Your search keyword '"K.H. Burrell"' showing total 14 results

1. Overview of recent experimental results from the DIII-D advanced tokamak program.

Author

K.H. Burrell for the DIII-D Team

Published

2003

2. Scaling trends of the critical E  ×  B shear for edge harmonic oscillation onset in DIII-D quiescent H-mode plasmas.

Author

T.M. Wilks, A.M. Garofalo, P.H. Diamond, Z.B. Guo, J.W. Hughes, K.H. Burrell, and Xi Chen

Subjects

QUIESCENT plasmas, MAGNETOHYDRODYNAMICS, SHEAR (Mechanics), GEOMETRY, ION acoustic waves

Abstract

Quiescent H-mode (QH-mode) has been identified as an attractive stationary operational regime in tokamaks due to its lack of edge localized modes (ELMs), along with good particle and impurity control aided by the presence of magnetohydrodynamic modes such as the edge harmonic oscillation (EHO) or edge turbulence. Experiments on the DIII-D tokamak explore local access conditions for QH-mode through measurements of the critical edge rotational shear necessary for the transition from a QH-mode with a coherent EHO to a typical ELMy H-mode. The critical E  ×  B shear and EHO frequency are predicted by a nonlinear phase-dynamics model relating the pressure and velocity perturbations in the edge pedestal region. The reduced theoretical model predicts a linear relationship between critical shearing rate and , where is the ion acoustic velocity, Lp the pressure gradient scale length, and the radial width of the mode. This scaling of the critical shearing rate agrees with the experimental trend, although the absolute magnitude of the shearing rate threshold is over-predicted by the model. Through a normalized predicted scaling, the model demonstrates the dynamic transition into and out of QH-mode qualitatively, within a single plasma discharge. The experimental comparison lends insight into improving the theoretical model by including more accurate geometry and toroidal mode number physics for more accurate quantitative predictions. [ABSTRACT FROM AUTHOR]

Published

2018

3. Experimental challenges to stiffness as a transport paradigm.

Author

T.c. Luce, K.h. Burrell, C. Holland, A. Marinoni, C.c. Petty, S.p. Smith, M.e. Austin, B.a. Grierson, and L. Zeng

Subjects

H-mode plasma confinement, PLASMA beam injection heating, ELECTRON transport, ANGULAR momentum (Nuclear physics), ENERGY dissipation

Abstract

Two power scans were carried out in H-mode plasmas in DIII-D; one employed standard co-current neutral beam injection (NBI), while the other used a mixture of co-current and counter-current NBI to scan power while holding the torque to a low fixed value. Analysis of the ion and electron heat transport, ion toroidal angular momentum transport, and thermal deuterium transport from these scans is presented. Invariance of the gradients or gradient scalelengths, as might be expected from stiff transport, was not generally observed. When invariance was seen, it was not accompanied by a strong increase in transport, except in the case of the absolute deuterium ion transport. Conduction in the ion channel is the dominant energy loss mechanism. The variation of the ion heat transport with applied power is similar for the co-injection and fixed torque scans, indicating that E  ×  B shearing is not determining the plasma response to additional power. There is however, a quantitative difference in the transport between the two scans, indicating E  ×  B shearing does play a role in the transport. Comparison of these results with a previous experiment that directly probed stiffness at a single radius leads to the following conclusion: while local stiffness as formally defined may hold, invariance of the gradients or normalized scalelengths does not follow from stiff transport in more practical scaling experiments, such as the power scans discussed here. Possible reasons for the lack of correspondence between the local picture and the global expectations are discussed. [ABSTRACT FROM AUTHOR]

Published

2018

4. The effect of electron cyclotron heating on density fluctuations at ion and electron scales in ITER baseline scenario discharges on the DIII-D tokamak.

Author

A. Marinoni, R.I. Pinsker, M. Porkolab, J.C. Rost, E.M. Davis, K.H. Burrell, J. Candy, G.M. Staebler, B.A. Grierson, G.R. McKee, T.L. Rhodes, and Team, The DIII-D

Subjects

PLASMA density, PLASMA fluctuations, ELECTRON cyclotron resonance heating, TOKAMAKS, HEAT flux, PLASMA beam injection heating

Abstract

Experiments simulating the ITER baseline scenario on the DIII-D tokamak show that torque-free pure electron heating, when coupled to plasmas subject to a net co-current beam torque, affects density fluctuations at electron scales on a sub-confinement time scale, whereas fluctuations at ion scales change only after profiles have evolved to a new stationary state. Modifications to the density fluctuations measured by the phase contrast imaging diagnostic (PCI) are assessed by analyzing the time evolution following the switch-off of electron cyclotron heating (ECH), thus going from mixed beam/ECH to pure neutral beam heating at fixed . Within 20 ms after turning off ECH, the intensity of fluctuations is observed to increase at frequencies higher than 200 kHz; in contrast, fluctuations at lower frequency are seen to decrease in intensity on a longer time scale, after other equilibrium quantities have evolved. Non-linear gyro-kinetic modeling at ion and electron scales scales suggest that, while the low frequency response of the diagnostic is consistent with the dominant ITG modes being weakened by the slow-time increase in flow shear, the high frequency response is due to prompt changes to the electron temperature profile that enhance electron modes and generate a larger heat flux and an inward particle pinch. These results suggest that electron heated regimes in ITER will feature multi-scale fluctuations that might affect fusion performance via modifications to profiles. [ABSTRACT FROM AUTHOR]

Published

2017

5. E  ×  B flow shear drive of the linear low-n modes of EHO in the QH-mode regime.

Author

G.S. Xu, B.N. Wan, Y.F. Wang, X.Q. Wu, Xi Chen, Y.-K. Martin Peng, H.Y. Guo, K.H. Burrell, A.M. Garofalo, T.H. Osborne, R.J. Groebner, H.Q. Wang, R. Chen, N. Yan, L. Wang, S.Y. Ding, L.M. Shao, G.H. Hu, Y.L. Li, and H. Lan

Subjects

SHEAR flow, HARMONIC oscillators, QUIESCENT plasmas, TURBULENCE, ELECTROMAGNETISM

Abstract

A new model for the edge harmonic oscillations (EHOs) in the quiescent H-mode regime has been developed, which successfully reproduces the recent observations in the DIII-D tokamak. In particular, at high E  ×  B flow shear only a few low-n kink modes remain unstable at the plasma edge, consistent with the EHO behavior, while at low E  ×  B flow shear, the unstable mode spectrum is significantly broadened, consistent with the low-n broadband electromagnetic turbulence behavior. The model is based on a new mechanism for destabilizing low-n kink/peeling modes by the E  ×  B flow shear, which underlies the EHOs, separately from the previously found Kelvin–Helmholtz drive. We find that the differential advection of mode vorticity by sheared E  ×  B flows modifies the 2D pattern of mode electrostatic potential perpendicular to the magnetic field lines, which in turn causes a radial expansion of the mode structure, an increase of field line bending away from the mode rational surface, and a reduction of inertial stabilization. This enhances the kink drive as the parallel wavenumber increases significantly away from the rational surface at the plasma edge where the magnetic shear is also strong. This destabilization is also shown to be independent of the sign of the flow shear, as observed experimentally, and has not been taken into account in previous pedestal linear stability analyses. Verification of the veracity of this EHO mechanism will require analysis of the nonlinear evolution of low-n kink/peeling modes so destabilized in the linear regime. [ABSTRACT FROM AUTHOR]

Published

2017

6. Bifurcation of quiescent H-mode to a wide pedestal regime in DIII-D and advances in the understanding of edge harmonic oscillations.

Author

Xi Chen, K.H. Burrell, T.H. Osborne, K. Barada, N.M. Ferraro, A.M. Garofalo, R.J. Groebner, G.R. McKee, C.C. Petty, M. Porkolab, T.L. Rhodes, J.C. Rost, P.B. Snyder, W.M. Solomon, Z. Yan, and Team, The DIII-D

Subjects

BIFURCATION theory, HARMONIC oscillators, QUIESCENT plasmas, ROTATIONAL flow, TORQUE control

Abstract

New experimental studies and modelling of the coherent edge harmonic oscillation (EHO), which regulates the conventional Quiescent H-mode (QH-mode) edge, validate the proposed hypothesis of edge rotational shear in destabilizing the low-n kink-peeling mode as the additional drive mechanism for the EHO. The observed minimum edge E  ×  B shear required for the EHO decreases linearly with pedestal collisionality , which is favorable for operating QH-mode in machines with low collisionality and low rotation such as ITER. In addition, the QH-mode regime in DIII-D has recently been found to bifurcate into a new ‘wide-pedestal’ state at low torque in double-null shaped plasmas, characterized by increased pedestal height, width and thermal energy confinement (Burrell 2016 Phys. Plasmas23 056103, Chen 2017 Nucl. Fusion57 022007). This potentially provides an alternate path for achieving high performance ELM-stable operation at low torque, in addition to the low-torque QH-mode sustained with applied 3D fields. Multi-branch low-k and intermediate-k turbulences are observed in the ‘wide-pedestal’. New experiments support the hypothesis that the decreased edge E  ×  B shear enables destabilization of broadband turbulence, which relaxes edge pressure gradients, improves peeling-ballooning stability and allows a wider and thus higher pedestal. The ability to accurately predict the critical E  ×  B shear for EHO and maintain high performance QH-mode at low torque is an essential requirement for projecting QH-mode operation to ITER and future machines. [ABSTRACT FROM AUTHOR]

Published

2017

7. NIMROD modeling of quiescent H-mode: reconstruction considerations and saturation mechanism.

Author

J.R. King, K.H. Burrell, A.M. Garofalo, R.J. Groebner, S.E. Kruger, A.Y. Pankin, and P.B. Snyder

Subjects

H-mode plasma confinement, MAGNETOHYDRODYNAMICS, PLASMA boundary layers, TURBULENCE, PLASMA density

Abstract

The extended-MHD NIMROD code (Sovinec and King 2010 J. Comput. Phys. 229 5803) models broadband-MHD activity from a reconstruction of a quiescent H-mode shot on the DIII-D tokamak (Luxon 2002 Nucl. Fusion42 614). Computations with the reconstructed toroidal and poloidal ion flows exhibit low- perturbations (–5) that grow and saturate into a turbulent-like MHD state. The workflow used to project the reconstructed state onto the NIMROD basis functions re-solves the Grad–Shafranov equation and extrapolates profiles to include scrape-off-layer currents. Evaluation of the transport from the turbulent-like MHD state leads to a relaxation of the density and temperature profiles. [ABSTRACT FROM AUTHOR]

Published

2017

8. Stationary QH-mode plasmas with high and wide pedestal at low rotation on DIII-D.

Author

Xi Chen, K.H. Burrell, T.H. Osborne, W.M. Solomon, K. Barada, A.M. Garofalo, R.J. Groebner, N.C. Luhmann, G.R. McKee, C.M. Muscatello, M. Ono, C.C. Petty, M. Porkolab, T.L. Rhodes, J.C. Rost, P.B. Snyder, G.M. Staebler, B.J. Tobias, Z. Yan, and Team, the DIII-D

Subjects

H-mode plasma confinement, HARMONIC oscillators, NEUTRAL beams, SHEAR flow, TORQUE

Abstract

A stationary, quiescent H-mode (QH-mode) regime with a wide pedestal and improved confinement at low rotation has been discovered on DIII-D with reactor relevant edge parameters and no ELMs. As the injected neutral beam torque is ramped down and the edge E  ×  B rotation shear reduces, the transition from standard QH to the wide pedestal QH-mode occurs. At the transition, the coherent edge harmonic oscillations (EHO) that usually regulate the standard QH edge cease and broadband edge MHD modes appear along with a rapid increase in the pedestal pressure height (by  ⩽60%) and width (by  ⩽50%). We posit that the enhanced edge turbulence-driven transport, enabled by the lower edge E  ×  B flow shear due to lower torque reduces the pedestal gradient and, combined with the high edge instability limit provided by the balanced double-null plasma shape, permits the development of a broader and thus higher pedestal that is turbulence-transport-limited. Even with the significantly enhanced pedestal pressure, the edge operating point is below the peeling ballooning mode stability boundary and thus without ELMs. Improved transport in the outer core region (0.8  ⩽  ρ  ⩽0.9) owing to increased E  ×  B flow shear in that region and the enhanced pedestal boost the overall confinement by up to 45%. These findings advance the physics basis for developing stationary ELM-free high-confinement operation at low rotation for future burning plasma where similar collisionality and rotation levels are expected. [ABSTRACT FROM AUTHOR]

Published

2017

9. Rotational shear effects on edge harmonic oscillations in DIII-D quiescent H-mode discharges.

Author

Xi Chen, K.H. Burrell, N.M. Ferraro, T.H. Osborne, M.E. Austin, A.M. Garofalo, R.J. Groebner, G.J. Kramer, N.C. Luhmann Jr, G.R. McKee, C.M. Muscatello, R. Nazikian, X. Ren, P.B. Snyder, W.M. Solomon, B.J. Tobias, and Z. Yan

Subjects

SHEAR (Mechanics), HARMONIC oscillators, QUIESCENT plasmas, H-mode plasma confinement, HYDRODYNAMICS

Abstract

In the quiescent H-mode (QH-mode) regime, edge harmonic oscillations (EHOs) play an important role in avoiding transient edge localized mode (ELM) power fluxes by providing benign and continuous edge particle transport. A detailed theoretical, experimental and modeling comparison has been made of low-n (n  ⩽  5) EHO in DIII-D QH-mode plasmas. The calculated linear eigenmode structure from the extended magentoohydrodynamics (MHD) code M3D-C1 matches closely the coherent EHO properties from external magnetics data and internal measurements using the ECE, BES, ECE-Imaging and microwave imaging reflectometer (MIR) diagnostics, as well as the kink/peeling mode properties found by the ideal MHD code ELITE. Numerical investigations indicate that the low-n EHO-like solutions from M3D-C1 are destabilized by rotation and/or rotational shear while high-n modes are stabilized. This effect is independent of the rotation direction, suggesting that EHOs can be destabilized in principle with rotation in either direction. The modeling results are consistent with observations of EHO, support the proposed theory of the EHO as a low-n kink/peeling mode destabilized by edge E  ×  B rotational shear, and improve our understanding and confidence in creating and sustaining QH-mode in present and future devices. [ABSTRACT FROM AUTHOR]

Published

2016

10. Dependence of neoclassical toroidal viscosity on the poloidal spectrum of applied nonaxisymmetric fields.

Author

N.C. Logan, J.-K. Park, C. Paz-Soldan, M.J. Lanctot, S.P. Smith, and K.H. Burrell

Subjects

TOROIDAL plasma, VISCOSITY, TORQUE, COUPLING constants, NONLINEAR theories

Abstract

This paper presents a single mode model that accurately predicts the coupling of applied nonaxisymmetric fields to the plasma response that induces neoclassical toroidal viscosity (NTV) torque in DIII-D H-mode plasmas. The torque is measured and modeled to have a sinusoidal dependence on the relative phase of multiple nonaxisymmetric field sources, including a minimum in which large amounts of nonaxisymmetric drive is decoupled from the NTV torque. This corresponds to the coupling and decoupling of the applied field to a NTV-driving mode spectrum. Modeling using the perturbed equilibrium nonambipolar transport (PENT) code confirms an effective single mode coupling between the applied field and the resultant torque, despite its inherent nonlinearity. The coupling to the NTV mode is shown to have a similar dependence on the relative phasing as that of the IPEC dominant mode, providing a physical basis for the efficacy of this linear metric in predicting error field correction optima in NTV dominated regimes. [ABSTRACT FROM AUTHOR]

Published

2016

11. Characterization of density fluctuations during the search for an I-mode regime on the DIII-D tokamak.

Author

A. Marinoni, J.C. Rost, M. Porkolab, A.E. Hubbard, T.H. Osborne, A.E. White, D.G. Whyte, T.L. Rhodes, E.M. Davis, D.R. Ernst, and K.H. Burrell

Subjects

TOKAMAKS, H-mode plasma confinement, PLASMA instabilities, PLASMA fluctuations, L-mode plasma confinement

Abstract

The I-mode regime, routinely observed on the Alcator C-Mod tokamak, is characterized by an edge energy transport barrier without an accompanying particle barrier and with broadband instabilities, known as weakly coherent modes (WCM), believed to regulate particle transport at the edge.Recent experiments on the DIII-D tokamak exhibit I-mode characteristics in various physical quantities.These DIII-D plasmas evolve over long periods, lasting several energy confinement times, during which the edge electron temperature slowly evolves towards an H-mode-like profile, while maintaining a typical L-mode edge density profile. During these periods, referred to as I-mode phases, the radial electric field at the edge also gradually reaches values typically observed in H-mode.Density fluctuations measured with the phase contrast imaging diagnostic during I-mode phases exhibit three features typically observed in H-mode on DIII-D, although they develop progressively with time and without a sharp transition: the intensity of the fluctuations is reduced; the frequency spectrum is broadened and becomes non-monotonic; two dimensional space-time spectra appear to approach those in H-mode, showing phase velocities of density fluctuations at the edge increasing to about 10 km s−1. However, in DIII-D there is no clear evidence of the WCM.Preliminary linear gyro-kinetic simulations are performed in the pedestal region with the GS2 code and its recently upgraded model collision operator that conserves particles, energy and momentum. The increased bootstrap current and flow shear generated by the temperature pedestal are shown to decrease growth rates, thus possibly generating a feedback mechanism that progressively stabilizes fluctuations. [ABSTRACT FROM AUTHOR]

Published

2015

12. Super H-mode: theoretical prediction and initial observations of a new high performance regime for tokamak operation.

Author

P.B. Snyder, W.M. Solomon, K.H. Burrell, A.M. Garofalo, B.A. Grierson, R.J. Groebner, A.W. Leonard, R. Nazikian, T.H. Osborne, E.A. Belli, J. Candy, and H.R. Wilson

Subjects

H-mode plasma confinement, TOKAMAKS, THOMSON scattering, PHOTON scattering, ATOMIC scattering

Abstract

A new ‘Super H-mode’ regime is predicted, which enables pedestal height and predicted fusion performance substantially higher than for H-mode operation. This new regime is predicted to exist by the EPED pedestal model, which calculates criticality constraints for peeling–ballooning and kinetic ballooning modes, and combines them to predict the pedestal height and width. EPED usually predicts a single (‘H-mode’) pedestal solution for each set of input parameters, however, in strongly shaped plasmas above a critical density, multiple pedestal solutions are found, including the standard ‘H-mode’ solution, and a ‘Super H-Mode’ solution at substantially larger pedestal height and width. The Super H-mode regime is predicted to be accessible by controlling the trajectory of the density, and to increase fusion performance for ITER, as well as for DEMO designs with strong shaping. A set of experiments on DIII-D has identified the predicted Super H-mode regime, and finds pedestal height and width, and their variation with density, in good agreement with theoretical predictions from the EPED model. The very high pedestal enables operation at high global beta and high confinement, including the highest normalized beta achieved on DIII-D with a quiescent edge. [ABSTRACT FROM AUTHOR]

Published

2015

13. Extending the physics basis of quiescent H-mode toward ITER relevant parameters.

Author

W.M. Solomon, K.H. Burrell, M.E. Fenstermacher, A.M. Garofalo, B.A. Grierson, A. Loarte, G.R. McKee, R. Nazikian, T.H. Osborne, and P.B. Snyder

Subjects

QUIESCENT plasmas, H-mode plasma confinement, IMPURITY centers, TOROIDAL plasma

Abstract

Recent experiments on DIII-D have addressed several long-standing issues needed to establish quiescent H-mode (QH-mode) as a viable operating scenario for ITER. In the past, QH-mode was associated with low density operation, but has now been extended to high normalized densities compatible with operation envisioned for ITER. Through the use of strong shaping, QH-mode plasmas have been maintained at high densities, both absolute ( ) and normalized Greenwald fraction (). In these plasmas, the pedestal can evolve to very high pressure and edge current as the density is increased. High density QH-mode operation with strong shaping has allowed access to a previously predicted regime of very high pedestal dubbed ‘Super H-mode’. Calculations of the pedestal height and width from the EPED model are quantitatively consistent with the experimentally observed density evolution. The confirmation of the shape dependence of the maximum density threshold for QH-mode helps validate the underlying theoretical model of peeling-ballooning modes for edge localized mode (ELM) stability. In general, QH-mode is found to achieve ELM-stable operation while maintaining adequate impurity exhaust, due to the enhanced impurity transport from an edge harmonic oscillation, thought to be a saturated kink-peeling mode driven by rotation shear. In addition, the impurity confinement time is not affected by rotation, even though the energy confinement time and measured shear are observed to increase at low toroidal rotation. Together with demonstrations of high beta, high confinement and low for many energy confinement times, these results suggest QH-mode as a potentially attractive operating scenario for the ITER mission. [ABSTRACT FROM AUTHOR]

Published

2015

14. Response of impurity particle confinement time to external actuators in QH-mode plasmas on DIII-D.

Author

B.A. Grierson, K.H. Burrell, A.M. Garofalo, W.M. Solomon, A. Diallo, and M. O'Mullane

Subjects

H-mode plasma confinement, L-mode plasma confinement, ACTUATOR manufacturing, ACTUATOR testing, AUTOMATIC control systems

Abstract

A series of quiescent H-mode discharges has been executed with the specific aim of determining the particle confinement time of impurities in the presence of the edge harmonic oscillation. These discharges utilize non-intrinsic, non-recycling fully-stripped fluorine as the diagnostic species monitored by charge-exchange recombination spectroscopy. It is found that the edge harmonic oscillation is an efficient means of impurity expulsion from the core plasma, with impurity exhaust rates comparable to or exceeding those in companion ELMing discharges. As the external torque from neutral beam injection is lowered, the global energy confinement time increases while the impurity confinement time does not display an increase. [ABSTRACT FROM AUTHOR]

Published

2014