Remote handling and plasma conditions to enable fusion nuclear science R&D using a component testing facility

Y. K.M. Peng; T. W. Burgess; A. J. Carroll; C. L. Neumeyer; J. M. Canik; M. J. Cole; W. D. Dorland; P. J. Fogarty; L. Grisham; D. L. Hillis; Y. Katoh; K. Korsah; M. Kotschenreuther; R. Lahaye; S. Mahajan; R. Majeski; B. E. Nelson; B. D. Patton; D. A. Rasmussen; S. A. Sabbagh; A. C. Sontag; R. E. Stoller; C. C. Tsai; P. Valanju; J. C. Wagner; G. L. Yoder

doi:10.13182/FST09-A9034

Remote handling and plasma conditions to enable fusion nuclear science R&D using a component testing facility

Y. K.M. Peng, T. W. Burgess, A. J. Carroll, C. L. Neumeyer, J. M. Canik, M. J. Cole, W. D. Dorland, P. J. Fogarty, L. Grisham, D. L. Hillis, Y. Katoh, K. Korsah, M. Kotschenreuther, R. Lahaye, S. Mahajan, R. Majeski, B. E. Nelson, B. D. Patton, D. A. Rasmussen, S. A. SabbaghA. C. Sontag, R. E. Stoller, C. C. Tsai, P. Valanju, J. C. Wagner, G. L. Yoder

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Abstract

The use of a fusion component testing facility to study and establish, during the ITER era, the remaining scientific and technical knowledge needed by fusion Demo is considered and described in this paper. This use aims to test components in an integrated fusion nuclear environment, for the first time, to discover and understand the underpinning physical properties, and to develop improved components for further testing, in a timeefficient manner. It requires a design with extensive modularization and remote handling of activated components, and flexible hot-cell laboratories. It further requires reliable plasma conditions to avoid disruptions and minimize their impact, and designs to reduce the divertor heat flux to the level of ITER design. As the plasma duration is extended through the planned ITER level (∼10³ s) and beyond, physical properties with increasing time constants, progressively for ∼1& s, ∼10⁵ s, and ∼10⁶ s, would become accessible for testing and R&D. The longest time constants of these are likely to be of the order of a week (∼10⁶ s Progressive stages of research operation are envisioned in deuterium, deuterium-tritium for the ITER duration, and deuteriumtritium with increasingly longer plasma durations. The fusion neutron fluence and operational duty factor anticipated for this "scientific exploration " phase of a component test facility are estimated to be up to 1 MWyr/m² and up to 10%, respectively.

Original language	English
Pages (from-to)	957-964
Number of pages	8
Journal	Fusion Science and Technology
Volume	56
Issue number	2
DOIs	https://doi.org/10.13182/FST09-A9034
State	Published - Aug 2009

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Peng, Y. K. M., Burgess, T. W., Carroll, A. J., Neumeyer, C. L., Canik, J. M., Cole, M. J., Dorland, W. D., Fogarty, P. J., Grisham, L., Hillis, D. L., Katoh, Y., Korsah, K., Kotschenreuther, M., Lahaye, R., Mahajan, S., Majeski, R., Nelson, B. E., Patton, B. D., Rasmussen, D. A., ... Yoder, G. L. (2009). Remote handling and plasma conditions to enable fusion nuclear science R&D using a component testing facility. Fusion Science and Technology, 56(2), 957-964. https://doi.org/10.13182/FST09-A9034

@article{e8a6380f82044ebda5635a896b58fa26,

title = "Remote handling and plasma conditions to enable fusion nuclear science R&D using a component testing facility",

abstract = "The use of a fusion component testing facility to study and establish, during the ITER era, the remaining scientific and technical knowledge needed by fusion Demo is considered and described in this paper. This use aims to test components in an integrated fusion nuclear environment, for the first time, to discover and understand the underpinning physical properties, and to develop improved components for further testing, in a timeefficient manner. It requires a design with extensive modularization and remote handling of activated components, and flexible hot-cell laboratories. It further requires reliable plasma conditions to avoid disruptions and minimize their impact, and designs to reduce the divertor heat flux to the level of ITER design. As the plasma duration is extended through the planned ITER level (∼103 s) and beyond, physical properties with increasing time constants, progressively for ∼1& s, ∼105 s, and ∼106 s, would become accessible for testing and R&D. The longest time constants of these are likely to be of the order of a week (∼106 s Progressive stages of research operation are envisioned in deuterium, deuterium-tritium for the ITER duration, and deuteriumtritium with increasingly longer plasma durations. The fusion neutron fluence and operational duty factor anticipated for this {"}scientific exploration {"} phase of a component test facility are estimated to be up to 1 MWyr/m2 and up to 10%, respectively.",

author = "Peng, {Y. K.M.} and Burgess, {T. W.} and Carroll, {A. J.} and Neumeyer, {C. L.} and Canik, {J. M.} and Cole, {M. J.} and Dorland, {W. D.} and Fogarty, {P. J.} and L. Grisham and Hillis, {D. L.} and Y. Katoh and K. Korsah and M. Kotschenreuther and R. Lahaye and S. Mahajan and R. Majeski and Nelson, {B. E.} and Patton, {B. D.} and Rasmussen, {D. A.} and Sabbagh, {S. A.} and Sontag, {A. C.} and Stoller, {R. E.} and Tsai, {C. C.} and P. Valanju and Wagner, {J. C.} and Yoder, {G. L.}",

year = "2009",

month = aug,

doi = "10.13182/FST09-A9034",

language = "English",

volume = "56",

pages = "957--964",

journal = "Fusion Science and Technology",

issn = "1536-1055",

publisher = "Taylor and Francis Group",

number = "2",

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Peng, YKM, Burgess, TW, Carroll, AJ, Neumeyer, CL, Canik, JM, Cole, MJ, Dorland, WD, Fogarty, PJ, Grisham, L, Hillis, DL, Katoh, Y, Korsah, K, Kotschenreuther, M, Lahaye, R, Mahajan, S, Majeski, R, Nelson, BE, Patton, BD, Rasmussen, DA, Sabbagh, SA, Sontag, AC, Stoller, RE, Tsai, CC, Valanju, P, Wagner, JC & Yoder, GL 2009, 'Remote handling and plasma conditions to enable fusion nuclear science R&D using a component testing facility', Fusion Science and Technology, vol. 56, no. 2, pp. 957-964. https://doi.org/10.13182/FST09-A9034

TY - JOUR

T1 - Remote handling and plasma conditions to enable fusion nuclear science R&D using a component testing facility

AU - Peng, Y. K.M.

AU - Burgess, T. W.

AU - Carroll, A. J.

AU - Neumeyer, C. L.

AU - Canik, J. M.

AU - Cole, M. J.

AU - Dorland, W. D.

AU - Fogarty, P. J.

AU - Grisham, L.

AU - Hillis, D. L.

AU - Katoh, Y.

AU - Korsah, K.

AU - Kotschenreuther, M.

AU - Lahaye, R.

AU - Mahajan, S.

AU - Majeski, R.

AU - Nelson, B. E.

AU - Patton, B. D.

AU - Rasmussen, D. A.

AU - Sabbagh, S. A.

AU - Sontag, A. C.

AU - Stoller, R. E.

AU - Tsai, C. C.

AU - Valanju, P.

AU - Wagner, J. C.

AU - Yoder, G. L.

PY - 2009/8

Y1 - 2009/8

N2 - The use of a fusion component testing facility to study and establish, during the ITER era, the remaining scientific and technical knowledge needed by fusion Demo is considered and described in this paper. This use aims to test components in an integrated fusion nuclear environment, for the first time, to discover and understand the underpinning physical properties, and to develop improved components for further testing, in a timeefficient manner. It requires a design with extensive modularization and remote handling of activated components, and flexible hot-cell laboratories. It further requires reliable plasma conditions to avoid disruptions and minimize their impact, and designs to reduce the divertor heat flux to the level of ITER design. As the plasma duration is extended through the planned ITER level (∼103 s) and beyond, physical properties with increasing time constants, progressively for ∼1& s, ∼105 s, and ∼106 s, would become accessible for testing and R&D. The longest time constants of these are likely to be of the order of a week (∼106 s Progressive stages of research operation are envisioned in deuterium, deuterium-tritium for the ITER duration, and deuteriumtritium with increasingly longer plasma durations. The fusion neutron fluence and operational duty factor anticipated for this "scientific exploration " phase of a component test facility are estimated to be up to 1 MWyr/m2 and up to 10%, respectively.

AB - The use of a fusion component testing facility to study and establish, during the ITER era, the remaining scientific and technical knowledge needed by fusion Demo is considered and described in this paper. This use aims to test components in an integrated fusion nuclear environment, for the first time, to discover and understand the underpinning physical properties, and to develop improved components for further testing, in a timeefficient manner. It requires a design with extensive modularization and remote handling of activated components, and flexible hot-cell laboratories. It further requires reliable plasma conditions to avoid disruptions and minimize their impact, and designs to reduce the divertor heat flux to the level of ITER design. As the plasma duration is extended through the planned ITER level (∼103 s) and beyond, physical properties with increasing time constants, progressively for ∼1& s, ∼105 s, and ∼106 s, would become accessible for testing and R&D. The longest time constants of these are likely to be of the order of a week (∼106 s Progressive stages of research operation are envisioned in deuterium, deuterium-tritium for the ITER duration, and deuteriumtritium with increasingly longer plasma durations. The fusion neutron fluence and operational duty factor anticipated for this "scientific exploration " phase of a component test facility are estimated to be up to 1 MWyr/m2 and up to 10%, respectively.

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Remote handling and plasma conditions to enable fusion nuclear science R&D using a component testing facility

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