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(EXP3/06) Dependence of Edge Stability on Plasma Shape and Local Pressure Gradients in the DIII-D and JT-60U Tokamaks

L. L. Lao¹⁾, Y. Kamada²⁾, T. Oikawa²⁾, L. R. Baylor³⁾, K. H. Burrell¹⁾, V. S. Chan¹⁾, M. S. Chance⁴⁾, M. S. Chu¹⁾, J. R. Ferron¹⁾, T. Fukuda²⁾, T. Hatae²⁾, A. Isayama²⁾, G. L. Jackson¹⁾, A. W. Leonard¹⁾, M. A. Makowski⁵⁾, J. Manickam⁴⁾, M. Murakami³⁾, M. Okabayashi⁴⁾, T. H. Osborne¹⁾, P. B. Snyder¹⁾, E. J. Strait¹⁾, S. Takeji²⁾, T. Takizuka²⁾, T. S. Taylor¹⁾, A. D. Turnbull¹⁾, K. Tsuchiya²⁾, and M. R. Wade^3)
 
1) General Atomics, San Diego, California USA
²⁾ Japan Atomic Energy Research Institute, Naka-machi, Naka-gun, Ibaraki-ken, Japan
³⁾ Oak Ridge National Laboratory, Oak Ridge, Tennessee USA
⁴⁾ Princeton Plasma Physics Laboratory, Princeton, New Jersey USA
⁵⁾ Lawrence Livermore National Laboratory, Livermore, California USA

Abstract.  The dependence of edge stability on plasma shape and local pressure gradients, P', in the DIII-D and JT-60U tokamaks is studied. The stronger plasma shaping in DIII-D allows the edge region of DIII-D discharges with Type I (``giant'') ELMs to have access to the second region of stability for ideal ballooning modes and larger edge P' than JT-60U Type I ELM discharges. These JT-60U discharges are near the ballooning mode first regime stability limit. DIII-D results support an ideal stability based working model of Type I ELMs as low to intermediate toroidal mode number, n, MHD modes. Results from stability analysis of JT-60U Type I ELM discharges indicate that predictions from this model are also consistent with JT-60U edge stability observations.

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