Demonstration of ITER operational scenarios on DIII-D

E. J. Doyle, J. C. Deboo, J. R. Ferron, G. L. Jackson, T. C. Luce, M. Murakami, T. H. Osborne, J. M. Park, P. A. Politzer, H. Reimerdes, R. V. Budny, T. A. Casper, C. D. Challis, R. J. Groebner, C. T. Holcomb, A. W. Hyatt, R. J. La Haye, G. R. McKee, T. W. Petrie, C. C. PettyT. L. Rhodes, M. W. Shafer, P. B. Snyder, E. J. Strait, M. R. Wade, G. Wang, W. P. West, L. Zeng

    Research output: Contribution to journalArticlepeer-review

    42 Scopus citations

    Abstract

    The DIII-D programme has recently initiated an effort to provide suitably scaled experimental evaluations of four primary ITER operational scenarios. New and unique features of this work are that the plasmas incorporate essential features of the ITER scenarios and anticipated operating characteristics; e.g. the plasma cross-section, aspect ratio and value of I/aB of the DIII-D discharges match the ITER design, with size reduced by a factor of 3.7. Key aspects of all four scenarios, such as target values for βN and H98, have been replicated successfully on DIII-D, providing an improved and unified physics basis for transport and stability modelling, as well as for performance extrapolation to ITER. In all four scenarios, normalized performance equals or closely approaches that required to realize the physics and technology goals of ITER, and projections of the DIII-D discharges are consistent with ITER achieving its goals of ≥400 MW of fusion power production and Q ≥ 10. These studies also address many of the key physics issues related to the ITER design, including the L-H transition power threshold, the size of edge localized modes, pedestal parameter scaling, the impact of tearing modes on confinement and disruptivity, beta limits and the required capabilities of the plasma control system. An example of direct influence on the ITER design from this work is a modification of the physics requirements for the poloidal field coil set at 15 MA, based on observations that the inductance in the baseline scenario case evolves to a value that lies outside the original ITER specification.

    Original languageEnglish
    Article number075005
    JournalNuclear Fusion
    Volume50
    Issue number7
    DOIs
    StatePublished - 2010

    Funding

    FundersFunder number
    Engineering and Physical Sciences Research CouncilEP/I501045/1
    Engineering and Physical Sciences Research Council

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