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207 results on '"Granetz, R. S."'

1. On the minimum transport required to passively suppress runaway electrons in SPARC disruptions

Author

Tinguely, R. A., Pusztai, I., Izzo, V. A., S'"arkimäki, K., Fülöp, T., Garnier, D. T., Granetz, R. S., Hoppe, M., Paz-Soldan, C., Sundström, A., and Sweeney, R.

Subjects
Physics - Plasma Physics
Abstract

In [V.A. Izzo et al 2022 Nucl. Fusion 62 096029], state-of-the-art modeling of thermal and current quench (CQ) MHD coupled with a self-consistent evolution of runaway electron (RE) generation and transport showed that a non-axisymmetric (n = 1) in-vessel coil could passively prevent RE beam formation during disruptions in SPARC, a compact high-field tokamak projected to achieve a fusion gain Q > 2 in DT plasmas. However, such suppression requires finite transport of REs within magnetic islands and re-healed flux surfaces; conservatively assuming zero transport in these regions leads to an upper bound of RE current ~1 MA compared to ~8.7 MA of pre-disruption plasma current. Further investigation finds that core-localized electrons, within r/a < 0.3 and with kinetic energies 0.2-15 MeV, contribute most to the RE plateau formation. Yet only a relatively small amount of transport, i.e. a diffusion coefficient ~18 $\mathrm{m^2/s}$, is needed in the core to fully mitigate these REs. Properly accounting for (i) the CQ electric field's effect on RE transport in islands and (ii) the contribution of significant RE currents to disruption MHD may help achieve this.

Published
2023
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2. Runaway electron deconfinement in SPARC and DIII-D by a passive 3D coil

Author

Izzo, V. A., Pusztai, I., Särkimäki, K., Sundström, A., Garnier, D., Weisberg, D., Tinguely, R. A., Paz-Soldan, C., Granetz, R. S., and Sweeney, R.

Subjects
Physics - Plasma Physics
Abstract

The operation of a 3D coil--passively driven by the current quench loop voltage--for the deconfinement of runaway electrons is modeled for disruption scenarios in the SPARC and DIII-D tokamaks. Nonlinear MHD modeling is carried out with the NIMROD code including time-dependent magnetic field boundary conditions to simulate the effect of the coil. Further modeling in some cases uses the ASCOT5 code to calculate advection and diffusion coefficients for runaway electrons based on the NIMROD-calculated fields, and the DREAM code to compute the runaway evolution in the presence of these transport coefficients. Compared with similar modeling in Tinguely, et al [2021 Nucl. Fusion 61 124003], considerably more conservative assumptions are made with the ASCOT5 results, zeroing low levels of transport, particularly in regions in which closed flux surfaces have reformed. Of three coil geometries considered in SPARC, only the $n=1$ coil is found to have sufficient resonant components to suppress the runaway current growth. Without the new conservative transport assumptions, full suppression of the RE current is maintained when the TQ MHD is included in the simulation or when the RE current is limited to 250kA, but when transport in closed flux regions is fully suppressed, these scenarios allow RE beams on the order of 1-2MA to appear. Additional modeling is performed to consider the effects of the close ideal wall. In DIII-D, the current quench is modeled for both limited and diverted equilibrium shapes. In the limited shape, the onset of stochasticity is found to be insensitive to the coil current amplitude and governed largely by the evolution of the safety-factor profile. In both devices, prediction of the q-profile evolution is seen to be critical to predicting the later time effects of the coil.

Published
2022
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3. Scenario adaptive disruption prediction study for next generation burning-plasma tokamaks

Author

Zhu, J., Rea, C., Granetz, R. S., Marmar, E. S., Montes, K. J., Sweeney, R., Tinguely, R. A., Chen, D. L., Shen, B., Xiao, B. J., Humphreys, D., Barr, J., and Meneghini, O.

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

Next generation high performance (HP) tokamaks risk damage from unmitigated disruptions at high current and power. Achieving reliable disruption prediction for a device's HP operation based on its low performance (LP) data is key to success. In this letter, through explorative data analysis and dedicated numerical experiments on multiple existing tokamaks, we demonstrate how the operational regimes of tokamaks can affect the power of a trained disruption predictor. First, our results suggest data-driven disruption predictors trained on abundant LP discharges work poorly on the HP regime of the same tokamak, which is a consequence of the distinct distributions of the tightly correlated signals related to disruptions in these two regimes. Second, we find that matching operational parameters among tokamaks strongly improves cross-machine accuracy which implies our model learns from the underlying scalings of dimensionless physics parameters like q_{95}, \beta_{p} and confirms the importance of these parameters in disruption physics and cross machine domain matching from the data-driven perspective. Finally, our results show how in the absence of HP data from the target devices, the best predictivity of the HP regime for the target machine can be achieved by combining LP data from the target with HP data from other machines. These results provide a possible disruption predictor development strategy for next generation tokamaks, such as ITER and SPARC, and highlight the importance of developing on existing machines baseline scenario discharges of future tokamaks to collect more relevant disruptive data.

Published
2021
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4. Hybrid deep learning architecture for general disruption prediction across tokamaks

Author

Zhu, J. X., Rea, C., Montes, K., Granetz, R. S., Sweeney, R., and Tinguely, R. A.

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

In this paper, we present a new deep learning disruption prediction algorithm based on important findings from explorative data analysis which effectively allows knowledge transfer from existing devices to new ones, thereby predicting disruptions using very limited disruptive data from the new devices. The explorative data analysis conducted via unsupervised clustering techniques confirms that time-sequence data are much better separators of disruptive and non-disruptive behavior than the instantaneous plasma state data with further advantageous implications for a sequence-based predictor. Based on such important findings, we have designed a new algorithm for multi-machine disruption prediction that achieves high predictive accuracy on the C-Mod (AUC=0.801), DIII-D (AUC=0.947) and EAST (AUC=0.973) tokamaks with limited hyperparameter tuning. Through numerical experiments, we show that boosted accuracy (AUC=0.959) is achieved on EAST predictions by including in the training only 20 disruptive discharges, thousands of non-disruptive discharges from EAST, and combining this with more than a thousand discharges from DIII-D and C-Mod. The improvement of predictive ability obtained by combining disruptive data from other devices is found to be true for all permutations of the three devices. Furthermore, by comparing the predictive performance of each individual numerical experiment, we find that non-disruptive data are machine-specific while disruptive data from multiple devices contain device-independent knowledge that can be used to inform predictions for disruptions occurring on a new device.

Published
2020
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5. An application of survival analysis to disruption prediction via Random Forests

Author

Tinguely, R. A., Montes, K. J., Rea, C., Sweeney, R., and Granetz, R. S.

Subjects
Physics - Plasma Physics
Abstract

One of the most pressing challenges facing the fusion community is adequately mitigating or, even better, avoiding disruptions of tokamak plasmas. However, before this can be done, disruptions must first be predicted with sufficient warning time to actuate a response. The established field of survival analysis provides a convenient statistical framework for time-to-event (i.e. time-to-disruption) studies. This paper demonstrates the integration of an existing disruption prediction machine learning algorithm with the Kaplan-Meier estimator of survival probability. Specifically discussed are the implied warning times from binary classification of disruption databases and the interpretation of output signals from Random Forest algorithms trained and tested on these databases. This survival analysis approach is applied to both smooth and noisy test data to highlight important features of the survival and hazard functions. In addition, this method is applied to three Alcator C-Mod plasma discharges and compared to a threshold-based scheme for triggering alarms. In one case, both techniques successfully predict the disruption; although, in another, neither warns of the impending disruption with enough time to mitigate. For the final discharge, the survival analysis approach could avoid the false alarm triggered by the threshold method. Limitations of this analysis and opportunities for future work are also presented.

Published
2019
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6. Experimental and synthetic measurements of polarized synchrotron emission from runaway electrons in Alcator C-Mod

Author

Tinguely, R. A., Hoppe, M., Granetz, R. S., Mumgaard, R. T., and Scott, S.

Subjects
Physics - Plasma Physics
Abstract

This paper presents the first experimental analysis of polarized synchrotron emission from relativistic runaway electrons (REs) in a tokamak plasma. Importantly, we show that the polarization information of synchrotron radiation can be used to diagnose spatially-localized RE pitch angle distributions. Synchrotron-producing REs were generated during low density, Ohmic, diverted plasma discharges in the Alcator C-Mod tokamak. The ten-channel Motional Stark Effect diagnostic was used to measure spatial profiles of the polarization angle $\theta_{\mathrm{pol}}$ and the fraction $\mathrm{f}_{\mathrm{pol}}$ of detected light that was linearly-polarized. Spatial transitions in $\theta_{\mathrm{pol}}$ of 90$\deg$---from horizontal to vertical polarization and vice versa---are observed in experimental data and are well-explained by the gyro-motion of REs and high directionality of synchrotron radiation. Polarized synchrotron emission is modeled with the synthetic diagnostic SOFT; its output Green's (or detector response) functions reveal a critical RE pitch angle at which $\theta_{\mathrm{pol}}$ flips by 90$\deg$ and $\mathrm{f}_{\mathrm{pol}}$ is minimal. Using SOFT, we determine the dominant RE pitch angle which reproduces measured $\theta_{\mathrm{pol}}$ and $\mathrm{f}_{\mathrm{pol}}$ values. The spatiotemporal evolutions of $\theta_{\mathrm{pol}}$ and $\mathrm{f}_{\mathrm{pol}}$ are explored in detail for one C-Mod discharge. For channels viewing REs near the magnetic axis and flux surfaces $q$ = 1 and 4/3, disagreements between synthetic and experimental signals suggest that the sawtooth instability may be influencing RE dynamics. Furthermore, other sources of pitch angle scattering, not considered in this analysis, could help explain discrepancies between simulation and experiment.

Published
2019
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7. Spatiotemporal evolution of runaway electrons from synchrotron images in Alcator C-Mod

Author

Tinguely, R. A., Granetz, R. S., Hoppe, M., and Embréus, O.

Subjects
Physics - Plasma Physics
Abstract

In the Alcator C-Mod tokamak, relativistic runaway electron (RE) generation can occur during the flattop current phase of low density, diverted plasma discharges. Due to the high toroidal magnetic field (B = 5.4 T), RE synchrotron radiation is measured by a wide-view camera in the visible wavelength range (~400-900 nm). In this paper, a statistical analysis of over one thousand camera images is performed to investigate the plasma conditions under which synchrotron emission is observed in C-Mod. In addition, the spatiotemporal evolution of REs during one particular discharge is explored in detail via a thorough analysis of the distortion-corrected synchrotron images. To accurately predict RE energies, the kinetic solver CODE [Landreman et al 2014 Comput. Phys. Commun. 185 847-855] is used to evolve the electron momentum-space distribution at six locations throughout the plasma: the magnetic axis and flux surfaces q = 1, 4/3, 3/2, 2, and 3. These results, along with the experimentally-measured magnetic topology and camera geometry, are input into the synthetic diagnostic SOFT [Hoppe et al 2018 Nucl. Fusion 58 026032] to simulate synchrotron emission and detection. Interesting spatial structure near the surface q = 2 is found to coincide with the onset of a locked mode and increased MHD activity. Furthermore, the RE density profile evolution is fit by comparing experimental to synthetic images, providing important insight into RE spatiotemporal dynamics.

Published
2018
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8. Measurements of runaway electron synchrotron spectra at high magnetic fields in Alcator C-Mod

Author

Tinguely, R. A., Granetz, R. S., Hoppe, M., and Embreus, O.

Subjects
Physics - Plasma Physics
Abstract

In the Alcator C-Mod tokamak, runaway electron (RE) experiments have been performed during low density, flattop plasma discharges at three magnetic fields: 2.7, 5.4, and 7.8 T, the last being the highest field to-date at which REs have been generated and measured in a tokamak. Time-evolving synchrotron radiation spectra were measured in the visible wavelength range (~300-1000 nm) by two absolutely-calibrated spectrometers viewing co- and counter-plasma current directions. In this paper, a test particle model is implemented to predict momentum-space and density evolutions of REs on the magnetic axis and q = 1, 3/2, and 2 surfaces. Drift orbits and subsequent loss of confinement are also incorporated into the evolution. These spatiotemporal results are input into the new synthetic diagnostic SOFT [M. Hoppe, et al., Nucl. Fusion 58(2), 026032 (2018)] which reproduces experimentally-measured spectra. For these discharges, it is inferred that synchrotron radiation dominates collisional friction as a power loss mechanism and that RE energies decrease as magnetic field is increased. Additionally, the threshold electric field for RE generation, as determined by hard X-ray and photo-neutron measurements, is compared to current theoretical predictions.

Published
2018
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9. Kinetic modelling of runaway electron avalanches in tokamak plasmas

Author

Nilsson, E., Decker, J., Peysson, Y., Granetz, R. S., Saint-Laurent, F., and Vlainic, M.

Subjects
Physics - Plasma Physics
Abstract

Runaway electrons (REs) can be generated in tokamak plasmas if the accelerating force from the toroidal electric field exceeds the collisional drag force due to Coulomb collisions with the background plasma. In ITER, disruptions are expected to generate REs mainly through knock-on collisions, where enough momentum can be transferred from existing runaways to slow electrons to transport the latter beyond a critical momentum, setting off an avalanche of REs. Since knock-on runaways are usually scattered off with a significant perpendicular component of the momentum with respect to the local magnetic field direction, these particles are highly magnetized. Consequently, the momentum dynamics require a full 3-D kinetic description, since these electrons are highly sensitive to the magnetic non-uniformity of a toroidal configuration. A bounce-averaged knock-on source term is derived. The generation of REs from the combined effect of Dreicer mechanism and knock-on collision process is studied with the code LUKE, a solver of the 3-D linearized bounce-averaged relativistic electron Fokker-Planck equation, through the calculation of the response of the electron distribution function to a constant parallel electric field. This work shows that the avalanche effect can be important even in non-disruptive scenarios. RE formation through knock-on collisions is found to be strongly reduced when taking place off the magnetic axis, since trapped electrons cannot contribute to the RE population. The relative importance of the avalanche mechanism is investigated as a function of the key parameters for RE formation; the plasma temperature and the electric field strength. In agreement with theoretical predictions, the simulations show that in low temperature and E-field knock-on collisions are the dominant source of REs and can play a significant role for RE generation, including in non-disruptive scenarios., Comment: 23 pages, 12 figures

Published
2015

12. Development of the first non-planar REBCO stellarator coil using VIPER cable.

Author

Riva, N, Granetz, R S, Vieira, R, Hubbard, A, Pfeiffer, A T, Harris, P, Chamberlain, C, Hartwig, Z S, Watterson, A, Anderson, D, and Volberg, R

Subjects
*STELLARATORS, *HIGH temperature superconductors, *SUPERCONDUCTING magnets, *VIPERIDAE, *CRITICAL currents, *COPPER oxide, *MAGNETIC fields
Abstract

The benefits of operating fusion devices, such as tokamaks and stellarators, at high fields make high-temperature superconducting magnets necessary to realize a compact fusion power system. Superconducting stellarators, such as W7-X, have used standard low-temperature superconductor technology niobium-titanium. ARPA-E has recently funded a two-year project led by the startup Type One Energy and involving the Fusion Technology Institute at the University of Wisconsin-Madison, the Plasma Science to design and fabricate the first non-planar high-temperature superconductor (HTS) rare-earth barium copper oxide (REBCO) coil for a high-field stellarator based on the SPARC tokamak's VIPER cable concept. The design consists of a 1.5-turn non-planar REBCO coil supported by a pair of 3D printed stainless steel radial plates. The ultimate goals of the project are to determine if commercial REBCO tapes and additive manufacturing can be used to fabricate high field ( ⩾ 10 T ) non-planar coils with tight bending radii ( ≃ 100 m m ) and with a degradation of the critical current smaller than 20% with respect to the expected performance. In this work we present numerical analysis for non-planar coils (critical current, magnetic field map, Lorentz forces and quench aspects) at the operating conditions of 77 K and 20 K and the fabrication and testing in liquid nitrogen (77 K) of the first two non-planar demonstrators for stellarators based on a VIPER cable. The first demonstrator is a short NO n-planar V IP E R cab L e (cable demonstrator at which we will refer to as NOVEL) equipped with 100 HTS REBCO tapes and with a critical current of 5700 A at 77 K (self-field); the second is a M ult I ple turns (1.5-turns) NO n-pl AN ar coil (coil demonstrator at which we will refer to as MINOAN) equipped with 30 HTS tapes and with a critical current of 2100 A at 77 K (self-field). Both demonstrators were tested at 77 K (liquid nitrogen bath) and the results showed that—even after being bent into non-planar shapes with bend radii ≃ 100 m m —the degradation of the critical current I c was within 15%, meeting the expected goals of the project. [ABSTRACT FROM AUTHOR]

Published
2023
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21. Disruption prediction using a full convolutional neural network on EAST.

Author

Guo, B H, Shen, B, Chen, D L, Rea, C, Granetz, R S, Huang, Y, Zeng, L, Zhang, H, Qian, J P, Sun, Y W, and Xiao, B J

Subjects
CONVOLUTIONAL neural networks
Abstract

In this study, a full convolutional neural network is trained on a large database of experimental EAST data to classify disruptive discharges and distinguish them from non-disruptive discharges. The database contains 14 diagnostic parameters from the ∼104 discharges (disruptive and non-disruptive). The test set contains 417 disruptive discharges and 999 non-disruptive discharges, which are used to evaluate the performance of the model. The results reveal that the true positive (TP) rate is ∼ 0.827, while the false positive (FP) rate is ∼0.067. This indicates that 72 disruptive discharges and 67 non-disruptive discharges are misclassified in the test set. The FPs are investigated in detail and are found to emerge due to some subtle disturbances in the signals, which lead to misjudgment of the model. Therefore, hundreds of non-disruptive discharges from training set, containing time slices of small disturbances, are artificially added into the training database for retraining the model. The same test set is used to assess the performance of the improved model. The TP rate of the improved model increases up to 0.875, while its FP rate decreases to 0.061. Overall, the proposed data-driven predicted model exhibits immense potential for application in long pulse fusion devices such as ITER. [ABSTRACT FROM AUTHOR]

Published
2021
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28. MHD STABILITY, OPERATIONAL LIMITS AND DISRUPTIONS

Author

Hender, T. C., Wesley, J. C., Bialek, J., Bondeson, A., Boozer, A. H., Buttery, R. J., Garofalo, A., Goodman, T. P., Granetz, R. S., Gribov, Y., Gruber, O., Gryaznevich, M., Giruzzi, G., Günter, S., Hayashi, N., Helander, P., Hegna, C. C., Howell, D. F., Humphreys, D. A., Huysmans, G. T. A., Hyatt, A. W., Isayama, A., Jardin, S. C., Kawano, Y., Kellman, A., Kessel, C., Koslowski, H. R., La Haye, R. J., Lazzaro, E., Liu, Y. Q., Lukash, V., Manickam, J., Medvedev, S., Mertens, V., Mirnov, S. V., Nakamura, Y., Navratil, G., Okabayashi, M., Ozeki, T., Paccagnella, R., Pautasso, G., Porcelli, F., Pustovitov, V. D., Riccardo, V., Sato, M., Sauter, O., Schaffer, M. J., Shimada, M., Sonato, Piergiorgio, Strait, E. J., Sugihara, M., Takechi, M., Turnbull, A. D., Westerhof, E., Whyte, D. G., Yoshino, R., and Zohm, H.

Published
2007

30. Effects of Magnetic Shear on Toroidal Rotation in Tokamak Plasmas with Lower Hybrid Current Drive

Author

Rice, J. E., primary, Podpaly, Y. A., additional, Reinke, M. L., additional, Mumgaard, R., additional, Scott, S. D., additional, Shiraiwa, S., additional, Wallace, G. M., additional, Chouli, B., additional, Fenzi-Bonizec, C., additional, Nave, M. F. F., additional, Diamond, P. H., additional, Gao, C., additional, Granetz, R. S., additional, Hughes, J. W., additional, Parker, R. R., additional, Bonoli, P. T., additional, Delgado-Aparicio, L., additional, Eriksson, L.-G., additional, Giroud, C., additional, Greenwald, M. J., additional, Hubbard, A. E., additional, Hutchinson, I. H., additional, Irby, J. H., additional, Kirov, K., additional, Mailloux, J., additional, Marmar, E. S., additional, and Wolfe, S. M., additional

Published
2013
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31. Energetic ion loss detector on the Alcator C-Mod tokamak

Author

Pace, D. C., primary, Granetz, R. S., additional, Vieira, R., additional, Bader, A., additional, Bosco, J., additional, Darrow, D. S., additional, Fiore, C., additional, Irby, J., additional, Parker, R. R., additional, Parkin, W., additional, Reinke, M. L., additional, Terry, J. L., additional, Wolfe, S. M., additional, Wukitch, S. J., additional, and Zweben, S. J., additional

Published
2012
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37. H-Mode Pedestal and L-H Transition Studies on Alcator C-Mod

Author

Hughes, J. W., primary, Hubbard, A. E., additional, Mossessian, D. A., additional, LaBombard, B., additional, Biewer, T. M., additional, Granetz, R. S., additional, Greenwald, M., additional, Hutchinson, I. H., additional, Irby, J. H., additional, Lin, Y., additional, Marmar, E. S., additional, Porkolab, M., additional, Rice, J. E., additional, Snipes, J. A., additional, Terry, J. L., additional, Wolfe, S., additional, and Zhurovich, K., additional

Published
2007
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38. Spontaneous Toroidal Rotation in Alcator C-Mod Plasmas with No Momentum Input

Author

Rice, J. E., primary, Marmar, E. S., additional, Bonoli, P. T., additional, Granetz, R. S., additional, Greenwald, M. J., additional, Hubbard, A. E., additional, Hughes, J. W., additional, Hutchinson, I. H., additional, Irby, J. H., additional, LaBombard, B., additional, Lee, W. D., additional, Lin, Y., additional, Mossessian, D., additional, Snipes, J. A., additional, Wolfe, S. M., additional, and Wukitch, S. J., additional

Published
2007
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39. Energetic Particle Physics Studies on Alcator C-Mod

Author

Snipes, J. A., primary, Basse, N., additional, Bonoli, P., additional, Boswell, C., additional, Edlund, E., additional, Fasoli, A., additional, Granetz, R. S., additional, Lin, L., additional, Lin, Y., additional, Parker, R., additional, Porkolab, M., additional, Sears, J., additional, Tang, V., additional, and Wukitch, S., additional

Published
2007
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40. Diagnostic Systems on Alcator C-Mod

Author

Basse, N. P., primary, Dominguez, A., additional, Edlund, E. M., additional, Fiore, C. L., additional, Granetz, R. S., additional, Hubbard, A. E., additional, Hughes, J. W., additional, Hutchinson, I. H., additional, Irby, J. H., additional, LaBombard, B., additional, Lin, L., additional, Lin, Y., additional, Lipschultz, B., additional, Liptac, J. E., additional, Marmar, E. S., additional, Mossessian, D. A., additional, Parker, R. R., additional, Porkolab, M., additional, Rice, J. E., additional, Snipes, J. A., additional, Tang, V., additional, Terry, J. L., additional, Wolfe, S. M., additional, Wukitch, S. J., additional, Zhurovich, K., additional, Bravenec, R. V., additional, Phillips, P. E., additional, Rowan, W. L., additional, Kramer, G. J., additional, Schilling, G., additional, Scott, S. D., additional, and Zweben, S. J., additional

Published
2007
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41. Impurity Transport in Alcator C-Mod Plasmas

Author

Rice, J. E., primary, Terry, J. L., additional, Marmar, E. S., additional, Granetz, R. S., additional, Greenwald, M. J., additional, Hubbard, A. E., additional, Irby, J. H., additional, Wolfe, S. M., additional, and Pedersen, T. Sunn, additional

Published
2007
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43. Measurement of the Current Profile in Alcator C-Mod with Lower Hybrid Current Drive Using an Upgraded Motional Stark Effect Diagnostic.

Author

Mumgaard, R. T., Scott, S. D., Shiraiwa, S., Wallace, G. M., Parker, R. R., Hughes, J. W., and Granetz, R. S.

Subjects
CURRENT-drive heating, STARK effect, PLASMA gases, ELECTROOPTICS, PLASMA density, PLASMA pressure, PLASMA physics
Abstract

Upgrades to the motional Stark effect (MSE) diagnostic on Alcator C-mod have enabled accurate measurement of the current profile using pitch angle constrained magnetic equilibrium reconstructions. The MSE diagnostic utilizes an intrashot calibration technique along with kinetic profiles to constrain the reconstruction throughout the discharge. The system was used to study the current profile in plasmas with substantial Lower Hybrid Current Drive (LHCD), including fully non-inductive discharges sustained for several current relaxation times. The current profile evolution is reconstructed using the MSE data with 100ms time resolution as LHCD is applied to the plasma and as the plasma current profile relaxes back to inductively driven after LHCD ceases. The LH driven current is observed to be off-axis and significantly broadens the plasma current profile, resulting in qo above 1 and sawtooth suppression. In fully noninductive discharges the reconstructed q profile is flat or non-monotonic. In plasmas with significant LHCD the plasma evolves towards a non-inductive equilibrium but in certain discharges large MHD instabilities coincide with a significant reduction in current drive. The reconstructed driven current profile was measured over a variety of parameters including plasma current, launched n|| and LH power. The plasma density was varied over a range where previous work shows the current drive efficiency decreases precipitously from the classic efficiency scaling proportional to 1/ne. As the density is increased the LHCD modification of the current profile is observed to decrease, consistent with decreases in non-thermal ECE emission and hard X-ray production indicating negligible current drive. [ABSTRACT FROM AUTHOR]

Published
2014
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44. Active and fast particle driven Alfvén eigenmodes in Alcator C-Mod

Author

Snipes, J. A., primary, Basse, N., additional, Boswell, C., additional, Edlund, E., additional, Fasoli, A., additional, Gorelenkov, N. N., additional, Granetz, R. S., additional, Lin, L., additional, Lin, Y., additional, Parker, R., additional, Porkolab, M., additional, Sears, J., additional, Sharapov, S., additional, Tang, V., additional, and Wukitch, S., additional

Published
2005
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45. Nonaxisymmetric field effects on Alcator C-Mod

Author

Wolfe, S. M., primary, Hutchinson, I. H., additional, Granetz, R. S., additional, Rice, J., additional, Hubbard, A., additional, Lynn, A., additional, Phillips, P., additional, Hender, T. C., additional, Howell, D. F., additional, La Haye, R. J., additional, and Scoville, J. T., additional

Published
2005
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48. Fast-ions on Alcator C-Mod: Comparisons between Simulation and Experiment for Equilibrium and Evolving Distributions.

Author

Bader, A., Bonoli, P. T., Granetz, R. S., Harvey, R. W., Jaeger, E. F., Parker, R., and Wukitch, S. J.

Subjects
TOKAMAKS, FAST ions, COMPARATIVE studies, SIMULATION methods & models, PHYSICS experiments, FUSION reactors, ALPHA rays, PHOTODIODES
Abstract

Analysis of fast-ion distributions >100 Te is important for both ITER and a fusion reactor, as both will have a significant population of fusion-born alpha particles. Furthermore, energetic ions may display transport properties that differ from the bulk plasma. It is imperative to benchmark current simulation codes with measurements of highly energetic fast-ions on current devices. Experimental measurements of ICRF heated H-minority plasmas on Alcator C-Mod are performed with an upgraded Compact Neutral Particle Analyzer (CNPA). The CNPA consists of vertically-viewing photodiode detectors with viewing chords from r/a = ∼0.18 to 0.6 and energies from 150 keV to 1.5 MeV. The CNPA measurements are compared to the output of a synthetic diagnostic that has been added to the Fokker-Planck solver CQL3D. CQL3D is coupled with the full-wave solver AORSA to evolve a self-consistent fast-ion distribution. Good agreement is obtained between simulation and experiment for fast ion distributions that are in steady-state (df/dt = 0). However, there are discrepancies between the experimental and simulated results for the time-dependent evolution of the fast-ion distribution. A possible explanation of the discrepancy is due to violation of certain assumptions of quasi-linear theory. [ABSTRACT FROM AUTHOR]

Published
2011
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50. β limiting MHD activity and mode locking in Alcator C-Mod

Author

Snipes, J A, primary, Granetz, R S, additional, Hastie, R J, additional, Hubbard, A E, additional, In, Y, additional, Mossessian, D, additional, Rice, J E, additional, Ramos, J J, additional, Schmittdiel, D, additional, Taylor, G, additional, and Wolfe, S M, additional

Published
2002
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