Edge localized modes and the pedestal: A model based on coupled peeling–ballooning modes

Snyder, P. B.; Wilson, H. R.; Ferron, J. R.; Lao, L. L.; Leonard, A. W.; Osborne, T.H.; Turnbull, A. D.; Mossessian, D.; Murakami, M.; Xu, X. Q.

doi:10.1063/1.1449463

Cited by 673 publications

(803 citation statements)

References 31 publications

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“…Even with the conservative values n e & 1 Â 10 19 m À3 and T e & 0:5 keV for the pedestal top, the estimated optical depth is s > 1 at the left side of the filamentary region, i.e., the pedestal top region because the ELMs are generally believed to develop at the steepest pressure gradient. 2,4 Combined with the observed coherent rotation of the entire filaments in the poloidal direction, this supports the validity of the ECE local measurement for all filament regions. On the other hand, the fluctuation dT rad =hT rad i will contain the finite density effect in the case of marginal optical depth, 12,13 i.e.,dT rad =hT rad i ¼ ð1 þ A 2 ÞdT e =hT e i þ A 2 dn e =hn e i, where A 2 ¼ ð1 À rÞse Às =ð1 À e Às Þð1 À re Às Þ and r is the wall reflection coefficient.…”

Section: Electron Cyclotron Emission Imaging In Kstarsupporting

confidence: 65%

“…The initial growth of the multiple ELM filaments is exponential in time and strongly localized in the edge region, which is in qualitative agreement with the linear peeling-ballooning model. 2 The saturated state is meta-stable but eventually transforms into the final crash phase through a short transient phase. The large ELM crash event is a series of filament bursts, which are inherently 3D and nonaxisymmetric events localized both poloidally and toroidally.…”

Section: Discussionmentioning

confidence: 99%

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Two-dimensional imaging of edge-localized modes in KSTAR plasmas unperturbed and perturbed by n=1 external magnetic fields

Yun¹,

Lee²,

Choi³

et al. 2012

Physics of Plasmas

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The temporal evolution of edge-localized modes (ELMs) has been studied using a 2-D electron cyclotron emission imaging system in the KSTAR tokamak. The ELMs are observed to evolve in three distinctive stages: the initial linear growth of multiple filamentary structures having a net poloidal rotation, the interim state of regularly spaced saturated filaments, and the final crash through a short transient phase characterized by abrupt changes in the relative amplitudes and distance among filaments. The crash phase, typically consisted of multiple bursts of a single filament, involves a complex dynamics, poloidal elongation of the bursting filament, development of a fingerlike bulge, and fast localized burst through the finger. Substantial alterations of the ELM dynamics, such as mode number, poloidal rotation, and crash time scale, have been observed under external magnetic perturbations with the toroidal mode number n ¼ 1. V C 2012 American Institute of Physics. [http://dx

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Section: Electron Cyclotron Emission Imaging In Kstarsupporting

confidence: 65%

Section: Discussionmentioning

confidence: 99%

Two-dimensional imaging of edge-localized modes in KSTAR plasmas unperturbed and perturbed by n=1 external magnetic fields

Yun¹,

Lee²,

Choi³

et al. 2012

Physics of Plasmas

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“…Numerical simulations have identified peeling and/or ballooning modes as candidate instabilities generating filamentary structures that burst outward across flux surfaces during periodic non-linear growth phases [2,3]. Because ELMs carry a substantial transient heat and particle load into the scrape-off layer (SOL), they will present serious power-handling problems to future fusion devices.…”

Section: Introductionmentioning

confidence: 99%

Transition to ELM-free improved H-mode by lithium deposition on NSTX graphite divertor surfaces

Mansfield

Kugel

Maingi

et al. 2009

Journal of Nuclear Materials

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a b s t r a c tLithium evaporated onto plasma facing components in the NSTX lower divertor has made dramatic improvements in discharge performance. As lithium accumulated, plasmas previously exhibiting robust Type 1 ELMs gradually transformed into discharges with intermittent ELMs and finally into continuously evolving ELM-free discharges. During this sequence, other discharge parameters changed in a complicated manner. As the ELMs disappeared, energy confinement improved and remarkable changes in edge and scrape-off layer plasma properties were observed. These results demonstrate that active modification of plasma surface interactions can preempt large ELMs.

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“…[1][2][3][4][5][6] Existing studies of the bootstrap current and the construction of analytic formulas being used in the equilibrium and stability analyses have been mainly focused on the core plasma. [7][8][9][10] Recently, the importance of the bootstrap current has been re-emphasized through its critical role played in the stability, equilibrium, and turbulence studies of the steep gradient edge pedestal 13,14 in H-mode (high confinement mode) operation. A steep pressure gradient in the edge pedestal yields a large localized bootstrap current.…”

Section: Introductionmentioning

confidence: 99%

Bootstrap current for the edge pedestal plasma in a diverted tokamak geometry

Koh

Chang

et al. 2012

Physics of Plasmas

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The edge bootstrap current plays a critical role in the equilibrium and stability of the steep edge pedestal plasma. The pedestal plasma has an unconventional and difficult neoclassical property, as compared with the core plasma. It has a narrow passing particle region in velocity space that can be easily modified or destroyed by Coulomb collisions. At the same time, the edge pedestal plasma has steep pressure and electrostatic potential gradients whose scale-lengths are comparable with the ion banana width, and includes a magnetic separatrix surface, across which the topological properties of the magnetic field and particle orbits change abruptly. A driftkinetic particle code XGC0, equipped with a mass-momentum-energy conserving collision operator, is used to study the edge bootstrap current in a realistic diverted magnetic field geometry with a self-consistent radial electric field. When the edge electrons are in the weakly collisional banana regime, surprisingly, the present kinetic simulation confirms that the existing analytic expressions [represented by O. Sauter et al., Phys. Plasmas 6, 2834] are still valid in this unconventional region, except in a thin radial layer in contact with the magnetic separatrix. The agreement arises from the dominance of the electron contribution to the bootstrap current compared with ion contribution and from a reasonable separation of the trapped-passing dynamics without a strong collisional mixing. However, when the pedestal electrons are in plateau-collisional regime, there is significant deviation of numerical results from the existing analytic formulas, mainly due to large effective collisionality of the passing and the boundary layer trapped particles in edge region. In a conventional aspect ratio tokamak, the edge bootstrap current from kinetic simulation can be significantly less than that from the Sauter formula if the electron collisionality is high. On the other hand, when the aspect ratio is close to unity, the collisional edge bootstrap current can be significantly greater than that from the Sauter formula. Rapid toroidal rotation of the magnetic field lines at the high field side of a tight aspect-ratio tokamak is believed to be the cause of the different behavior. A new analytic fitting formula, as a simple modification to the Sauter formula, is obtained to bring the analytic expression to a better agreement with the edge kinetic simulation results. V C 2012 American Institute of Physics.

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Edge localized modes and the pedestal: A model based on coupled peeling–ballooning modes

Cited by 673 publications

References 31 publications

Two-dimensional imaging of edge-localized modes in KSTAR plasmas unperturbed and perturbed by n=1 external magnetic fields

Two-dimensional imaging of edge-localized modes in KSTAR plasmas unperturbed and perturbed by n=1 external magnetic fields

Transition to ELM-free improved H-mode by lithium deposition on NSTX graphite divertor surfaces

Bootstrap current for the edge pedestal plasma in a diverted tokamak geometry

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