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World-first use of 3D magnetic coils to stabilise fusion plasma

Monday 20 October, 2025

MAST Upgrade, the UK’s national fusion experiment, has demonstrated multiple world-first breakthroughs, while solving key fusion challenges, during its 4th scientific campaign


For the first time in a spherical tokamak, small magnetic coils have been used to stabilise instabilities in fusion plasmas


Researchers have demonstrated independent control of upper and lower divertors, opening new capabilities for future fusion power plants


The fourth campaign also achieved the best plasma shape ever recorded within the machine, a major factor in improving plasma performance


Oxford, United Kingdom (20 October 2025) – In a major breakthrough for fusion energy research, scientists at the UK Atomic Energy Authority (UKAEA) have used magnetic coils to apply a 3D magnetic field and stabilise instabilities in a spherical tokamak plasma for the first time. This achievement marks a significant step forward in the development of sustainable fusion energy within spherical tokamaks.


To achieve fusion using Mega Amp Spherical Tokamak (MAST) Upgrade, fusion fuel needs to be confined at high temperature within the tokamak to create a plasma.


If the plasma current, pressure or density is too high, the plasma can become unstable, reducing performance or risking damage to tokamak components. Maintaining plasma stability is one of fusion’s key challenges.


Edge Localised Modes (ELMs) are instabilities that occur at the edge of a plasma and could pose a serious challenge to the inner components of a future fusion power plant. Using Resonant Magnetic Perturbation (RMP) coils – which apply a small 3D magnetic field at the plasma edge – UKAEA researchers have demonstrated complete suppression of ELMs within the MAST Upgrade machine. This is the first time such suppression has been evidenced in a spherical tokamak.


James Harrison, Head of MAST Upgrade Science at UKAEA, said:


“Suppressing ELMs in a spherical tokamak is a landmark achievement. It is an important demonstration that advanced control techniques developed for conventional tokamaks can be successfully adapted to compact configurations to develop the scientific basis for future power plants like STEP, the Spherical Tokamak for Energy Production.”


MAST Upgrade, the largest spherical tokamak operating in the world, is designed in the shape of a cored apple, in contrast to other ring-shaped tokamaks. These findings were part of MAST Upgrade’s fourth scientific campaign, focused on plasma properties and controlling plasma exhaust.


Further work is planned in the next MAST Upgrade experimental campaign to verify and expand on this world-first finding. In time, these results will directly inform the design of ELM control systems for the UK’s STEP Fusion programme. In addition, they will also help to eliminate ELMs as a barrier to commercial fusion viability.


Advancing plasma exhaust solutions


In another world first, UKAEA researchers have demonstrated that they can independently control the plasma exhaust in the upper and lower divertors in MAST Upgrade without impacting the performance or density of the plasma in the main chamber of the tokamak.


A tokamak exhaust system – known as a divertor – takes the particles and heat ejected from the plasma and directs it onto surfaces within the tokamak. Managing plasma exhaust is another key fusion challenge, and the ability to independently control upper and lower divertors in a tokamak could significantly enhance the robustness and flexibility of future power plant operations.


Additionally, experiments involving nitrogen injection at the plasma edge have shown that energy can be more evenly distributed across plasma-facing components. This technique prevents excessive heat concentration and opens a new path for managing power exhaust in compact spherical tokamaks, bringing them in line with advanced exhaust solutions being explored in conventional aspect ratio machines.


Record performance and plasma shaping


MAST Upgrade also set a record for power injected into its plasma, reaching 3.8 megawatts using neutral beam heating. This milestone supports higher performance plasma scenarios and contributes to the development of power plant-relevant conditions.


In the latest round of experiments, the team also achieved the best plasma shape ever recorded on the machine, with an elongation of 2.5 – meaning the plasma height is 2.5 times its width.


The shaping of a plasma can have a stabilising effect, enabling higher-performance plasmas which have higher pressure and better confinement. Greater plasma elongation, or height divided by width, improves plasma performance and will be a key target for future fusion power plants like STEP.


Fulvio Militello, Executive Director of Plasma Science and Fusion Operations, UKAEA, said:


“I’m delighted with the ground-breaking findings from our team at UKAEA. These achievements reinforce the UK’s leadership in fusion research and bring us closer to realising fusion as a clean, safe, and abundant energy source for the future.”





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