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1. Characterizing the negative triangularity reactor core operating space with integrated modeling

Author

Wilson, H. S., Nelson, A. O., McClenaghan, J., Rodriguez-Fernandez, P., Parisi, J., and Paz-Soldan, C.

Subjects
Physics - Plasma Physics
Abstract

NT experiments have demonstrated core performance on par with positive triangularity (PT) H-mode without edge-localized modes (ELMs), encouraging further study of an NT reactor core. In this work, we use integrated modeling to scope the operating space around two NT reactor strategies: a high-field, compact fusion pilot plant concept and a low field, high aspect ratio concept. By integrating equilibrium, core transport, and edge ballooning instability models, we establish a range of operating points with less than 50 MW scrape-off layer power and fusion power comparable to positive triangularity (PT) H-mode reactor concepts. Heating and seeded impurities are leveraged to accomplish the same fusion performance and scrape-off layer exhaust power for various pressure edge boundary conditions. Scans over these pressure edge conditions accommodate any current uncertainty of the properties of the NT edge and show that the performance of an NT reactor will be extremely dependent on the edge pressure. The high-field case is found to enable lower scrape-off layer power because it is capable of reaching high fusion powers at a relatively compact size, which allows increased separatrix density without exceeding the Greenwald density limit. An increase in fusion power density is seen at weaker NT. Infinite-n ballooning instability models indicate that an NT reactor core can reach fusion powers comparable to leading PT H-mode reactor concepts while remaining ballooning-stable. Seeded krypton is leveraged to further lower scrape-off layer power since NT does not have a requirement to remain in H-mode. We contextualize the NT reactor operating space by comparing to popular PT H-mode reactor concepts, and find that NT exhibits competitive ELM-free performance with these concepts for a variety of edge conditions while maintaining relatively low scrape-off layer power., Comment: 23 pages, 14 figures. Submitted to Plasma Physics and Controlled Fusion Special Issue on Advances in the Physics Basis of Negative Triangularity Tokamaks

Published
2024

2. Achievement of highly radiating plasma in negative triangularity and effect of reactor-relevant seeded impurities on confinement and transport

Author

Casali, L., Eldon, D., Odstrcil, T., Mattes, R., Welsh, A., Lee, K., Nelson, A. O., Paz-Soldan, C., Khabanov, F., Cote, T., McLean, A. G., Scotti, F., and Thome, K. E.

Subjects
Physics - Plasma Physics
Abstract

The first achievement of highly radiating plasmas in negative triangularity is shown with an operational space featuring high core radiation at high Greenwald fraction obtained with the injection of reactor-relevant seeded gases. These negative triangularity (NT) shape diverted discharges reach high values of normalized plasma pressure (BetaN > 2) at high radiation fraction with no ELMs. We demonstrate that as long as the impurity level in the core is kept low to avoid excessive fuel dilution and impurity accumulation, integration of NT configuration with high radiation fraction not only is achievable but it can lead to confinement improvement with stabilization effects originating from collisionality, ExB shear and profiles changes due to impurity radiation cooling. The underlying physics mechanism is robust and holds for a variety of impurity species. The absence of the requirement to stay in H-mode translates in a higher core radiation fraction potentially allowed in NT shape effectively mitigating the power exhaust issue. The results presented here demonstrate a path to high performance, ELM free and highly radiative regime with rector-relevant seeding gases making this regime a potential new scenario for reactor operation.

Published
2024

3. Suppression of Edge Localized Modes in ITER Baseline Scenario in EAST using Edge Localized Magnetic Perturbations

Author

Xie, P., Sun, Y., Jia, M., Loarte, A., Liu, Y. Q., Ye, C., Gu, S., Sheng, H., Liang, Y., Ma, Q., Yang, H., Paz-Soldan, C. A., Deng, G., Fu, S., Chen, G., He, K., Jia, T., Lu, D., Lv, B., Qian, J., Wang, H. H., Wang, S., Weisberg, D., Wu, X., Xu, W., Yan, X., Yu, Y., Zang, Q., Zeng, L., Zhang, T., Zhou, C., Zhou, Z., Wan, B., and Team, the EAST

Subjects
Physics - Plasma Physics
Abstract

We report the suppression of Type-I Edge Localized Modes (ELMs) in the EAST tokamak under ITER baseline conditions using $n = 4$ Resonant Magnetic Perturbations (RMPs), while maintaining energy confinement. Achieving RMP-ELM suppression requires a normalized plasma beta ($\beta_N$) exceeding 1.8 in a target plasma with $q_{95}\approx 3.1$ and tungsten divertors. Quasi-linear modeling shows high plasma beta enhances RMP-driven neoclassical toroidal viscosity torque, reducing field penetration thresholds. These findings demonstrate the feasibility and efficiency of high $n$ RMPs for ELM suppression in ITER., Comment: 6 pages, 4 figures

Published
2024

4. First Access to ELM-free Negative Triangularity at Low Aspect Ratio

Author

Nelson, A. O., Vincent, C., Anand, H., Lovell, J., Parisi, J. F., Wilson, H. S., Imada, K., Wehner, W. P., Kochan, M., Blackmore, S., McArdle, G., Guizzo, S., Rondini, L., Freiberger, S., and Paz-Soldan, C.

Subjects
Physics - Plasma Physics
Abstract

A plasma scenario with negative triangularity (NT) shaping is achieved on MAST-U for the first time. While edge localized modes (ELMs) are eventually suppressed as the triangularity is decreased below $\delta$ < -0.06, an extended period of H-mode operation with Type-III ELMs is sustained at less negative $\delta$ even through access to the second stability region for ideal ballooning modes is closed. This documents a qualitative difference from the ELM-free access conditions documented in NT scenarios on conventional aspect ratio machines. The electron temperature at the pedestal top drops across the transition to ELM-free operation, but a steady rise in core temperature as $\delta$ is decreased allows for similar normalized beta in the ELM-free NT and H-mode positive triangularity shapes.

Published
2024

5. Power handling in a highly-radiative negative triangularity pilot plant

Author

Miller, M. A., Arnold, D., Wigram, M., Nelson, A. O., Witham, J., Rutherford, G., Choudhury, H., Cummings, C., Paz-Soldan, C., and Whyte, D. G.

Subjects
Physics - Plasma Physics
Abstract

This work explores power handling solutions for high-field, highly-radiative negative triangularity (NT) reactors based around the MANTA concept \cite{rutherford_manta_2024}. The divertor design is kept as simple as possible, opting for a standard divertor with standard leg length. FreeGS is used to create an equilibrium for the boundary region, prioritizing a short outer leg length of only $\sim$50 cm ($\sim$40\% of the minor radius). The UEDGE code package is used for the boundary plasma solution, to track plasma temperatures and fluxes to the divertor targets. It is found that for $P_\mathrm{SOL}$ = 25 MW and $n_\mathrm{sep} = 0.96 \times 10^{20}$ m$^{-3}$, conditions consistent with initial core transport modeling, little additional power mitigation is necessary. For external impurity injection of just 0.13\% Ne, the peak heat flux density at the more heavily loaded outer targets falls to 7.8 MW/m$^{2}$, while the electron temperature $T_\mathrm{e}$ remains just under 5 eV. Scans around the parameter space reveal that even at densities lower than in the primary operating scenario, $P_\mathrm{SOL}$ can be increased up to 50 MW, so long as a slightly higher fraction of extrinsic radiator is used. With less than 1\% neon (Ne) impurity content, the divertor still experiences less than 10 MW/m$^{2}$ at the outer target. Design of the plasma-facing components includes a close-fitting vacuum vessel with a tungsten inner surface as well as FLiBe-carrying cooling channels fashioned into the VV wall directly behind the divertor targets. For the seeded heat flux profile, Ansys Fluent heat transfer simulations estimate that the outer target temperature remains at just below 1550\degree C. Initial scoping of advanced divertor designs shows that for an X-divertor, detachment of the outer target becomes much simpler, and plasma fluxes to the targets drop considerably with only 0.01\% Ne content.

Published
2024

6. MANTA: A Negative-Triangularity NASEM-Compliant Fusion Pilot Plant

Author

MANTA Collaboration, Rutherford, G., Wilson, H. S., Saltzman, A., Arnold, D., Ball, J. L., Benjamin, S., Bielajew, R., de Boucaud, N., Calvo-Carrera, M., Chandra, R., Choudhury, H., Cummings, C., Corsaro, L., DaSilva, N., Diab, R., Devitre, A. R., Ferry, S., Frank, S. J., Hansen, C. J., Jerkins, J., Johnson, J. D., Lunia, P., van de Lindt, J., Mackie, S., Maris, A. D., Mandell, N. R., Miller, M. A., Mouratidis, T., Nelson, A. O., Pharr, M., Peterson, E. E., Rodriguez-Fernandez, P., Segantin, S., Tobin, M., Velberg, A., Wang, A. M., Wigram, M., Witham, J., Paz-Soldan, C., and Whyte, D. G.

Subjects
Physics - Plasma Physics
Abstract

The MANTA (Modular Adjustable Negative Triangularity ARC-class) design study investigated how negative-triangularity (NT) may be leveraged in a compact, fusion pilot plant (FPP) to take a ``power-handling first" approach. The result is a pulsed, radiative, ELM-free tokamak that satisfies and exceeds the FPP requirements described in the 2021 National Academies of Sciences, Engineering, and Medicine report ``Bringing Fusion to the U.S. Grid". A self-consistent integrated modeling workflow predicts a fusion power of 450 MW and a plasma gain of 11.5 with only 23.5 MW of power to the scrape-off layer (SOL). This low $P_\text{SOL}$ together with impurity seeding and high density at the separatrix results in a peak heat flux of just 2.8 MW/m$^{2}$. MANTA's high aspect ratio provides space for a large central solenoid (CS), resulting in ${\sim}$15 minute inductive pulses. In spite of the high B fields on the CS and the other REBCO-based magnets, the electromagnetic stresses remain below structural and critical current density limits. Iterative optimization of neutron shielding and tritium breeding blanket yield tritium self-sufficiency with a breeding ratio of 1.15, a blanket power multiplication factor of 1.11, toroidal field coil lifetimes of $3100 \pm 400$ MW-yr, and poloidal field coil lifetimes of at least $890 \pm 40$ MW-yr. Following balance of plant modeling, MANTA is projected to generate 90 MW of net electricity at an electricity gain factor of ${\sim}2.4$. Systems-level economic analysis estimates an overnight cost of US\$3.4 billion, meeting the NASEM FPP requirement that this first-of-a-kind be less than US\$5 billion. The toroidal field coil cost and replacement time are the most critical upfront and lifetime cost drivers, respectively.

Published
2024

7. Characterization of the ELM-free Negative Triangularity Edge on DIII-D

Author

Nelson, A. O., Schmitz, L., Cote, T., Parisi, J. F., Stewart, S., Paz-Soldan, C., Thome, K. E., Austin, M. E., Scotti, F., Barr, J. L., Hyatt, A., Leuthold, N., Marinoni, A., Neiser, T., Osborne, T., Richner, N., Welander, A. S., Wehner, W. P., Wilcox, R., Wilks, T. M., and Yang, J.

Subjects
Physics - Plasma Physics
Abstract

Tokamak plasmas with strong negative triangularity (NT) shaping typically exhibit fundamentally different edge behavior than conventional L-mode or H-mode plasmas. Over the entire DIII-D database, plasmas with sufficiently negative triangularity are found to be inherently free of edge localized modes (ELMs), even at injected powers well above the predicted L-H power threshold. A critical triangularly ($\delta_\mathrm{crit}\simeq-0.15$), consistent with inherently ELM-free operation is identified, beyond which access to the second stability region for infinite-$n$ ballooning modes closes on DIII-D. It is also possible to close access to this region, and thereby prevent an H-mode transition, at weaker average triangularities ($\delta\lesssim\delta_\mathrm{crit}$) provided that at least one of the two x-points is still sufficiently negative. Enhanced low field side magnetic fluctuations during ELM-free operation are consistent with additional turbulence limiting the NT edge gradient. Despite the reduced upper limit on the pressure gradient imposed by ballooning stability, NT plasmas are able to support small pedestals and are typically characterized by an enhancement of edge pressure gradients beyond those found in traditional L-mode plasmas. Further, the pressure gradient inside of this small pedestal is unusually steep, allowing access to high core performance that is competitive with other ELM-free regimes previously achieved on DIII-D. Since ELM-free operation in NT is linked directly to the magnetic geometry, NT fusion pilot plants are predicted to maintain advantageous edge conditions even in burning plasma regimes, potentially eliminating reactor core-integration issues caused by ELMs.

Published
2024

8. Operational Space and Plasma Performance with an RMP-ELM Suppressed Edge

Author

Paz-Soldan, C., Gu, S., Leuthold, N., Lunia, P., Xie, P., Kim, M. W., Kim, S. K., Logan, N. C., Park, J. -K., Suttrop, W., Sun, Y., Weisberg, D. B., Willensdorfer, M., ASDEX-Upgrade, the, DIII-D, EAST, and Teams, KSTAR

Subjects
Physics - Plasma Physics
Abstract

The operational space and global performance of plasmas with edge-localized modes (ELMs) suppressed by resonant magnetic perturbations (RMPs) are surveyed by comparing AUG, DIII-D, EAST, and KSTAR stationary operating points. RMP-ELM suppression is achieved over a range of plasma currents, toroidal fields, and RMP toroidal mode numbers. Consistent operational windows in edge safety factor are found across devices, while windows in plasma shaping parameters are distinct. Accessed pedestal parameters reveal a quantitatively similar pedestal-top density limit for RMP-ELM suppression in all devices of just over 3x1019 m-3. This is surprising given the wide variance of many engineering parameters and edge collisionalities, and poses a challenge to extrapolation of the regime. Wide ranges in input power, confinement time, and stored energy are observed, with the achieved triple product found to scale like the product of current, field, and radius. Observed energy confinement scaling with engineering parameters for RMP-ELM suppressed plasmas are presented and compared with expectations from established H and L-mode scalings, including treatment of uncertainty analysis. Different scaling exponents for individual engineering parameters are found as compared to the established scalings. However, extrapolation to next-step tokamaks ITER and SPARC find overall consistency within uncertainties with the established scalings, finding no obvious performance penalty when extrapolating from the assembled multi-device RMP-ELM suppressed database. Overall this work identifies common physics for RMP-ELM suppression and highlights the need to pursue this no-ELM regime at higher magnetic field and different plasma physical size., Comment: 22 pages, 11 figures

Published
2024
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9. Assessment of vertical stability for negative triangularity pilot plants

Author

Guizzo, S., Nelson, A. O., Hansen, C., Logak, F., and Paz-Soldan, C.

Subjects
Physics - Plasma Physics
Abstract

Negative triangularity (NT) tokamak configurations may be more susceptible to magneto-hydrodynamic instability, posing challenges for recent reactor designs centered around their favorable properties, such as improved confinement and operation free of edge-localized modes. In this work, we assess the vertical stability of plasmas with NT shaping and develop potential reactor solutions. When coupled with a conformal wall, NT equilibria are confirmed to be less vertically stable than equivalent positive triangularity (PT) configurations. Unlike PT, their vertical stability is degraded at higher poloidal beta. Furthermore, improvements in vertical stability at low aspect ratio do not translate to the NT geometry. NT equilibria are stabilized in PT vacuum vessels due to the increased proximity of the plasma and the wall on the outboard side, but this scenario is found to be undesirable due to reduced vertical gaps which give less spatial margin for control recovery. Instead, we demonstrate that informed positioning of passively conducting plates can lead to improved vertical stability in NT configurations on par with stability metrics expected in PT scenarios. An optimal setup for passive plates in highly elongated NT devices is presented, where plates on the outboard side of the device reduce vertical instability growth rates to 16% of their baseline value. For lower target elongations, integration of passive stabilizers with divertor concepts can lead to significant improvements in vertical stability. Plates on the inboard side of the device are also uniquely enabled in NT geometries, providing opportunity for spatial separation of vertical stability coils and passive stabilizers.

Published
2024

10. TokaMaker: An open-source time-dependent Grad-Shafranov tool for the design and modeling of axisymmetric fusion devices

Author

Hansen, C., Stewart, I. G., Burgess, D., Pharr, M., Guizzo, S., Logak, F., Nelson, A. O., and Paz-Soldan, C.

Subjects
Physics - Plasma Physics, Physics - Computational Physics
Abstract

In this paper, we present a new static and time-dependent MagnetoHydroDynamic (MHD) equilibrium code, TokaMaker, for axisymmetric configurations of magnetized plasmas, based on the well-known Grad-Shafranov equation. This code utilizes finite element methods on an unstructured triangular grid to enable capturing accurate machine geometry and simple mesh generation from engineering-like descriptions of present and future devices. The new code is designed for ease of use without sacrificing capability and speed through a combination of Python, Fortran, and C/C++ components. A detailed description of the numerical methods of the code, including a novel formulation of the boundary conditions for free-boundary equilibria, and validation of the implementation of those methods using both analytic test cases and cross-code validation is shown. Results show expected convergence across tested polynomial orders for analytic and cross-code test cases.

Published
2023
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11. Design of Passive and Structural Conductors for Tokamaks Using Thin-Wall Eddy Current Modeling

Author

Battey, A. F., Hansen, C., Garnier, D., Weisberg, D., Paz-Soldan, C., Sweeney, R., Tinguely, R. A., and Creely, A. J.

Subjects
Physics - Plasma Physics
Abstract

A new three-dimensional electromagnetic modeling tool ThinCurr has been developed using the existing PSI-Tet finite-element code in support of conducting structure design work for both the SPARC and DIII-D tokamaks. Within this framework a 3D conducting structure model was created for both the SPARC and DIII-D tokamaks in the thin-wall limit. This model includes accurate details of the vacuum vessel and other conducting structural elements with realistic material resistivities. This model was leveraged to support the design of a passive runaway electron mitigation coil (REMC), studying the effect of various design parameters, including coil resistivity, current quench duration, and plasma vertical position, on the effectiveness of the coil. The REMC is a non-axisymmetric coil designed to passively drive large non-axisymmetric fields during the plasma disruption thereby destroying flux surfaces and deconfining RE seed populations. These studies indicate that current designs should apply substantial 3D fields at the plasma surface during future plasma current disruptions as well as highlight the importance of having the REMC conductors away from the machine midplane in order to ensure they are robust to off-normal disruption scenarios., Comment: 33 pages and 14 figures. to be published in Nuclear Fusion

Published
2023

12. Simultaneous access to high normalized current, pressure, density, and confinement in strongly-shaped diverted negative triangularity plasmas

Author

Paz-Soldan, C., Chrystal, C., Lunia, P., Nelson, A. O., Thome, K. E., Austin, M. E., Cote, T. B., Hyatt, A. W., Marinoni, A., Osborne, T. H., Pharr, M., Sauter, O., Scotti, F., Wilks, T. M., and Wilson, H. S.

Subjects
Physics - Plasma Physics
Abstract

Strongly-shaped diverted negative triangularity (NT) plasmas in the DIII-D tokamak demonstrate simultaneous access to high normalized current, pressure, density, and confinement. NT plasmas are shown to exist across an expansive parameter space compatible with high fusion power production, revealing surprisingly good core stability properties that compare favorably to conventional positive triangularity plasmas in DIII-D. Non-dimensionalizing the operating space, edge safety factors below 3, normalized betas above 3, Greenwald density fractions above 1, and high-confinement mode (H-mode) confinement qualities above 1 are simultaneously observed, all with a robustly stable edge free from deleterious edge-localized mode instabilities. Scaling of the confinement time with engineering parameters reveals at least a linear dependence on plasma current although with significant power degradation, both in excess of expected H-mode scalings. These results increase confidence that NT plasmas are a viable approach to realize fusion power and open directions for future detailed study.

Published
2023
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13. Highest fusion performance without harmful edge energy bursts in tokamak

Author

Kim, SK, Shousha, R, Yang, SM, Hu, Q, Hahn, SH, Jalalvand, A, Park, J-K, Logan, NC, Nelson, AO, Na, Y-S, Nazikian, R, Wilcox, R, Hong, R, Rhodes, T, Paz-Soldan, C, Jeon, YM, Kim, MW, Ko, WH, Lee, JH, Battey, A, Yu, G, Bortolon, A, Snipes, J, and Kolemen, E

Subjects
Nuclear and Plasma Physics, Information and Computing Sciences, Applied Computing, Physical Sciences, Affordable and Clean Energy
Abstract

The path of tokamak fusion and International thermonuclear experimental reactor (ITER) is maintaining high-performance plasma to produce sufficient fusion power. This effort is hindered by the transient energy burst arising from the instabilities at the boundary of plasmas. Conventional 3D magnetic perturbations used to suppress these instabilities often degrade fusion performance and increase the risk of other instabilities. This study presents an innovative 3D field optimization approach that leverages machine learning and real-time adaptability to overcome these challenges. Implemented in the DIII-D and KSTAR tokamaks, this method has consistently achieved reactor-relevant core confinement and the highest fusion performance without triggering damaging bursts. This is enabled by advances in the physics understanding of self-organized transport in the plasma edge and machine learning techniques to optimize the 3D field spectrum. The success of automated, real-time adaptive control of such complex systems paves the way for maximizing fusion efficiency in ITER and beyond while minimizing damage to device components.

Published
2024

14. Robust avoidance of edge-localized modes alongside gradient formation in the negative triangularity tokamak edge

Author

Nelson, A. O., Schmitz, L., Paz-Soldan, C., Thome, K. E., Cote, T. B., Leuthold, N., Scotti, F., Austin, M. E., Hyatt, A., and Osborne, T.

Subjects
Physics - Plasma Physics
Abstract

In a series of high performance diverted discharges on DIII-D, we demonstrate that strong negative triangularity (NT) shaping robustly suppresses all edge-localized mode (ELM) activity over a wide range of plasma conditions: $\langle n\rangle=0.1-1.5\times10^{20}$m$^{-3}$, $P_\mathrm{aux}=0-15$MW and $|B_\mathrm{t}|=1-2.2$T, corresponding to $P_\mathrm{loss}/P_\mathrm{LH08}\sim8$. The full dataset is consistent with the theoretical prediction that magnetic shear in the NT edge inhibits access to ELMing H-mode regimes; all experimental pressure profiles are found to be at or below the infinite-$n$ ballooning stability limit. Importantly, we also report enhanced edge pressure gradients at strong NT that are significantly steeper than in traditional ELM-free L-mode plasmas and provide significant promise for NT reactor integration., Comment: 5 pages, 5 figures

Published
2023
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15. 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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16. 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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17. H-mode inhibition in negative triangularity tokamak reactor plasmas

Author

Nelson, A. O., Paz-Soldan, C., and Saarelma, S.

Subjects
Physics - Plasma Physics
Abstract

Instability to high toroidal mode number ($n$) ballooning modes has been proposed as the primary gradient-limiting mechanism for tokamak equilibria with negative triangularity ($\delta$) shaping, preventing access to strong H-mode regimes when $\delta\ll0$. To understand how this mechanism extrapolates to reactor conditions, we model the infinite-$n$ ballooning stability as a function of internal profiles and equilibrium shape using a combination of the CHEASE and BALOO codes. While the critical $\delta$ required for avoiding $2^\mathrm{nd}$ stability to high-$n$ modes is observed to depend in a complicated way on various shaping parameters, including the equilibrium aspect ratio, elongation and squareness, equilibria with negative triangularity are robustly prohibited from accessing the $2^\mathrm{nd}$ stability region, offering the prediction that that negative triangularity reactors should maintain L-mode-like operation. In order to access high-$n$ $2^\mathrm{nd}$ stability, the local shear over the entire bad curvature region must be sufficiently negative to overcome curvature destabilization on the low field side. Scalings of the ballooning-limited pedestal height are provided as a function of plasma parameters to aid future scenario design.

Published
2022
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19. Latest results on quiescent and post-disruption runaway electron mitigation experiments at Frascati Tokamak Upgrade

Author

Carnevale, D., Buratti, P., Baruzzo, M., Bin, W., Bombarda, F., Boncagni, L., Paz-Soldan, C., Calacci, L., Cappelli, M., Castaldo, C., Ceccuzzi, S., Centioli, C., Cianfarani, C., Coda, S., Cordella, F., Arcangelo, O. D, Decker, J., Duval, B., Esposito, B., Gabellieri, L., Galeani, S., Garavaglia, S., Galperti, C., Ghillardi, G., Granucci, G., Lenhen, M., Liuzza, D., Martinelli, F., Mazzotta, C., Napoli, F., Nardon, E., Oliva, F., Panaccione, L., Passeri, M., Pucella, G., Ramogida, G., Romano, A., Sassano, M., Tudisco, O., team, the Ftu, and Team, Eurofusion Mst1

Subjects
Physics - Plasma Physics
Abstract

Results from the last FTU campaigns on the deuterium large (wrt FTU volume) pellet REs suppression capability, mainly due to the induced burst MHD activity expelling REs seed are presented for discharges with 0.5 MA and 5.3T. Clear indications of avalanche multiplication of REs following single pellet injection on 0.36 MA flat-top discharges is shown together with quantitative indications of dissipative effects in terms of critical electrical field increase due to fan-like instabilities. Analysis of large fan-like instabilities on post-disruption RE beams, that seem to be correlated with low electrical field and background density drops, reveal their strong RE energy suppression capability suggesting a new strategy for RE energy suppression controlling large fan instabilities. We demonstrate how such density drops can be induced using modulated ECRH power on post-disruption beams., Comment: DRAFT that will be submitted to NF (the conference version is on FEC/IAEA conference 2020)

Published
2021

20. Plasma Performance and Operational Space without ELMs in DIII-D

Author

Paz-Soldan, C.

Subjects
Physics - Plasma Physics
Abstract

A database of DIII-D plasmas without ELMs compares the operating space and plasma performance of stationary no-ELM regimes: RMP-ELM suppression, QH-mode, I-mode, EDA H-mode, L-mode, and negative triangularity L-mode (Neg-D). Operational space is documented in terms of engineering and physics parameters, revealing divergent constraints. Some operational space discriminants (such as pedestal collisionality) are well known, while others, such as low torque & safety factor, or high power & density, are less commonly emphasized. Normalized performance (confinement quality and normalized pressure) also discriminate the no-ELM regimes and favor the regimes tolerant to power in DIII-D: RMP, QH, and Neg-D. Absolute performance (triple product $\langle p\rangle\tau$) also discriminates no-ELM regimes and is found to rise linearly with IaB and also benefits from tolerance to power. The highest normalized performance using the metric $\langle p\rangle\tau$/IaB is found in QH and RMP regimes. Though comparable QH and RMP performance is found, the pedestal pressure (p_ped) is very different. p_ped in RMP plasmas is relatively low, and the best performance is found with a high core $\langle p\rangle$ fraction alongside high core rotation, consistent with an ExB shear confinement enhancement. p_ped of QH plasmas is significantly higher than RMP, and QH performance does not correlate with core rotation. However, the highest QH p_ped are found with high carbon fraction. While normalized performance of Neg-D plasmas is comparable to QH and RMP plasmas, the absolute confinement of Neg-D is lower, owing to low elongation and low p_ped achieved thus far. Only the EDA-H, Neg-D, and L-mode scenarios have approached divertor-compatible high separatrix density conditions, with Neg-D preserving the highest performance owing to its compatibility with both high power and density., Comment: 43 figures

Published
2020
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21. Runaway Electron Seed Formation at Reactor-Relevant Temperature

Author

Paz-Soldan, C., Aleynikov, P., Hollmann, E. M., Lvovskiy, A., Bykov, I., Du, X., Eidietis, N. W., and Shiraki, D.

Subjects
Physics - Plasma Physics
Abstract

Systematic variation of the pre-disruption core electron temperature (Te) from 1 to 12 keV using an internal transport barrier scenario reveals a dramatic increase in the production of seed runaway electrons (REs), ultimately accessing near-complete conversion of the pre-disruption current into sub-MeV RE current. Injected Ar pellets are observed to ablate more intensely and promptly as Te rises. At high Te, the observed ablation exceeds predictions from published thermal ablation models. Simultaneously, the thermal quench (TQ) is observed to significantly shorten with increasing Te -- a surprising result. While the reason for the shorter TQ is not yet understood, candidate mechanisms include: insufficiently accurate thermal ablation models, enhanced ablation driven by the seed RE population, or significant parallel heat transport along stochastic fields. Kinetic modeling that self-consistently treats the plasma cooling via radiation, the induced electric field, and the formation of the seed RE is performed. Including the combined effect of the inherent dependence of hot-tail RE seeding on Te together with the shortened TQ, modeling recovers the progression towards near-complete conversion of the pre-disruption current to RE current as Te rises. Measurement of the HXR spectrum during the early current quench (CQ) reveals a trend of decreasing energy with pre-disruption Te. At the very highest Te ($\approx$ 12 keV), $\approx$ 100% conversion of the thermal current to runaway current is found. The energy of this peculiar RE beam is inferred to be sub-MeV as it emits vanishingly few MeV hard X-rays (HXRs). These measurements demonstrate novel TQ dynamics as Te is varied and illustrate the limitations of treating the RE seed formation problem without considering the inter-related dependencies of the pellet ablation, radiative energy loss, and resultant variations of the TQ duration.

Published
2020
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22. Wide operational windows of edge-localized mode suppression by resonant magnetic perturbations in the DIII-D tokamak

Author

Hu, Q. M., Nazikian, R., Grierson, B. A., Logan, N. C., Orlov, D. M., Paz-Soldan, C., and Yu, Q.

Subjects
Physics - Plasma Physics
Abstract

Edge-Localized-Mode (ELM) suppression by resonant magnetic perturbations (RMPs) generally occurs over very narrow ranges of the plasma current (or magnetic safety factor q95) in the DIII-D tokamak. However, wide q95 ranges of ELM suppression are needed for the safety and operational flexibility of ITER and future reactors. In DIII-D ITER Similar Shape (ISS) plasmas with n=3 RMPs, the range of q95 for ELM suppression is found to increase with decreasing electron density. Nonlinear two-fluid MHD simulations reproduce the observed q95 windows of ELM suppression and the dependence on plasma density, based on the conditions for resonant field penetration at the top of the pedestal. When the RMP amplitude is close to the threshold for resonant field penetration, only narrow isolated magnetic islands form near the top of the pedestal, leading to narrow q95 windows of ELM suppression. However, as the threshold for field penetration decreases with decreasing density, resonant field penetration can take place over a wider range of q95. For sufficiently low density (penetration threshold) multiple magnetic islands form near the top of the pedestal giving rise to continuous q95 windows of ELM suppression. The model predicts that wide q95 windows of ELM suppression can be achieved at substantially higher pedestal pressure in DIII-D by shifting to higher toroidal mode number (n=4) RMPs.

Published
2019
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23. The Density Dependence of Edge-Localized-Mode Suppression and Pump-out by Resonant Magnetic Perturbations in the DIII-D Tokamak

Author

Hu, Q. M., Nazikian, R., Grierson, B., Logan, N. C., Park, J-K., Paz-Soldan, C., and Yu, Q.

Subjects
Physics - Plasma Physics
Abstract

The density dependence of edge-localized-mode (ELM) suppression and density pump-out (density reduction) by n = 2 resonant magnetic perturbations (RMPs) is consistent with the effects of narrow well-separated magnetic islands at the top and bottom of the H-mode pedestal in DIII-D low-collisionality plasmas. Nonlinear two-fluid MHD simulations for DIII-D ITER Similar Shape (ISS) discharges show that, at low collisionality, low pedestal density is required for resonant field penetration at the pedestal top, consistent with the ubiquitous low density requirement for ELM suppression in these DIII-D plasmas. The simulations predict a drop in the pedestal pressure due to parallel transport across these narrow width (0.02) magnetic islands at the top of the pedestal that is stabilizing to Peeling-Ballooning-Modes (PBMs), and comparable to the pedestal pressure reduction observed in experiment at the onset of ELM suppression. The simulations predict density pump-out at experimentally relevant levels (-20%) at low pedestal collisionality due to very narrow (~0.01-0.02) RMP driven magnetic islands at the pedestal foot at ~0.99. The simulations show decreasing pump-out with increasing density, consistent with experiment, resulting from the inverse dependence of parallel particle transport on resistivity at the foot of the pedestal. The robust screening of resonant fields is predicted between the top and bottom of the pedestal during density pump-out and ELM suppression, consistent with the preservation of strong temperature gradients in the edge transport barrier as seen in experiment.

Published
2019
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24. Benign termination of runaway electron beams on ASDEX Upgrade and TCV

Author

Sheikh, U, Decker, J, Hoppe, M, Pedrini, M, Sieglin, B, Simons, L, Cazabonne, J, Caloud, J, Cerovsky, J, Coda, S, Colandrea, C, Dal Molin, A, Duval, B, Ficker, O, Griener, M, Papp, G, Pautasso, G, Paz-Soldan, C, Reux, C, Tomesova, E, Wijkamp, T, Sheikh U., Decker J., Hoppe M., Pedrini M., Sieglin B., Simons L., Cazabonne J., Caloud J., Cerovsky J., Coda S., Colandrea C., Dal Molin A., Duval B., Ficker O., Griener M., Papp G., Pautasso G., Paz-Soldan C., Reux C., Tomesova E., Wijkamp T., Sheikh, U, Decker, J, Hoppe, M, Pedrini, M, Sieglin, B, Simons, L, Cazabonne, J, Caloud, J, Cerovsky, J, Coda, S, Colandrea, C, Dal Molin, A, Duval, B, Ficker, O, Griener, M, Papp, G, Pautasso, G, Paz-Soldan, C, Reux, C, Tomesova, E, Wijkamp, T, Sheikh U., Decker J., Hoppe M., Pedrini M., Sieglin B., Simons L., Cazabonne J., Caloud J., Cerovsky J., Coda S., Colandrea C., Dal Molin A., Duval B., Ficker O., Griener M., Papp G., Pautasso G., Paz-Soldan C., Reux C., Tomesova E., and Wijkamp T.

Abstract

This paper discusses the development of a benign termination scenario for runaway electron (RE) beams on ASDEX Upgrade and TCV. A systematic study revealed that a low electron density (n e) companion plasma was required to achieve a large MHD instability, which expelled the confined REs over a large wetted area and allowed for the conversion of magnetic energy to radiation. Control of the companion plasma ne was achieved via neutral pressure regulation and was agnostic to material injection method. The neutral pressure required for recombination was found to be dependent on impurity species, quantity and RE current. On TCV, n e increased at neutral pressures above 1 Pa, indicating that higher collisionality between the REs and neutrals may lead to an upper pressure limit. The conversion of magnetic energy to radiated energy was measured on both machines and a decrease in efficiency was observed at high neutral pressure on TCV. The benign termination technique was able to prevent any significant increase in maximum heat flux on AUG from 200 to 600 kA of RE current, highlighting the ability of this approach to handle fully formed RE beams.

Published
2024

25. Experimental conditions to suppress edge localised modes by magnetic perturbations in the ASDEX Upgrade tokamak

Author

Suttrop, W., Kirk, A., Bobkov, V., Cavedon, M., Dunne, M., McDermott, R. M., Meyer, H., Nazikian, R., Paz-Soldan, C., Ryan, D. A., Viezzer, E., and Willensdorfer, M.

Subjects
Physics - Plasma Physics
Abstract

Access conditions for full suppression of Edge Localised Modes (ELMs) by Magnetic Perturbations (MP) in low density high confinement mode (H-mode) plasmas are studied in the ASDEX Upgrade tokamak. The main empirical requirements for full ELM suppression in our experiments are: 1. The poloidal spectrum of the MP must be aligned for best plasma response from weakly stable kink-modes, which amplify the perturbation, 2. The plasma edge density must be below a critical value, $3.3 \times 10^{19}$~m$^{-3}$. The edge collisionality is in the range $\nu^*_i = 0.15-0.42$ (ions) and $\nu^*_e = 0.15-0.25$ (electrons). However, our data does not show that the edge collisionality is the critical parameter that governs access to ELM suppression. 3. The pedestal pressure must be kept sufficiently low to avoid destabilisation of small ELMs. This requirement implies a systematic reduction of pedestal pressure of typically 30\% compared to unmitigated ELMy H-mode in otherwise similar plasmas. 4. The edge safety factor $q_{95}$ lies within a certain window. Within the range probed so far, $q_{95}=3.5-4.2$, one such window, $q_{95}=3.57-3.95$ has been identified. Within the range of plasma rotation encountered so far, no apparent threshold of plasma rotation for ELM suppression is found. This includes cases with large cross field electron flow in the entire pedestal region, for which two-fluid MHD models predict that the resistive plasma response to the applied MP is shielded.

Published
2018
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26. Interpretation of runaway electron synchrotron and bremsstrahlung images

Author

Hoppe, M., Embréus, O., Paz-Soldan, C., Moyer, R. A., and Fülöp, T.

Subjects
Physics - Plasma Physics
Abstract

The crescent spot shape observed in DIII-D runaway electron synchrotron radiation images is shown to result from the high degree of anisotropy in the emitted radiation, the finite spectral range of the camera and the distribution of runaways. The finite spectral camera range is found to be particularly important, as the radiation from the high-field side can be stronger by a factor $10^6$ than the radiation from the low-field side in DIII-D. By combining a kinetic model of the runaway dynamics with a synthetic synchrotron diagnostic we see that physical processes not described by the kinetic model (such as radial transport) are likely to be limiting the energy of the runaways. We show that a population of runaways with lower dominant energies and larger pitch-angles than those predicted by the kinetic model provide a better match to the synchrotron measurements. Using a new synthetic bremsstrahlung diagnostic we also simulate the view of the Gamma Ray Imager (GRI) diagnostic used at DIII-D to resolve the spatial distribution of runaway-generated bremsstrahlung., Comment: 21 pages, 11 figures

Published
2017
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27. High performance power handling in the absence of an H-mode edge in negative triangularity DIII-D plasmas.

Author

Scotti, F., Marinoni, A., McLean, A.G., Paz-Soldan, C., Thome, K.E., Zhao, M., Allen, S., Austin, M., Burke, M.G., Eldon, D., Fenstermacher, M., Hyatt, A., Lasnier, C.J., Leonard, A., Lore, J., Nelson, A.O., Osborne, T., Sauter, O., Truong, D., and Van Zeeland, M.A.

Subjects
PLASMA boundary layers, HEAT flux, ELECTRON temperature, PLASMA currents, PLASMA dynamics
Abstract

Experiments performed during strongly-shaped high-power diverted negative triangularity (NT) experiments in DIII-D achieved detached divertor conditions and a transient-free edge, showcasing the potential for application of NT to a core-edge integrated reactor-like scenario and providing the first characterization of the parametric dependencies for detachment onset. Detached divertor conditions will be required in future devices to mitigate divertor heat fluxes. Access to dissipative divertor conditions was investigated via an increase in upstream density. Detachment onset at the outer strike point was achieved with H-mode level confinement H 98 − y 2 ∼ 1 and reactor-relevant normalized pressures β N ∼ 2 . Confinement degradation was observed with deeper detachment, associated with the loss of an electron temperature pedestal. Differences in geometry, radial transport, impact of cross field drifts are discussed to explain differences in access to detachment in NT discharges. Higher normalized densities, with respect to equivalent discharges in positive triangularity, were necessary to achieve detachment, partially explained by the shorter parallel connection length to the targets. The effect of cross-field particle drifts (E × B, B × ∇ B) on access to detachment was demonstrated by the lower upstream density needed to access detachment with ion B × ∇ B drift directed outside of the active divertor (Greenwald fraction f Gw ∼ 0.9–1.0 vs f Gw ∼ 1.3). The upstream density at detachment onset was observed to increase linearly with plasma current with ion B × ∇ B drift into the divertor, consistent with the observed narrowing of the scrape-off layer heat flux width λ q . Edge fluid simulations capture separatrix densities needed to achieve detachment in NT plasma and their dependence on drift direction. The ability to reproduce detachment dynamics in NT plasma increases the confidence in future design studies for NT divertors. [ABSTRACT FROM AUTHOR]

Published
2024
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28. Benign termination of runaway electron beams on ASDEX Upgrade and TCV

Author

Sheikh, U., Decker, J., Hoppe, Mathias, Pedrini, M., Sieglin, B., Simons, L., Cazabonne, J., Caloud, J., Cerovsky, J., Coda, S., Colandrea, C., Dal Molin, A., Duval, B., Ficker, O., Griener, M., Papp, G., Pautasso, G., Paz-Soldan, C., Reux, C., Tomesova, E., Wijkamp, T., Sheikh, U., Decker, J., Hoppe, Mathias, Pedrini, M., Sieglin, B., Simons, L., Cazabonne, J., Caloud, J., Cerovsky, J., Coda, S., Colandrea, C., Dal Molin, A., Duval, B., Ficker, O., Griener, M., Papp, G., Pautasso, G., Paz-Soldan, C., Reux, C., Tomesova, E., and Wijkamp, T.

Abstract

This paper discusses the development of a benign termination scenario for runaway electron (RE) beams on ASDEX Upgrade and TCV. A systematic study revealed that a low electron density (n e) companion plasma was required to achieve a large MHD instability, which expelled the confined REs over a large wetted area and allowed for the conversion of magnetic energy to radiation. Control of the companion plasma ne was achieved via neutral pressure regulation and was agnostic to material injection method. The neutral pressure required for recombination was found to be dependent on impurity species, quantity and RE current. On TCV, n e increased at neutral pressures above 1 Pa, indicating that higher collisionality between the REs and neutrals may lead to an upper pressure limit. The conversion of magnetic energy to radiated energy was measured on both machines and a decrease in efficiency was observed at high neutral pressure on TCV. The benign termination technique was able to prevent any significant increase in maximum heat flux on AUG from 200 to 600 kA of RE current, highlighting the ability of this approach to handle fully formed RE beams., QC 20240201

Published
2024
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29. Dynamics of JET runaway electron beams in D2-rich shattered pellet injection mitigation experiments

Author

Sommariva, C., Pau, A., Silburn, S., Reux, C., Hoppe, Mathias, Buratti, P., Ficker, O., Morales, Rennan B., Fontana, M., Sun, H., Carvalho, P., Sheena, M., Gerasimov, S., Szepesi, G., Boboc, A., Coffey, I., Kiptily, V., Sauter, O., Pautasso, G., Paz-Soldan, C., Decker, J., Sommariva, C., Pau, A., Silburn, S., Reux, C., Hoppe, Mathias, Buratti, P., Ficker, O., Morales, Rennan B., Fontana, M., Sun, H., Carvalho, P., Sheena, M., Gerasimov, S., Szepesi, G., Boboc, A., Coffey, I., Kiptily, V., Sauter, O., Pautasso, G., Paz-Soldan, C., and Decker, J.

Abstract

The publication provide further insights into the dynamics of JET runaway electron (RE) beams mitigated by D2-rich shattered pellet injection (SPI) (Reux et al 2022 Plasma Phys. Control. Fusion 64 034002). Multi-diagnostic analyses show that mechanisms causing continuous RE losses and energy transfer from hot electrons to cold background plasma can act before the SPI. After the SPI, measurements are compatible with a reduction of the maximum energy and pitch angle of the RE distribution while the population of supra-thermal electrons increases. The RE population growth is likely due to electron avalanche. Dark island-like pattern chains, characterised by an integer poloidal mode number and a certain minor radius, are identified in the JET RE beam synchrotron radiation videos. The synchrotron island dynamics is studied via a newly developed computer vision code (Sommariva and Silburn https://c4science.ch/source/ pSpiPTV/). The radial motion of synchrotron island chains is found to be consistent with the most plausible time evolution of the radial current density profile compatible with both the RE synchrotron videos and the total RE current time trace. Similarly, correlations are identified between the temporal progression of the synchrotron islands poloidal rotation frequency and sudden MHD relaxation events. Loss-of-RE events probably caused by non-linear interactions between synchrotron islands are observed for the first time. Experimental evidences suggest that synchrotron islands are possibly related to the existence of magnetic islands which may lead to the development of new RE beam mitigation strategies., QC 20240926

Published
2024
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30. Compatibility of internal transport barrier with steady-state operation in the high bootstrap fraction regime on DIII-D

Author

Garofalo, AM, Gong, X, Grierson, BA, Ren, Q, Solomon, WM, Strait, EJ, Van Zeeland, MA, Holcomb, CT, Meneghini, O, Smith, SP, Staebler, GM, Wan, B, Bravenec, R, Budny, RV, Ding, S, Hanson, JM, Heidbrink, WW, Lao, LL, Li, G, Pan, C, Petty, CC, Qian, J, Paz-Soldan, C, and Xu, G

Subjects
steady state, ion transport barrier, wall stabilization, high beta, Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics
Abstract

Recent EAST/DIII-D joint experiments on the high poloidal beta tokamak regime in DIII-D have demonstrated fully noninductive operation with an internal transport barrier (ITB) at large minor radius, at normalized fusion performance increased by 30% relative to earlier work (Politzer et al 2005 Nucl. Fusion 45 417). The advancement was enabled by improved understanding of the 'relaxation oscillations', previously attributed to repetitive ITB collapses, and of the fast ion behavior in this regime. It was found that the 'relaxation oscillations' are coupled core-edge modes amenable to wall-stabilization, and that fast ion losses which previously dictated a large plasma-wall separation to avoid wall over-heating, can be reduced to classical levels with sufficient plasma density. By using optimized waveforms of the plasma-wall separation and plasma density, fully noninductive plasmas have been sustained for long durations with excellent energy confinement quality, bootstrap fraction ≥80%, βN ≤ 4, βP ≥ 3, and βT ≥ 2%. These results bolster the applicability of the high poloidal beta tokamak regime toward the realization of a steady-state fusion reactor.

Published
2015

31. Fast ion transport during applied 3D magnetic perturbations on DIII-D

Author

Van Zeeland, MA, Ferraro, NM, Grierson, BA, Heidbrink, WW, Kramer, GJ, Lasnier, CJ, Pace, DC, Allen, SL, Chen, X, Evans, TE, García-Muñoz, M, Hanson, JM, Lanctot, MJ, Lao, LL, Meyer, WH, Moyer, RA, Nazikian, R, Orlov, DM, Paz-Soldan, C, and Wingen, A

Subjects
fast ion transport, 3D magnetic perturbations, prompt beam loss, DIII-D tokamak, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Fluids & Plasmas
Abstract

Measurements show fast ion losses correlated with applied three-dimensional (3D) fields in a variety of plasmas ranging from L-mode to resonant magnetic perturbation (RMP) edge localized mode (ELM) suppressed H-mode discharges. In DIII-D L-mode discharges with a slowly rotating n = 2 magnetic perturbation, scintillator detector loss signals synchronized with the applied fields are observed to decay within one poloidal transit time after beam turnoff indicating they arise predominantly from prompt loss orbits. Full orbit following using M3D-C1 calculations of the perturbed fields and kinetic profiles reproduce many features of the measured losses and points to the importance of the applied 3D field phase with respect to the beam injection location in determining the overall impact on prompt beam ion loss. Modeling of these results includes a self-consistent calculation of the 3D perturbed beam ion birth profiles and scrape-off-layer ionization, a factor found to be essential to reproducing the experimental measurements. Extension of the simulations to full slowing down timescales, including fueling and the effects of drag and pitch angle scattering, show the applied n = 3 RMPs in ELM suppressed H-mode plasmas can induce a significant loss of energetic particles from the core. With the applied n = 3 fields, up to 8.4% of the injected beam power is predicted to be lost, compared to 2.7% with axisymmetric fields only. These fast ions, originating from minor radii ρ > 0.7, are predicted to be primarily passing particles lost to the divertor region, consistent with wide field-of-view infrared periscope measurements of wall heating in n = 3 RMP ELM suppressed plasmas. Edge fast ion Dα (FIDA) measurements also confirm a large change in edge fast ion profile due to the n = 3 fields, where the effect was isolated by using short 50 ms RMP-off periods during which ELM suppression was maintained yet the fast ion profile was allowed to recover. The role of resonances between fast ion drift motion and the applied 3D fields in the context of selectively targeting regions of fast ion phase space is also discussed.

Published
2015

32. Resistive and ferritic-wall plasma dynamos in a sphere

Author

Khalzov, I. V., Brown, B. P., Kaplan, E. J., Katz, N., Paz-Soldan, C., Rahbarnia, K., Spence, E. J., and Forest, C. B.

Subjects
Physics - Plasma Physics
Abstract

We numerically study the effects of varying electric conductivity and magnetic permeability of the bounding wall on a kinematic dynamo in a sphere for parameters relevant to Madison plasma dynamo experiment (MPDX). The dynamo is excited by a laminar, axisymmetric flow of von Karman type. The flow is obtained as a solution to the Navier-Stokes equation for an isothermal fluid with a velocity profile specified at the sphere's boundary. The properties of the wall are taken into account as thin-wall boundary conditions imposed on the magnetic field. It is found that an increase in the permeability of the wall reduces the critical magnetic Reynolds number Rm_cr. An increase in the conductivity of the wall leaves Rm_cr unaffected, but reduces the dynamo growth rate.

Published
2012
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37. Stellarator Research Opportunities: A Report of the National Stellarator Coordinating Committee

Author

Gates, David A., Anderson, David, Anderson, S., Zarnstorff, M., Spong, Donald A., Weitzner, Harold, Neilson, G. H., Ruzic, D., Andruczyk, D., Harris, J. H., Mynick, H., Hegna, C. C., Schmitz, O., Talmadge, J. N., Curreli, D., Maurer, D., Boozer, A. H., Knowlton, S., Allain, J. P., Ennis, D., Wurden, G., Reiman, A., Lore, J. D., Landreman, Matt, Freidberg, J. P., Hudson, S. R., Porkolab, M., Demers, D., Terry, J., Edlund, E., Lazerson, S. A., Pablant, N., Fonck, R., Volpe, F., Canik, J., Granetz, R., Ware, A., Hanson, J. D., Kumar, S., Deng, C., Likin, K., Cerfon, A., Ram, A., Hassam, A., Prager, S., Paz-Soldan, C., Pueschel, M. J., Joseph, I., and Glasser, A. H.

Published
2018
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40. Prospects of core–edge integrated no-ELM and small-ELM scenarios for future fusion devices

Author

Viezzer, E., primary, Austin, M.E., additional, Bernert, M., additional, Burrell, K.H., additional, Cano-Megias, P., additional, Chen, X., additional, Cruz-Zabala, D.J., additional, Coda, S., additional, Faitsch, M., additional, Février, O., additional, Gil, L., additional, Giroud, C., additional, Happel, T., additional, Harrer, G.F., additional, Hubbard, A.E., additional, Hughes, J.W., additional, Kallenbach, A., additional, Labit, B., additional, Merle, A., additional, Meyer, H., additional, Paz-Soldan, C., additional, Oyola, P., additional, Sauter, O., additional, Siccinio, M., additional, Silvagni, D., additional, and Solano, E.R., additional

Published
2023
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41. Transition in particle transport under resonant magnetic perturbations in a tokamak

Author

Kim, S.K., Logan, N.C., Becoulet, M., Hoelzl, M., Hu, Q., Huijsmans, G.T.A., Pamela, S.J.P., Yu, Q., Yang, S.M., Paz-Soldan, C., Kolemen, E., Park, J.K., Kim, S.K., Logan, N.C., Becoulet, M., Hoelzl, M., Hu, Q., Huijsmans, G.T.A., Pamela, S.J.P., Yu, Q., Yang, S.M., Paz-Soldan, C., Kolemen, E., and Park, J.K.

Abstract

Nonlinear 3D MHD simulations and validations reveal that the hybrid particle-MHD transport is a key process for driving the pump-out in the presence of Resonant Magnetic Perturbations (RMPs) in the KSTAR tokamak. Particle transport and the resulting density pump-out by RMPs are shown to be composed of not only the classical flow convection near magnetic islands due to polarization but also the neoclassical ion diffusion across perturbed magnetic surfaces. The latter is known as the Neoclassical Toroidal Viscosity (NTV) and is integrated into nonlinear MHD simulations here for the first time, revealing that the two-stage pump-outs observed in KSTAR experiments are reproduced only with such integrated nonlinear MHD and transport evolution. Near-resonant responses, which have received less attention than the resonant response, play distinct roles in the pump-out along with the island formation. In addition, this modeling is used to investigate the pump-outs in double-null-like plasmas and numerically capture the effect of the double-null shape on the pump-outs, which may explain the difficulty of Edge Localized Mode (ELM) suppression access in double-like plasmas. This reveals new aspects of the impact toroidal geometry and mode coupling have on 3D physics and reveals the importance of near-resonant components in suppressing ELMs.

Published
2023

42. Parametric study of Alfvenic instabilities driven by runaway electrons during the current quench in DIII-D

Author

Lvovskiy, A, Paz-Soldan, C, Eidietis, N, Dal Molin, A, Degrandchamp, G, Hollmann, E, Lestz, J, Liu, C, Nocente, M, Shiraki, D, Du, X, Eidietis, NW, DeGrandchamp, GH, Hollmann, EM, Lestz, JB, Lvovskiy, A, Paz-Soldan, C, Eidietis, N, Dal Molin, A, Degrandchamp, G, Hollmann, E, Lestz, J, Liu, C, Nocente, M, Shiraki, D, Du, X, Eidietis, NW, DeGrandchamp, GH, Hollmann, EM, and Lestz, JB

Abstract

To avoid or mitigate runaway electron (RE) beams in ITER, RE-driven instabilities are actively studied as a complimentary technique to massive material injection. In this work we report experimental dependencies of Alfvénic instabilities driven by REs during the current quench in DIII-D on plasma and material injection parameters. These instabilities, observed in the frequency range of 0.1-3 MHz, correlate with increased RE loss and thus may play a role in non-sustained RE beams. It was found that as the toroidal magnetic field ( B T ) decreases, the RE population becomes more energetic, the energy of instabilities increases, and no RE beam is observed when the maximum energy of REs exceeds 15 MeV (or when B T is below 1.8 T). Analysis of disruptions at plasma core temperature ( T e ) of 1 keV and 8 keV shows that the RE population is much less energetic (with the maximum energy of only about 3 MeV) when T e is high, and no instabilities are observed in this case. Besides disruptions above caused by Ar injection, cases with Ne and D2 injections were also studied. Both Ne and D2 injections cause no sustained RE beams, however, for different reasons. Measurements of the instability polarization indicate that it is of predominantly compressional nature at the edge, which is consistent with modeling suggesting excitation of compressional Alfvén eigenmodes. However, drive of global Alfvén eigenmodes is also possible at low frequencies.

Published
2023

43. Diffusion–convection model of runaway electrons due to large magnetohydrodynamic perturbations in post-thermal quench plasmas.

Author

Liu, Yueqiang, Aleynikova, K., Hollmann, E. M., Paz-Soldan, C., Aleynikov, P., Khayrutdinov, R., and Lukash, V.

Subjects
PARTICLE motion, ELECTRONS, ORBITS (Astronomy), ELECTRON diffusion, TOROIDAL plasma, EQUILIBRIUM
Abstract

Systematic test particle tracing simulations for runaway electrons (REs) are performed for six post-thermal quench equilibria from DIII-D and ITER, where large scale, kink-like n = 1 (n is the toroidal mode number) magnetohydrodynamic (MHD) instabilities are found. The modeled particle guiding center orbits allow extraction of the effective diffusion–convection coefficients of REs in the presence of large three-dimensional (3D) perturbations up to 10% of the equilibrium toroidal field. With a fixed spatial distribution of the field perturbation, the RE transport coefficients along the plasma radial coordinate track reasonably well with the surface-averaged perturbation level. A substantial variation in the value of the transport coefficients—by three orders of magnitude in most cases, however, occurs with varying launching location of REs along the plasma radius. Large 3D perturbations almost always lead to comparable diffusion and convection processes, meaning that diffusion alone is insufficient to describe the particle motion. At lower (but still high) level of perturbation, the RE convection is found to be dominant over diffusion. A similar observation is made when the perturbation is too strong. In the presence of large perturbation, the dependence of the RE transport on the particle energy is sensitive to the spatial distribution of the perturbation. Based on numerically obtained RE transport coefficients, an analytic fitting model is proposed to quantify the particle diffusion and convection processes due to large MHD events in post-thermal quench plasmas. The model is shown to reasonably well reproduce the direct test particle tracing results for the RE loss fraction and can, thus, be useful for incorporating into other kinetic RE codes in order to simulate the RE beam evolution in the presence of large 3D perturbations. [ABSTRACT FROM AUTHOR]

Published
2023
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44. Trends in runaway electron plateau partial recombination by massive H2 or D2 injection in DIII-D and JET and first extrapolations to ITER and SPARC

Author

Hollmann, E.M., primary, Baylor, L., additional, Boboc, A., additional, Carvalho, P., additional, Eidietis, N.W., additional, Herfindal, J.L., additional, Jachmich, S., additional, Lvovskiy, A., additional, Paz-Soldan, C., additional, Reux, C., additional, Shiraki, D., additional, and Sweeney, R., additional

Published
2023
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47. Reducing the L-H transition power threshold in ITER-similar-shape DIII-D hydrogen plasmas

Author

Schmitz, L., primary, Wilcox, R.S., additional, Shiraki, D., additional, Rhodes, T.L., additional, Yan, Z., additional, McKee, G.R., additional, Callahan, K.J., additional, Chrystal, C., additional, Haskey, S.R., additional, Liu, Y.Q., additional, Laggner, F., additional, Zeng, L., additional, Osborne, T.H., additional, Grierson, B.A., additional, Paz-Soldan, C., additional, Leuthold, N., additional, Lyons, B.C., additional, Gohil, P., additional, and Petty, C.C., additional

Published
2022
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49. 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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