Fusion Simulations Reveal the Multi-Scale Nature of Tokamak Turbulence

Scientists use supercomputer simulations to understand the complex interplay between large-scale ion and small-scale electron plasma motion in determining fusion performance

Image courtesy of E.A. Belli
The contrast between turbulence driven by large-scale ion motion (left) and multi-scale turbulence that couples with the fast, small-scale motion of electrons (right) to drive heat loss in a tokamak.

The Science

Creating efficient, self-sustaining fusion power requires good confinement of the heat in the plasma. Plasma confinement is limited by particle and energy losses due to turbulence. A new analysis used a powerful supercomputer to study this turbulence. The study examined the complex interaction between the slow, large-scale motion of hydrogen fuel ions and the fast, small-scale motion of electrons. It found that this so-called “multi-scale turbulence” is mostly responsible for the heat losses in the edge region of tokamak experiments in the conditions required for an optimized fusion reactor.

The Impact

Plasma turbulence can limit the performance of fusion reactors. Researchers know that the edge region of the tokamak plasma plays a key role in setting overall energy confinement. The new supercomputer simulations provide much-needed predictions of edge turbulence. This will aid fusion science researchers in designing next-generation fusion reactors like ITER with optimal fusion performance.

Summary

Previous simulations have focused on turbulence driven by the large-scale motion of hydrogen fuel ions. Recent advances in computing have enabled new simulations that can couple the space and time scales of hydrogen ions to the smaller spatial scales and faster time scales of the much lighter electrons. Hydrogen ions are 1800 times heavier than electrons.

Using one of the most powerful computers in the world, the Summit supercomputer at the Oak Ridge Leadership Computing Facility, a Department of Energy user facility, scientists performed the first simulations of plasma turbulence in the edge of tokamaks that capture the multi-scale ion-electron interaction. The team included researchers from General Atomics and the University of California San Diego. The simulations accurately predict the heat losses measured in experiments in the DIII-D tokamak. The findings reveal that turbulence at small electron scales can become the dominant driver of heat loss in the tokamak edge.

Contact

Emily Belli
General Atomics
[email protected]  

Funding

This work was funded by the Department of Energy Office of Science, Office of Fusion Energy Sciences.

Publications

Belli, E.A., Candy J., and Sfiligoi, I., Spectral Transition of Multiscale Turbulence in the Tokamak Pedestal. Plasma Physics and Controlled Fusion, 65, 024001 (2023). [DOI: 10.1088/1361-6587/aca9fa]

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Program: FES