Momentum confinement at low torque

W. M. Solomon; K. H. Burrell; J. S. Degrassie; R. Budny; R. J. Groebner; J. E. Kinsey; G. J. Kramer; T. C. Luce; M. A. Makowski; D. Mikkelsen; R. Nazikian; C. C. Petty; P. A. Politzer; S. D. Scott; M. A. Van Zeeland; M. C. Zarnstorff

doi:10.1088/0741-3335/49/12B/S29

Momentum confinement at low torque

W. M. Solomon
, K. H. Burrell
, J. S. Degrassie
, R. Budny
, R. J. Groebner
, J. E. Kinsey
, G. J. Kramer
, T. C. Luce
, M. A. Makowski
, D. Mikkelsen
, R. Nazikian
, C. C. Petty
, P. A. Politzer
, S. D. Scott
, M. A. Van Zeeland
, M. C. Zarnstorff

PPPL Tokamak Expermntl Science

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

87 Scopus citations

Abstract

Momentum confinement was investigated on DIII-D as a function of applied neutral beam torque at constant normalized beta β_N, by varying the mix of co (parallel to the plasma current) and counter neutral beams. Under balanced neutral beam injection (i.e. zero total torque to the plasma), the plasma maintains a significant rotation in the co-direction. This 'intrinsic' rotation can be modeled as being due to an offset in the applied torque (i.e. an 'anomalous torque'). This anomalous torque appears to have a magnitude comparable to one co neutral beam source. The presence of such an anomalous torque source must be taken into account to obtain meaningful quantities describing momentum transport, such as the global momentum confinement time and local diffusivities. Studies of the mechanical angular momentum in ELMing H-mode plasmas with elevated q_min show that the momentum confinement time improves as the torque is reduced. In hybrid plasmas, the opposite effect is observed, namely that momentum confinement improves at high torque/rotation. GLF23 modeling suggests that the role of E × B shearing is quite different between the two plasmas, which may help to explain the different dependence of the momentum confinement on torque.

Original language	English (US)
Pages (from-to)	B313-B324
Journal	Plasma Physics and Controlled Fusion
Volume	49
Issue number	12 B
DOIs	https://doi.org/10.1088/0741-3335/49/12B/S29
State	Published - Dec 1 2007

All Science Journal Classification (ASJC) codes

Nuclear Energy and Engineering
Condensed Matter Physics

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Solomon, W. M., Burrell, K. H., Degrassie, J. S., Budny, R., Groebner, R. J., Kinsey, J. E., Kramer, G. J., Luce, T. C., Makowski, M. A., Mikkelsen, D., Nazikian, R., Petty, C. C., Politzer, P. A., Scott, S. D., Van Zeeland, M. A., & Zarnstorff, M. C. (2007). Momentum confinement at low torque. Plasma Physics and Controlled Fusion, 49(12 B), B313-B324. https://doi.org/10.1088/0741-3335/49/12B/S29

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title = "Momentum confinement at low torque",

abstract = "Momentum confinement was investigated on DIII-D as a function of applied neutral beam torque at constant normalized beta βN, by varying the mix of co (parallel to the plasma current) and counter neutral beams. Under balanced neutral beam injection (i.e. zero total torque to the plasma), the plasma maintains a significant rotation in the co-direction. This 'intrinsic' rotation can be modeled as being due to an offset in the applied torque (i.e. an 'anomalous torque'). This anomalous torque appears to have a magnitude comparable to one co neutral beam source. The presence of such an anomalous torque source must be taken into account to obtain meaningful quantities describing momentum transport, such as the global momentum confinement time and local diffusivities. Studies of the mechanical angular momentum in ELMing H-mode plasmas with elevated qmin show that the momentum confinement time improves as the torque is reduced. In hybrid plasmas, the opposite effect is observed, namely that momentum confinement improves at high torque/rotation. GLF23 modeling suggests that the role of E × B shearing is quite different between the two plasmas, which may help to explain the different dependence of the momentum confinement on torque.",

author = "Solomon, \{W. M.\} and Burrell, \{K. H.\} and Degrassie, \{J. S.\} and R. Budny and Groebner, \{R. J.\} and Kinsey, \{J. E.\} and Kramer, \{G. J.\} and Luce, \{T. C.\} and Makowski, \{M. A.\} and D. Mikkelsen and R. Nazikian and Petty, \{C. C.\} and Politzer, \{P. A.\} and Scott, \{S. D.\} and \{Van Zeeland\}, \{M. A.\} and Zarnstorff, \{M. C.\}",

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doi = "10.1088/0741-3335/49/12B/S29",

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T1 - Momentum confinement at low torque

AU - Solomon, W. M.

AU - Burrell, K. H.

AU - Degrassie, J. S.

AU - Budny, R.

AU - Groebner, R. J.

AU - Kinsey, J. E.

AU - Kramer, G. J.

AU - Luce, T. C.

AU - Makowski, M. A.

AU - Mikkelsen, D.

AU - Nazikian, R.

AU - Petty, C. C.

AU - Politzer, P. A.

AU - Scott, S. D.

AU - Van Zeeland, M. A.

AU - Zarnstorff, M. C.

PY - 2007/12/1

Y1 - 2007/12/1

N2 - Momentum confinement was investigated on DIII-D as a function of applied neutral beam torque at constant normalized beta βN, by varying the mix of co (parallel to the plasma current) and counter neutral beams. Under balanced neutral beam injection (i.e. zero total torque to the plasma), the plasma maintains a significant rotation in the co-direction. This 'intrinsic' rotation can be modeled as being due to an offset in the applied torque (i.e. an 'anomalous torque'). This anomalous torque appears to have a magnitude comparable to one co neutral beam source. The presence of such an anomalous torque source must be taken into account to obtain meaningful quantities describing momentum transport, such as the global momentum confinement time and local diffusivities. Studies of the mechanical angular momentum in ELMing H-mode plasmas with elevated qmin show that the momentum confinement time improves as the torque is reduced. In hybrid plasmas, the opposite effect is observed, namely that momentum confinement improves at high torque/rotation. GLF23 modeling suggests that the role of E × B shearing is quite different between the two plasmas, which may help to explain the different dependence of the momentum confinement on torque.

AB - Momentum confinement was investigated on DIII-D as a function of applied neutral beam torque at constant normalized beta βN, by varying the mix of co (parallel to the plasma current) and counter neutral beams. Under balanced neutral beam injection (i.e. zero total torque to the plasma), the plasma maintains a significant rotation in the co-direction. This 'intrinsic' rotation can be modeled as being due to an offset in the applied torque (i.e. an 'anomalous torque'). This anomalous torque appears to have a magnitude comparable to one co neutral beam source. The presence of such an anomalous torque source must be taken into account to obtain meaningful quantities describing momentum transport, such as the global momentum confinement time and local diffusivities. Studies of the mechanical angular momentum in ELMing H-mode plasmas with elevated qmin show that the momentum confinement time improves as the torque is reduced. In hybrid plasmas, the opposite effect is observed, namely that momentum confinement improves at high torque/rotation. GLF23 modeling suggests that the role of E × B shearing is quite different between the two plasmas, which may help to explain the different dependence of the momentum confinement on torque.

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UR - https://www.scopus.com/pages/publications/36349019665#tab=citedBy

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SP - B313-B324

JO - Plasma Physics and Controlled Fusion

JF - Plasma Physics and Controlled Fusion

IS - 12 B

ER -

Momentum confinement at low torque

Abstract

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