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1. Prediction of Performance and Turbulence in ITER Burning Plasmas via Nonlinear Gyrokinetic Profile Prediction

Author

Howard, N. T., Rodriguez-Fernandez, P., Holland, C., and Candy, J.

Subjects
Physics - Plasma Physics
Abstract

Burning plasma performance, transport, and the effect of hydrogen isotope on confinement has been predicted for ITER baseline scenario (IBS) conditions using nonlinear gyrokinetic profile predictions. Accelerated by surrogate modeling [P. Rodriguez-Fernandez NF 2022], high fidelity, nonlinear gyrokinetic simulations performed with the CGYRO code [J. Candy JCP 2016], were used to predict profiles of Ti, Te, and ne while including the effects of alpha heating, auxiliary power, collisional energy exchange, and radiation losses. Predicted profiles and resulting energy confinement are found to produce fusion power and gain that are approximately consistent with mission goals (Pfusion = 500MW at Q=10) for the baseline scenario and exhibit energy confinement that is within 1 sigma of the H-mode energy confinement scaling. The power of the surrogate modeling technique is demonstrated through the prediction of alternative ITER scenarios with reduced computational cost. These scenarios include conditions with maximized fusion gain and an investigation of potential Resonant Magnetic Perturbation effects on performance with a minimal number of gyrokinetic profile iterations required. These predictions highlight the stiff ITG nature of the core turbulence predicted in the ITER baseline and demonstrate that Q>17 conditions may be accessible by reducing auxiliary input power while operating in IBS conditions. Prediction of full kinetic profiles allowed for the projection of hydrogen isotope effects around ITER baseline conditions. The gyrokinetic fuel ion species was varied from H, D, and 50/50 D-T and kinetic profiles were predicted. Results indicate that a weak or negligible isotope effect will be observed to arise from core turbulence in ITER baseline scenario conditions. The resulting energy confinement, turbulence, and density peaking, and the implications for ITER operations will be discussed.

Published
2024

2. Core performance predictions in projected SPARC first-campaign plasmas with nonlinear CGYRO

Author

Rodriguez-Fernandez, P., Howard, N. T., Saltzman, A., Shoji, L., Body, T., Battaglia, D. J., Hughes, J. W., Candy, J., Staebler, G. M., and Creely, A. J.

Subjects
Physics - Plasma Physics, Physics - Computational Physics
Abstract

This work characterizes the core transport physics of SPARC early-campaign plasmas using the PORTALS-CGYRO framework. Empirical modeling of SPARC plasmas with L-mode confinement indicates an ample window of breakeven (Q>1) without the need of H-mode operation. Extensive modeling of multi-channel (electron energy, ion energy and electron particle) flux-matched conditions with the nonlinear CGYRO code for turbulent transport coupled to the macroscopic plasma evolution using PORTALS reveal that the maximum fusion performance to be attained will be highly dependent on the near-edge pressure. Stiff core transport conditions are found, particularly when fusion gain approaches unity, and predicted density peaking is found to be in line with empirical databases of particle source-free H-modes. Impurity optimization is identified as a potential avenue to increase fusion performance while enabling core-edge integration. Extensive validation of the quasilinear TGLF model builds confidence in reduced-model predictions. The implications of projecting L-mode performance to high-performance and burning-plasma devices is discussed, together with the importance of predicting edge conditions.

Published
2024

3. Enhancing predictive capabilities in fusion burning plasmas through surrogate-based optimization in core transport solvers

Author

Rodriguez-Fernandez, P., Howard, N. T., Saltzman, A., Kantamneni, S., Candy, J., Holland, C., Balandat, M., Ament, S., and White, A. E.

Subjects
Physics - Plasma Physics, Computer Science - Machine Learning, Physics - Computational Physics
Abstract

This work presents the PORTALS framework, which leverages surrogate modeling and optimization techniques to enable the prediction of core plasma profiles and performance with nonlinear gyrokinetic simulations at significantly reduced cost, with no loss of accuracy. The efficiency of PORTALS is benchmarked against standard methods, and its full potential is demonstrated on a unique, simultaneous 5-channel (electron temperature, ion temperature, electron density, impurity density and angular rotation) prediction of steady-state profiles in a DIII-D ITER Similar Shape plasma with GPU-accelerated, nonlinear CGYRO. This paper also provides general guidelines for accurate performance predictions in burning plasmas and the impact of transport modeling in fusion pilot plants studies.

Published
2023

4. Predictions of improved confinement in SPARC via energetic particle turbulence stabilization

Author

Di Siena, A., Rodriguez-Fernandez, P., Howard, N. T., Navarro, A. Banon, Bilato, R., Goerler, T., Poli, 1 E., Merlo, G., Wrigh, J., Greenwald, M., and Jenko, F.

Subjects
Physics - Plasma Physics
Abstract

The recent progress in high-temperature superconductor technologies has led to the design and construction of SPARC, a compact tokamak device expected to reach plasma breakeven with up to $25$MW of external ion cyclotron resonant heating (ICRH) power. This manuscript presents local (flux-tube) and radially global gyrokinetic GENE (Jenko et al 2000 Phys. Plasmas {\bf 7} 1904) simulations for a reduced-field and current H-mode SPARC scenario showing that supra-thermal particles - generated via ICRH - strongly suppress ion-scale turbulent transport by triggering a fast ion-induced anomalous transport barrier (F-ATB). The trigger mechanism is identified as a wave-particle resonant interaction between the fast particle population and plasma micro-instabilities (Di Siena et al 2021 Phys. Rev. Lett. {\bf 125} 025002). By performing a series of global simulations employing different profiles for the thermal ions, we show that the fusion gain of this SPARC scenario could be substantially enhanced up to $\sim 80\%$ by exploiting this fast ion stabilizing mechanism. A study is also presented to further optimize the energetic particle profiles, thus possibly leading experimentally to an even more significant fusion gain.

Published
2022
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5. Interpreting Radial Correlation Doppler Reflectometry using Gyrokinetic Simulations

Author

Ruiz, J. Ruiz, Parra, F. I., Hall-Chen, V. H., Christen, N., Barnes, M., Candy, J., Garcia, J., Giroud, C., Guttenfelder, W., Hillesheim, J. C., Holland, C., Howard, N. T., Ren, Y., White, A. E., and contributors., JET

Subjects
Physics - Plasma Physics
Abstract

A linear response, local model for the DBS amplitude applied to gyrokinetic simulations shows that radial correlation Doppler reflectometry measurements (RCDR, Schirmer et al., Plasma Phys. Control. Fusion 49 1019 (2007)) are not sensitive to the average turbulence radial correlation length, but to a correlation length that depends on the binormal wavenumber $k_\perp$ selected by the Doppler backscattering (DBS) signal. Nonlinear gyrokinetic simulations show that the turbulence naturally exhibits a non-separable power law spectrum in wavenumber space, leading to a power law dependence of the radial correlation length with binormal wavenumber $l_r \sim C k_\perp^{-\alpha} (\alpha \approx 1)$ which agrees with the inverse proportionality relationship between the measured $l_r$ and $k_\perp $ in experiments (Fernandez-Marina et al., Nucl. Fusion 54 072001 (2014)). This offers the possibility of characterizing the eddy aspect ratio in the perpendicular plane to the magnetic field and motivates future use of a non-separable turbulent spectrum to quantitatively interpret RCDR and potentially other turbulence diagnostics. The radial correlation length is only measurable when the radial resolution at the cutoff location $W_n$ satisfies $W_n \ll l_r$, while the measurement becomes dominated by $W_n$ for $W_n \gg l_r$. This suggests that $l_r$ is likely inaccessible for electron-scale DBS measurements ($k_\perp\rho_s > 1$). The effect of $W_n$ on ion-scale radial correlation lengths could be non-negligible., Comment: Total of 13 figures, 36 pages. TEX commands are included in the abstract for mathematical expressions. Submitted to Plasma Physics and Controlled Fusion

Published
2022
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6. Experimental Inference of Neutral and Impurity Transport in Alcator C-Mod Using High-Resolution X-Ray and Ultra-Violet Spectra

Author

Sciortino, F., Howard, N. T., Reksoatmodjo, R., Foster, A. R., Hughes, J. W., Marmar, E. S., Miller, M. A., Mordijck, S., Odstrcčil, T., Pütterich, T., Reinke, M. L., Rice, J. E., and Rodriguez-Fernandez, P.

Subjects
Physics - Plasma Physics, Physics - Atomic Physics
Abstract

We present experimental inferences of cross-field impurity transport coefficients for Alcator C-Mod plasmas using a novel forward model for the entire Ca K-alpha spectrum, including satellite lines within the spectral range, to compare to high-resolution X-ray Imaging Crystal Spectroscopy (XICS). These measurements are complemented by Extreme Ultra-Violet (EUV) spectroscopy that constrains transport closer to the edge. Using new atomic data sets for both XICS and EUV analysis has enabled consideration of line ratios across both spectral ranges and has increased the accuracy of inferred transport coefficients. Inclusion of charge exchange between edge thermal neutrals and impurities is shown to be extremely important in C-Mod pedestals. We obtain D atomic neutral densities from experimental D Ly-alpha measurements at the midplane and compare these to SOLPS-ITER simulations, finding good agreement. Bayesian inferences of impurity transport coefficients are presented for L-, EDA H-, and I-mode discharges, making use of the Aurora package for forward modeling and combining our spectroscopic constraints. Experimentally inferred diffusion profiles are found to match turbulent transport models at midradius within uncertainties, using both quasilinear gyro-fluid TGLF SAT-1 and nonlinear ion-scale gyrokinetic CGYRO simulations. Significant discrepancies in convection are observed in some cases, suggesting difficulties in predictions of flat or hollow impurity profiles., Comment: 23 pages of main body; 38 pages including appendices. 17 figures. Submitted to Nuclear Fusion

Published
2021
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7. Modeling of Particle Transport, Neutrals and Radiation in Magnetically-Confined Plasmas with Aurora

Author

Sciortino, F., Odstrčil, T., Cavallaro, A., Smith, S., Meneghini, O., Reksoatmodjo, R., Linder, O., Lore, J. D., Howard, N. T., Marmar, E. S., and Mordijck, S.

Subjects
Physics - Plasma Physics, Physics - Applied Physics, Physics - Computational Physics, Physics - Data Analysis, Statistics and Probability
Abstract

We present Aurora, an open-source package for particle transport, neutrals and radiation modeling in magnetic confinement fusion plasmas. Aurora's modern multi-language interface enables simulations of 1.5D impurity transport within high-performance computing frameworks, particularly for the inference of particle transport coefficients. A user-friendly Python library allows simple interaction with atomic rates from the Atomic Data and Atomic Structure database as well as other sources. This enables a range of radiation predictions, both for power balance and spectroscopic analysis. We discuss here the superstaging approximation for complex ions, as a way to group charge states and reduce computational cost, demonstrating its wide applicability within the Aurora forward model and beyond. Aurora also facilitates neutral particle analysis, both from experimental spectroscopic data and other simulation codes. Leveraging Aurora's capabilities to interface SOLPS-ITER results, we demonstrate that charge exchange is unlikely to affect the total radiated power from the ITER core during high performance operation. Finally, we describe the ImpRad module in the OMFIT framework, developed to enable experimental analysis and transport inferences on multiple devices using Aurora., Comment: 8 pages + references, 5 figures

Published
2021
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8. Inference of Experimental Radial Impurity Transport on Alcator C-Mod: Bayesian Parameter Estimation and Model Selection

Author

Sciortino, F., Howard, N. T., Marmar, E. S., Odstrcil, T., Cao, N. M., Dux, R., Hubbard, A. E., Hughes, J. W., Irby, J. H., Marzouk, Y., Milanese, L. M., Reinke, M. L., Rice, J. E., and Rodriguez-Fernandez, P.

Subjects
Physics - Plasma Physics, Physics - Applied Physics, Physics - Computational Physics, Physics - Data Analysis, Statistics and Probability
Abstract

We present a fully Bayesian approach for the inference of radial profiles of impurity transport coefficients and compare its results to neoclassical, gyrofluid and gyrokinetic modeling. Using nested sampling, the Bayesian Impurity Transport InferencE (BITE) framework can handle complex parameter spaces with multiple possible solutions, offering great advantages in interpretative power and reliability with respect to previously demonstrated methods. BITE employs a forward model based on the pySTRAHL package, built on the success of the well-known STRAHL code [Dux, IPP Report, 2004], to simulate impurity transport in magnetically-confined plasmas. In this paper, we focus on calcium (Ca, Z=20) Laser Blow-Off injections into Alcator C-Mod plasmas. Multiple Ca atomic lines are diagnosed via high-resolution X-ray Imaging Crystal Spectroscopy and Vacuum Ultra-Violet measurements. We analyze a sawtoothing I-mode discharge for which neoclassical and turbulent (quasilinear and nonlinear) predictions are also obtained. We find good agreement in diffusion across the entire radial extent, while turbulent convection and density profile peaking are estimated to be larger in experiment than suggested by theory. Efforts and challenges associated with the inference of experimental pedestal impurity transport are discussed., Comment: 38 pages, 19 figures, submitted for publication in Nuclear Fusion

Published
2020
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9. Effect of plasma elongation on current dynamics during tokamak disruptions

Author

Fülöp, T., Helander, P., Vallhagen, O., Embréus, O., Hesslow, L., Svensson, P., Creely, A. J., Howard, N. T., and Rodriguez-Fernandez, P.

Subjects
Physics - Plasma Physics
Abstract

Plasma terminating disruptions in tokamaks may result in relativistic runaway electron beams with potentially serious consequences for future devices with large plasma currents. In this paper we investigate the effect of plasma elongation on the coupled dynamics of runaway generation and resistive diffusion of the electric field. We find that elongated plasmas are less likely to produce large runaway currents, partly due to the lower induced electric fields associated with larger plasmas, and partly due to direct shaping effects, which mainly lead to a reduction in the runaway avalanche gain., Comment: 11 pages, 3 figures

Published
2019
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11. Simultaneous reproduction of experimental profiles, fluxes, transport coefficients, and turbulence characteristics via nonlinear gyrokinetic profile predictions in a DIII-D ITER similar shape plasma

Author

Howard, N. T., primary, Rodriguez-Fernandez, P., additional, Holland, C., additional, Odstrcil, T., additional, Grierson, B., additional, Sciortino, F., additional, McKee, G., additional, Yan, Z., additional, Wang, G., additional, Rhodes, T. L., additional, White, A. E., additional, Candy, J., additional, and Chrystal, C., additional

Published
2024
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12. A new synthetic correlation electron cyclotron emission diagnostic for validating nonlinear gyrokinetic simulations of electron temperature turbulence.

Author

Wang, G., Rhodes, T. L., Howard, N. T., and Peebles, W. A.

Subjects
ELECTRON emission, ELECTRON temperature, ELECTRON configuration, ANTENNA radiation patterns, TRANSFER functions, PLASMA turbulence
Abstract

To validate nonlinear gyrokinetic simulations of electron temperature turbulence, the experimental correlation electron cyclotron emission (CECE) measurements are to be compared using a synthetic CECE diagnostic, which generates modeled CECE measurement quantities by implementing realistic measurement parameters (e.g., spatial and wavenumber resolutions, radial location, etc.) to nonlinear gyrokinetic simulations. In this work, we calculate the radial and vertical spatial and wavenumber transfer functions, which are defined by the electron cyclotron emission emissivity radial profile and vertical probing antenna pattern, respectively. These transfer functions are applied to nonlinear gyrokinetic simulations of electron temperature turbulence using the continuum gyrokinetic code. A simultaneous comparison of the experimental electron temperature turbulence power spectrum and root-mean-square (RMS) level, as well as the radial correlation length with the new synthetic CECE diagnostic at a core location ρ ∼ 0.75 in an L-mode DIII-D tokamak plasma, is presented. The preliminary result shows that the synthetic CECE output underestimates the RMS level by ∼42% and overestimates the radial correlation length by ∼40%. [ABSTRACT FROM AUTHOR]

Published
2024
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13. Simulating energetic ions and enhanced fusion rates from ion-cyclotron resonance heating with a full-wave/Fokker–Planck model.

Author

Frank, S. J., Wright, J. C., Rodriguez-Fernandez, P., Howard, N. T., and Bonoli, P. T.

Subjects
CYCLOTRON resonance, FAST ions, LARMOR radius, RESONANCE, RADIO frequency, TENSOR products
Abstract

Reproducing fast-ion enhanced fusion rates from ion-cyclotron resonance heating (ICRH) in tokamaks requires the self-consistent coupling of a full-wave solver and a Fokker–Planck solver, which evolves multiple simultaneously resonant ion species. We introduce a new self-consistent model that iterates the TORIC full-wave solver with the CQL3D Fokker–Planck solver using the integrated plasma simulator (IPS). This model evolves the bounce-averaged ion distribution functions in both parallel and perpendicular velocity-space with a quasilinear radio frequency (RF) diffusion operator valid in the ion finite Larmor radius (FLR) limit and the RF electric fields with the resultant non-Maxwellian FLR dielectric tensor. This produces non-Maxwellian ICRH simulations that are fully self-consistent, fast, and interoperable with integrated modeling frameworks, such as TRANSP/GACODE/IPS-FASTRAN. We demonstrate our model's capabilities by validating it against experimental data in Alcator C-Mod. We then perform the first RF heating simulations of SPARC using self-consistent non-Maxwellian ion distributions to investigate the potential to enhance fusion rates using ion cyclotron resonance heating generated fast ions. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Investigation of core impurity transport in DIII-D diverted negative triangularity plasmas

Author

Sciortino, F, primary, Howard, N T, additional, Odstrčil, T, additional, Austin, M, additional, Bykov, I, additional, Chrystal, C, additional, Haskey, S R, additional, Lore, J D, additional, Marinoni, A, additional, Marmar, E S, additional, Meneghini, O, additional, Paz-Soldan, C, additional, Rodriguez-Fernandez, P, additional, Smith, S P, additional, and Thome, K E, additional

Published
2022
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20. Overview of the SPARC tokamak

Author

Creely, A. J., Greenwald, M. J., Ballinger, S. B., Brunner, D., Canik, J., Doody, J., Fulop, T., Garnier, D. T., Granetz, R., Gray, T. K., Holland, C., Howard, N. T., Hughes, J. W., Irby, J. H., Izzo, V. A., Kramer, G. J., Kuang, A. Q., LaBombard, B., Lin, Yijun, Lipschultz, B., Logan, N. C., Lore, J. D., Marmar, E. S., Montes, K., Mumgaard, R. T., Paz-Soldan, C., Rea, C., Reinke, M. L., Rodriguez-Fernandez, P., Sarkimaki, K., Sciortino, F., Scott, S. D., Snicker, A., Snyder, P. B., Sorbom, B. N., Sweeney, R., Tinguely, R. A., Tolman, E. A., Umansky, M., Vallhagen, O., Varje, J., Whyte, D. G., Wright, J. C., Wukitch, S. J., Zhu, J., SPARC Team, Department of Applied Physics, Aalto-yliopisto, and Aalto University

Subjects
Tokamak, DATABASE, fusion plasma, Fusion plasma, Plasma confinement, 01 natural sciences, 010305 fluids & plasmas, law.invention, PHYSICS, PLASMA-FACING COMPONENTS, DESIGN, law, 0103 physical sciences, 010306 general physics, PROGRESS, DEMO, Physics, plasma confinement, TUNGSTEN, CONSTRUCTION, Fusion power, Condensed Matter Physics, H-MODE CONFINEMENT, plasma devices, Systems engineering, CHAPTER 2
Abstract

The SPARC tokamak is a critical next step towards commercial fusion energy. SPARC is designed as a high-field ($B_0 = 12.2$T), compact ($R_0 = 1.85$m,$a = 0.57$m), superconducting, D-T tokamak with the goal of producing fusion gain$Q>2$from a magnetically confined fusion plasma for the first time. Currently under design, SPARC will continue the high-field path of the Alcator series of tokamaks, utilizing new magnets based on rare earth barium copper oxide high-temperature superconductors to achieve high performance in a compact device. The goal of$Q>2$is achievable with conservative physics assumptions ($H_{98,y2} = 0.7$) and, with the nominal assumption of$H_{98,y2} = 1$, SPARC is projected to attain$Q \approx 11$and$P_{\textrm {fusion}} \approx 140$MW. SPARC will therefore constitute a unique platform for burning plasma physics research with high density ($\langle n_{e} \rangle \approx 3 \times 10^{20}\ \textrm {m}^{-3}$), high temperature ($\langle T_e \rangle \approx 7$keV) and high power density ($P_{\textrm {fusion}}/V_{\textrm {plasma}} \approx 7\ \textrm {MW}\,\textrm {m}^{-3}$) relevant to fusion power plants. SPARC's place in the path to commercial fusion energy, its parameters and the current status of SPARC design work are presented. This work also describes the basis for global performance projections and summarizes some of the physics analysis that is presented in greater detail in the companion articles of this collection.

Published
2020

22. Edge turbulence measurements in L-mode and I-mode at ASDEX Upgrade.

Author

Bielajew, R., Conway, G. D., Griener, M., Happel, T., Höfler, K., Howard, N. T., Hubbard, A. E., McCarthy, W., Molina Cabrera, P. A., Nishizawa, T., Rodriguez-Fernandez, P., Silvagni, D., Vanovac, B., Wendler, D., Yoo, C., and White, A. E.

Subjects
PLASMA turbulence, TURBULENCE, ELECTRON emission, ELECTRON configuration, EDGES (Geometry)
Abstract

The I-mode confinement regime is promising for future reactor operation due to high energy confinement without high particle confinement. However, the role of edge turbulence in creating I-mode's beneficial transport properties is still unknown. New measurements of edge turbulence ( ρ pol = 0.9 − 1.0) in L-modes and I-modes at low and high densities at ASDEX Upgrade are presented in this paper. A high radial resolution correlation electron cyclotron emission radiometer measures the broadband turbulence throughout the L-mode and I-mode edge and pedestal. The weakly coherent mode (WCM) is measured in both L-mode and I-mode near the last closed flux surface with Te fluctuation levels of 2.3%–4.2%, with a frequency shift between the two phases related to a deeper Er well in I-mode. An n e T e phase diagnostic captures a change of the WCM n e T e phase between L-mode and I-mode from − 171 ° to − 143 °. The thermal He beam diagnostic measures a WCM wavenumber range of −0.5 to −1.0 cm−1. A low-frequency edge oscillation (LFEO) appears in the I-mode phase of these discharges and displays coupling to the WCM, but the LFEO does not appear in the L-mode phase. Linear gyrokinetic simulations of the outer core and pedestal top turbulence indicate that while the dominant turbulent modes in the outer core are ion directed and electrostatic, the turbulence becomes increasingly electron directed and electromagnetic with increasing radius. Collisionality is not found to impact characteristics of the L-mode and I-mode edge turbulence with respect to the presence of the WCM; however, the quality of global confinement decreases with collisionality. [ABSTRACT FROM AUTHOR]

Published
2022
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23. Correlation ECE diagnostic in Alcator C-Mod

Author

Sung C., White A. E., Howard N. T., Mikkelsen D., Irby J., Leccacorvi R., Vieira R., Oi C., Rice J., Reinke M., Gao C., Ennever P., Porkolab M., Churchill R., Theiler C., Walk J., Hughes J., Hubbard A., and Greenwald M.

Subjects
Physics, QC1-999
Abstract

Correlation ECE (CECE) is a diagnostic technique that allows measurement of small amplitude electron temperature, Te, fluctuations through standard cross-correlation analysis methods. In Alcator C-Mod, a new CECE diagnostic has been installed[Sung RSI 2012], and interesting phenomena have been observed in various plasma conditions. We find that local Te fluctuations near the edge (ρ ~ 0:8) decrease across the linearto- saturated ohmic confinement transition, with fluctuations decreasing with increasing plasma density[Sung NF 2013], which occurs simultaneously with rotation reversals[Rice NF 2011]. Te fluctuations are also reduced across core rotation reversals with an increase of plasma density in RF heated L-mode plasmas, which implies that the same physics related to the reduction of Te fluctuations may be applied to both ohmic and RF heated L-mode plasmas. In I-mode plasmas, we observe the reduction of core Te fluctuations, which indicates changes of turbulence occur not only in the pedestal region but also in the core across the L/I transition[White NF 2014]. The present CECE diagnostic system in C-Mod and these experimental results are described in this paper.

Published
2015
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29. Predict-first experiments and modeling of perturbative cold pulses in the DIII-D tokamak

Author

Rodriguez-Fernandez, P., primary, White, A. E., additional, Howard, N. T., additional, Grierson, B. A., additional, Zeng, L., additional, Yuan, X., additional, Staebler, G. M., additional, Austin, M. E., additional, Odstrcil, T., additional, Rhodes, T. L., additional, Sciortino, F., additional, Rice, J. E., additional, Thome, K. E., additional, Angioni, C., additional, Fable, E., additional, and Meneghini, O., additional

Published
2019
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30. Electron critical gradient scale length measurements of ICRF heated L-mode plasmas at Alcator C-Mod tokamak

Author

Houshmandyar, S., primary, Hatch, D. R., additional, Horton, C. W., additional, Liao, K. T., additional, Phillips, P. E., additional, Rowan, W. L., additional, Zhao, B., additional, Cao, N. M., additional, Ernst, D. R., additional, Greenwald, M., additional, Howard, N. T., additional, Hubbard, A. E., additional, Hughes, J. W., additional, and Rice, J. E., additional

Published
2018
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33. Explaining Cold-Pulse Dynamics in Tokamak Plasmas Using Local Turbulent Transport Models

Author

Rodriguez-Fernandez, P., primary, White, A. E., additional, Howard, N. T., additional, Grierson, B. A., additional, Staebler, G. M., additional, Rice, J. E., additional, Yuan, X., additional, Cao, N. M., additional, Creely, A. J., additional, Greenwald, M. J., additional, Hubbard, A. E., additional, Hughes, J. W., additional, Irby, J. H., additional, and Sciortino, F., additional

Published
2018
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34. X-ray observations of ${{\rm{K}}}_{\beta }$ emission from mediumZHe-like ions in C-Mod tokamak plasmas

Author

Rice, J E, primary, Rosmej, F B, additional, Cao, N, additional, Chilenski, M, additional, Howard, N T, additional, Hubbard, A E, additional, Hughes, J W, additional, Irby, J H, additional, Lin, Y, additional, Rodriguez-Fernandez, P, additional, Wolfe, S M, additional, Wukitch, S J, additional, Bitter, M, additional, Delgado-Aparicio, L, additional, Hill, K, additional, and Reinke, M L, additional

Published
2018
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35. Impurity transport, turbulence transitions and intrinsic rotation in Alcator C-Mod plasmas

Author

Massachusetts Institute of Technology. Plasma Science and Fusion Center, White, Anne, White, Anne E., Greenwald, Martin J, Rice, John E, Holland, C., Howard, N. T., Massachusetts Institute of Technology. Plasma Science and Fusion Center, White, Anne, White, Anne E., Greenwald, Martin J, Rice, John E, Holland, C., and Howard, N. T.

Abstract

Linear and nonlinear gyrokinetic simulations are used to probe turbulent impurity transport in intrinsically rotating tokamak plasmas. For this simulation-based study, experimental input parameters are taken from a pair of ICRF heated Alcator C-Mod discharges exhibiting a change in the sign of the normalized toroidal rotation gradient at mid-radius (i.e. a change from hollow to peaked intrinsic rotation profiles). The simulations show that there is no change in the peaking of the calcium impurity between the plasmas with peaked and hollow rotation profiles, suggesting that the impurity transport and the shape of the rotation do not always change together. Furthermore, near mid-radius, r/a = 0.5 (normalized midplane minor radius), the linear and nonlinear gyrokinetic simulations exhibit no evidence of a transition from ion temperature gradient (ITG) to trapped electron mode dominance when the intrinsic rotation profile changes from peaked to hollow. Extensive nonlinear sensitivity analysis is performed, and there is no change in the ITG critical gradient or in the stiffness of ion heat transport with the change in the intrinsic toroidal rotation profile shape, which suggests that the shape of the rotation profile is not dominated by the ITG onset in these cases., United States. Department of Energy (contract DE-FC02-99ER54512-CMOD), United States. Department of Energy (Fusion Energy Postdoctoral Research Program)

Published
2017

42. Multispecies density peaking in gyrokinetic turbulence simulations of low collisionality Alcator C-Mod plasmas

Author

Mikkelsen, D. R., primary, Bitter, M., additional, Delgado-Aparicio, L., additional, Hill, K. W., additional, Greenwald, M., additional, Howard, N. T., additional, Hughes, J. W., additional, Rice, J. E., additional, Reinke, M. L., additional, Podpaly, Y., additional, Ma, Y., additional, Candy, J., additional, and Waltz, R. E., additional

Published
2015
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44. Nonlinear gyrokinetic simulations of the I-mode high confinement regime and comparisons with experimenta)

Author

White, A. E., primary, Howard, N. T., additional, Creely, A. J., additional, Chilenski, M. A., additional, Greenwald, M., additional, Hubbard, A. E., additional, Hughes, J. W., additional, Marmar, E., additional, Rice, J. E., additional, Sierchio, J. M., additional, Sung, C., additional, Walk, J. R., additional, Whyte, D. G., additional, Mikkelsen, D. R., additional, Edlund, E. M., additional, Kung, C., additional, Holland, C., additional, Candy, J., additional, Petty, C. C., additional, Reinke, M. L., additional, and Theiler, C., additional

Published
2015
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