) is one of the few long pulse (364 s) fusion devices with actively cooled W plasma-facing components in the world. WEST is a unique test bed to study impurity migration and plasma density control via reactor relevant wall conditioning techniques. The phase II of WEST operations began in 2022, after the installation of a new lower divertor, now entirely equipped with actively cooled, ITER grade, W monoblocks. After pump down, we baked WEST between 90 °C and 170 °C for ∼2 weeks. After 82.5 h at 90 °C and 33 h at 170 °C, vacuum conditions were stable with a vessel pressure of 6x10-5 Pa and mass spectra dominated by H2 molecules. While at 170 °C, we performed ∼40 h of D2 glow discharge cleaning (GDC) and ∼5 h of glow discharge boronization (GDB), using a 15 %-85 % B2D6-He mix and a total boron mass of ∼12 g. This was the very first GDB at such high temperature for WEST. The whole wall conditioning sequence led to a ∼10 times reduction of the H2O signal as well as to a ∼3 times reduction of the O2 signal, according to mass spectra. Once back to 70 °C, the vessel pressure was 5.5x10-6 Pa and plasma restart was seamless with ∼30 s cumulated over the very first 5 pulses and an Ohmic radiated power fraction Frad = 0.6, showing successful conditioning of the new ITER grade divertor. The effect of the first, ‘hot’ GDB faded with a characteristic cumulative injected energy of 2.45 GJ and saturation towards Frad ∼0.8. After 1.4 h and 7.5 GJ of cumulative plasma time and injected energy, we carried out a second GDB, this time at 70 °C. This ‘cold’ GDB initially led to a much lower Ohmic Frad = 0.3–0.4 but the effect lasted ∼7 times less, with a characteristic cumulative injected energy of 0.37 GJ. At the end of the campaign, we cumulated ∼3h and ∼30 GJ through repetitive, minute long pulses without any boronization. Throughout this 4-weeks-long experiment, Frad in the 4 MW heating phase evolved only marginally (from 0.5 to 0.55). This increase is mostly due to the build-up of re/co-deposited layers on both lower divertor targets.

AB - Future fusion reactors like ITER and DEMO will have all-tungsten (W) walls and long pulses. These features will make wall conditioning more difficult than in most of the existing devices. The W Environment Steady-state Tokamak (WEST) is one of the few long pulse (364 s) fusion devices with actively cooled W plasma-facing components in the world. WEST is a unique test bed to study impurity migration and plasma density control via reactor relevant wall conditioning techniques. The phase II of WEST operations began in 2022, after the installation of a new lower divertor, now entirely equipped with actively cooled, ITER grade, W monoblocks. After pump down, we baked WEST between 90 °C and 170 °C for ∼2 weeks. After 82.5 h at 90 °C and 33 h at 170 °C, vacuum conditions were stable with a vessel pressure of 6x10-5 Pa and mass spectra dominated by H2 molecules. While at 170 °C, we performed ∼40 h of D2 glow discharge cleaning (GDC) and ∼5 h of glow discharge boronization (GDB), using a 15 %-85 % B2D6-He mix and a total boron mass of ∼12 g. This was the very first GDB at such high temperature for WEST. The whole wall conditioning sequence led to a ∼10 times reduction of the H2O signal as well as to a ∼3 times reduction of the O2 signal, according to mass spectra. Once back to 70 °C, the vessel pressure was 5.5x10-6 Pa and plasma restart was seamless with ∼30 s cumulated over the very first 5 pulses and an Ohmic radiated power fraction Frad = 0.6, showing successful conditioning of the new ITER grade divertor. The effect of the first, ‘hot’ GDB faded with a characteristic cumulative injected energy of 2.45 GJ and saturation towards Frad ∼0.8. After 1.4 h and 7.5 GJ of cumulative plasma time and injected energy, we carried out a second GDB, this time at 70 °C. This ‘cold’ GDB initially led to a much lower Ohmic Frad = 0.3–0.4 but the effect lasted ∼7 times less, with a characteristic cumulative injected energy of 0.37 GJ. At the end of the campaign, we cumulated ∼3h and ∼30 GJ through repetitive, minute long pulses without any boronization. Throughout this 4-weeks-long experiment, Frad in the 4 MW heating phase evolved only marginally (from 0.5 to 0.55). This increase is mostly due to the build-up of re/co-deposited layers on both lower divertor targets.

UR - https://www.scopus.com/pages/publications/85204720988

U2 - 10.1016/j.nme.2024.101741

DO - 10.1016/j.nme.2024.101741

M3 - Article

AN - SCOPUS:85204720988

SN - 2352-1791

VL - 41

JO - Nuclear Materials and Energy

JF - Nuclear Materials and Energy

M1 - 101741

ER -

Wall conditions in WEST during operations with a new ITER grade, actively cooled divertor

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