Highest fusion performance without harmful edge energy bursts in tokamak

Kim, S. K.; Shousha, R.; Yang, S. M.; Hu, Q.; Hahn, S. H.; Jalalvand, A.; Park, J.-K.; Logan, N. C.; Nelson, A. O.; Na, Y.-S.; Nazikian, R.; Wilcox, R.; Hong, R.; Rhodes, T.; Paz-Soldan, C.; Jeon, Y. M.; Kim, M. W.; Ko, W. H.; Lee, J. H.; Battey, A.; Yu, G.; Bortolon, A.; Snipes, J.; Kolemen, E.

doi:10.1038/s41467-024-48415-w

Nat Commun

2024

DOI: 10.1038/s41467-024-48415-w

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Highest fusion performance without harmful edge energy bursts in tokamak

S. K. Kim,

R. Shousha,

S. M. Yang

et al.

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 machi… Show more

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Cited by 5 publications

References 91 publications

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Laser Ignition Breakthrough—and More Startups—Brighten Outlook for Nuclear Fusion

Leslie

2024

Engineering

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Laser Ignition Breakthrough—and More Startups—Brighten Outlook for Nuclear Fusion

Leslie

2024

Engineering

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Modelling of the electron cyclotron emission burst from a laboratory tokamak plasma with loss-cone maser instability

Yu,

Kramer,

Zhu

et al. 2024

J. Plasma Phys.

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The maser instability associated with the loss-cone distribution has been widely invoked to explain the radio bursts observed in the astrophysical plasma environment, such as aurora and corona. In the laboratory plasma of a tokamak, events reminiscent of these radio bursts have also been frequently observed as an electron cyclotron emission (ECE) burst in the microwave range ( $\mathrm{\sim }2{f_{\textrm{ce}}}$ near the last closed flux surface) during transient magnetohydrodynamic events. These bursts have a short duration of ~10 μs and display a radiation spectrum corresponding to a radiation temperature ${T_{e,\textrm{rad}}}$ of over $30\ \textrm{keV}$ while the edge thermal electron temperature ${T_e}$ is only in the range of $1\ \textrm{keV}$ . Suprathermal electrons can be generated through magnetic reconnection, and a loss-cone distribution can be generated through open stochastic field lines in the magnetic mirror of the near-edge region of a tokamak plasma. Radiation modelling shows that a sharp distribution gradient $\partial f/\partial {v_ \bot } > 0$ at the loss-cone boundary can cause a negative absorption of ECE radiation through the maser instability. The negative absorption then amplifies the radiation so that the microwave intensity is significantly stronger than the thermal value. The significant ${T_{e,\textrm{rad}}}$ from the simulations suggests the potential role of the loss-cone maser instability in generating the ECE burst in a tokamak.

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Effect of energetic ions on edge-localized modes in tokamak plasmas

Dominguez-Palacios,

Futatani,

Garcia-Munoz

et al. 2025

Nat. Phys.

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The most efficient and promising operational regime for the International Thermonuclear Experimental Reactor tokamak is the high-confinement mode. In this regime, however, periodic relaxations of the plasma edge can occur. These edge-localized modes pose a threat to the integrity of the fusion device. Here we reveal the strong impact of energetic ions on the spatio-temporal structure of edge-localized modes in tokamaks using nonlinear hybrid kinetic–magnetohydrodynamic simulations. A resonant interaction between the fast ions at the plasma edge and the electromagnetic perturbations from the edge-localized mode leads to an energy and momentum exchange. Energetic ions modify, for example, the amplitude, frequency spectrum and crash timing of edge-localized modes. The simulations reproduce some observations that feature abrupt and large edge-localized mode crashes. The results indicate that, in the International Thermonuclear Experimental Reactor, a strong interaction between the fusion-born alpha particles and ions from neutral beam injection, a main heating and fast particle source, is expected with predicted edge-localized mode perturbations. This work advances the understanding of the physics underlying edge-localized mode crashes in the presence of energetic particles and highlights the importance of including energetic ion kinetic effects in the optimization of edge-localized mode control techniques and regimes that are free of such modes.

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Highest fusion performance without harmful edge energy bursts in tokamak

Cited by 5 publications

References 91 publications

Laser Ignition Breakthrough—and More Startups—Brighten Outlook for Nuclear Fusion

Laser Ignition Breakthrough—and More Startups—Brighten Outlook for Nuclear Fusion

Modelling of the electron cyclotron emission burst from a laboratory tokamak plasma with loss-cone maser instability

Effect of energetic ions on edge-localized modes in tokamak plasmas

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