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Predictions of core plasma performance for the SPARC tokamak

P. Rodriguez-Fernandez, N. T. Howard, M. Greenwald, A. J. Creely, J. W. Hughes, J. C. Wright, C. Holland, Y. Lin, F. Sciortino, the SPARC team

2020Journal of Plasma Physics93 citationsDOIOpen Access PDF

Abstract

SPARC is designed to be a high-field, medium-size tokamak aimed at achieving net energy gain with ion cyclotron range-of-frequencies (ICRF) as its primary auxiliary heating mechanism. Empirical predictions with conservative physics indicate that SPARC baseline plasmas would reach $Q\approx 11$ , which is well above its mission objective of $Q>2$ . To build confidence that SPARC will be successful, physics-based integrated modelling has also been performed. The TRANSP code coupled with the theory-based trapped gyro-Landau fluid (TGLF) turbulence model and EPED predictions for pedestal stability find that $Q\approx 9$ is attainable in standard H-mode operation and confirms $Q > 2$ operation is feasible even with adverse assumptions. In this analysis, ion cyclotron waves are simulated with the full wave TORIC code and alpha heating is modelled with the Monte–Carlo fast ion NUBEAM module. Detailed analysis of expected turbulence regimes with linear and nonlinear CGYRO simulations is also presented, demonstrating that profile predictions with the TGLF reduced model are in reasonable agreement.

Topics & Concepts

PhysicsCyclotronTokamakPlasmaTurbulenceComputational physicsMonte Carlo methodNonlinear systemIonAtomic physicsStatistical physicsNuclear physicsMechanicsQuantum mechanicsStatisticsMathematicsMagnetic confinement fusion researchIonosphere and magnetosphere dynamicsParticle accelerators and beam dynamics
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