Pressure profile modification of internal transport barrier plasmas in Alcator C-Mod

J. E. Rice; P. T. Bonoli; C. L. Fiore; W. D. Lee; E. S. Marmar; S. J. Wukitch; R. S. Granetz; A. E. Hubbard; J. W. Hughes; J. H. Irby; Y. Lin; D. Mossessian; S. M. Wolfe; K. Zhurovich; M. J. Greenwald; I. H. Hutchinson; M. Porkolab; J. A. Snipes

doi:10.1088/0029-5515/43/8/320

Pressure profile modification of internal transport barrier plasmas in Alcator C-Mod

J. E. Rice, P. T. Bonoli, C. L. Fiore, W. D. Lee, E. S. Marmar, S. J. Wukitch, R. S. Granetz, A. E. Hubbard, J. W. Hughes, J. H. Irby, Y. Lin, D. Mossessian, S. M. Wolfe, K. Zhurovich, M. J. Greenwald, I. H. Hutchinson, M. Porkolab, J. A. Snipes

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Abstract

Internal transport barrier (ITB) plasmas with peak pressures of 0.25 MPa and pressure gradients as large as 2.5 MPam^-1 have been produced in Alcator C-Mod using off-axis ion cyclotron range of frequencies (ICRF) heating. The onset of the ITBs is apparent when the pressure gradient exceeds 1.0 MPam^-1, which is similar to the JET criterion of ρ _s*/L ≥ 0.014. Concommitant with the peaking of the core pressure as the ITB develops is a drop of the toroidal rotation velocity profile inside of the barrier foot; the maximum of the velocity gradient coincides with the peak in the pressure gradient. The quasi-coherent (QC) mode, associated with the enhanced D_α (EDA) H-mode plasmas which evolve the ITBs, breaks up and disappears as the barriers develop, even though the measured edge pedestal parameters remain fixed. The position of the ITB foot has been moved over a range of 1/3 of the plasma minor radius by varying the toroidal magnetic field. The peak in the calculated bootstrap current density profile has correspondingly been regulated over a similar range in plasma minor radius. The location of the density profile foot is found to expand as the toroidal magnetic field is reduced and the ICRF frequency is lowered. The density foot radius is relatively independent of q₉₅, however, in a scan of the plasma current at fixed B_T and wave frequency.

Original language	English (US)
Pages (from-to)	781-788
Number of pages	8
Journal	Nuclear Fusion
Volume	43
Issue number	8
DOIs	https://doi.org/10.1088/0029-5515/43/8/320
State	Published - Aug 2003
Externally published	Yes

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

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10.1088/0029-5515/43/8/320

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Rice, J. E., Bonoli, P. T., Fiore, C. L., Lee, W. D., Marmar, E. S., Wukitch, S. J., Granetz, R. S., Hubbard, A. E., Hughes, J. W., Irby, J. H., Lin, Y., Mossessian, D., Wolfe, S. M., Zhurovich, K., Greenwald, M. J., Hutchinson, I. H., Porkolab, M., & Snipes, J. A. (2003). Pressure profile modification of internal transport barrier plasmas in Alcator C-Mod. Nuclear Fusion, 43(8), 781-788. https://doi.org/10.1088/0029-5515/43/8/320

@article{1a3e7be8b98b49d89fc22dd2a8f8b160,

title = "Pressure profile modification of internal transport barrier plasmas in Alcator C-Mod",

abstract = "Internal transport barrier (ITB) plasmas with peak pressures of 0.25 MPa and pressure gradients as large as 2.5 MPam-1 have been produced in Alcator C-Mod using off-axis ion cyclotron range of frequencies (ICRF) heating. The onset of the ITBs is apparent when the pressure gradient exceeds 1.0 MPam-1, which is similar to the JET criterion of ρ s*/L ≥ 0.014. Concommitant with the peaking of the core pressure as the ITB develops is a drop of the toroidal rotation velocity profile inside of the barrier foot; the maximum of the velocity gradient coincides with the peak in the pressure gradient. The quasi-coherent (QC) mode, associated with the enhanced Dα (EDA) H-mode plasmas which evolve the ITBs, breaks up and disappears as the barriers develop, even though the measured edge pedestal parameters remain fixed. The position of the ITB foot has been moved over a range of 1/3 of the plasma minor radius by varying the toroidal magnetic field. The peak in the calculated bootstrap current density profile has correspondingly been regulated over a similar range in plasma minor radius. The location of the density profile foot is found to expand as the toroidal magnetic field is reduced and the ICRF frequency is lowered. The density foot radius is relatively independent of q95, however, in a scan of the plasma current at fixed BT and wave frequency.",

author = "Rice, \{J. E.\} and Bonoli, \{P. T.\} and Fiore, \{C. L.\} and Lee, \{W. D.\} and Marmar, \{E. S.\} and Wukitch, \{S. J.\} and Granetz, \{R. S.\} and Hubbard, \{A. E.\} and Hughes, \{J. W.\} and Irby, \{J. H.\} and Y. Lin and D. Mossessian and Wolfe, \{S. M.\} and K. Zhurovich and Greenwald, \{M. J.\} and Hutchinson, \{I. H.\} and M. Porkolab and Snipes, \{J. A.\}",

year = "2003",

month = aug,

doi = "10.1088/0029-5515/43/8/320",

language = "English (US)",

volume = "43",

pages = "781--788",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "8",

}

Rice, JE, Bonoli, PT, Fiore, CL, Lee, WD, Marmar, ES, Wukitch, SJ, Granetz, RS, Hubbard, AE, Hughes, JW, Irby, JH, Lin, Y, Mossessian, D, Wolfe, SM, Zhurovich, K, Greenwald, MJ, Hutchinson, IH, Porkolab, M & Snipes, JA 2003, 'Pressure profile modification of internal transport barrier plasmas in Alcator C-Mod', Nuclear Fusion, vol. 43, no. 8, pp. 781-788. https://doi.org/10.1088/0029-5515/43/8/320

TY - JOUR

T1 - Pressure profile modification of internal transport barrier plasmas in Alcator C-Mod

AU - Rice, J. E.

AU - Bonoli, P. T.

AU - Fiore, C. L.

AU - Lee, W. D.

AU - Marmar, E. S.

AU - Wukitch, S. J.

AU - Granetz, R. S.

AU - Hubbard, A. E.

AU - Hughes, J. W.

AU - Irby, J. H.

AU - Lin, Y.

AU - Mossessian, D.

AU - Wolfe, S. M.

AU - Zhurovich, K.

AU - Greenwald, M. J.

AU - Hutchinson, I. H.

AU - Porkolab, M.

AU - Snipes, J. A.

PY - 2003/8

Y1 - 2003/8

N2 - Internal transport barrier (ITB) plasmas with peak pressures of 0.25 MPa and pressure gradients as large as 2.5 MPam-1 have been produced in Alcator C-Mod using off-axis ion cyclotron range of frequencies (ICRF) heating. The onset of the ITBs is apparent when the pressure gradient exceeds 1.0 MPam-1, which is similar to the JET criterion of ρ s*/L ≥ 0.014. Concommitant with the peaking of the core pressure as the ITB develops is a drop of the toroidal rotation velocity profile inside of the barrier foot; the maximum of the velocity gradient coincides with the peak in the pressure gradient. The quasi-coherent (QC) mode, associated with the enhanced Dα (EDA) H-mode plasmas which evolve the ITBs, breaks up and disappears as the barriers develop, even though the measured edge pedestal parameters remain fixed. The position of the ITB foot has been moved over a range of 1/3 of the plasma minor radius by varying the toroidal magnetic field. The peak in the calculated bootstrap current density profile has correspondingly been regulated over a similar range in plasma minor radius. The location of the density profile foot is found to expand as the toroidal magnetic field is reduced and the ICRF frequency is lowered. The density foot radius is relatively independent of q95, however, in a scan of the plasma current at fixed BT and wave frequency.

AB - Internal transport barrier (ITB) plasmas with peak pressures of 0.25 MPa and pressure gradients as large as 2.5 MPam-1 have been produced in Alcator C-Mod using off-axis ion cyclotron range of frequencies (ICRF) heating. The onset of the ITBs is apparent when the pressure gradient exceeds 1.0 MPam-1, which is similar to the JET criterion of ρ s*/L ≥ 0.014. Concommitant with the peaking of the core pressure as the ITB develops is a drop of the toroidal rotation velocity profile inside of the barrier foot; the maximum of the velocity gradient coincides with the peak in the pressure gradient. The quasi-coherent (QC) mode, associated with the enhanced Dα (EDA) H-mode plasmas which evolve the ITBs, breaks up and disappears as the barriers develop, even though the measured edge pedestal parameters remain fixed. The position of the ITB foot has been moved over a range of 1/3 of the plasma minor radius by varying the toroidal magnetic field. The peak in the calculated bootstrap current density profile has correspondingly been regulated over a similar range in plasma minor radius. The location of the density profile foot is found to expand as the toroidal magnetic field is reduced and the ICRF frequency is lowered. The density foot radius is relatively independent of q95, however, in a scan of the plasma current at fixed BT and wave frequency.

UR - https://www.scopus.com/pages/publications/0041919160

UR - https://www.scopus.com/inward/citedby.url?scp=0041919160&partnerID=8YFLogxK

U2 - 10.1088/0029-5515/43/8/320

DO - 10.1088/0029-5515/43/8/320

M3 - Article

AN - SCOPUS:0041919160

SN - 0029-5515

VL - 43

SP - 781

EP - 788

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 8

ER -

Pressure profile modification of internal transport barrier plasmas in Alcator C-Mod

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