Highest Fusion Performance without Harmful Edge Energy Bursts in Tokamak

TL;DR

This paper introduces a machine learning-based real-time 3D magnetic field optimization method for tokamaks, achieving high fusion performance without damaging instabilities, demonstrated on DIII-D and KSTAR devices.

Contribution

It presents a novel adaptive 3D field optimization approach using machine learning, enabling stable, high-performance fusion in tokamaks without harmful energy bursts.

Findings

Achieved highest fusion performance without damaging instabilities.

Demonstrated automated 3D optimization relevant to ITER.

Validated on multiple tokamaks with real-time adaptability.

Abstract

The path of tokamak fusion and 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 high-confinement plasmas. The application of 3D magnetic perturbations is the method in ITER and possibly in future fusion power plants to suppress this instability and avoid energy busts damaging the device. Unfortunately, the conventional use of the 3D field in tokamaks typically leads to degraded fusion performance and an increased risk of other plasma instabilities, two severe issues for reactor implementation. In this work, we present an innovative 3D field optimization, exploiting machine learning, real-time adaptability, and multi-device capabilities to overcome these limitations. This integrated scheme is successfully deployed on DIII-D and KSTAR tokamaks, consistently achieving reactor-relevant core confinement and the highest fusion performance without triggering damaging instabilities or bursts while demonstrating ITER-relevant automated 3D optimization for the first time. This is enabled both by advances in the physics understanding of self-organized transport in the plasma edge and by advances in machine-learning technology, which is used to optimize the 3D field spectrum for automated management of a volatile and complex system. These findings establish real-time adaptive 3D field optimization as a crucial tool for ITER and future reactors to maximize fusion performance while simultaneously minimizing damage to machine components.