A longstanding mystery in nuclear fusion research may have been solved, thanks to a new theoretical model that could help scientists resolve why simulations often underestimate the turbulence at the edge of tokamak plasmas.
Researchers at the University of California, San Diego, made the discovery, which identified instabilities at the plasma’s outer boundary, a phenomenon previously overlooked by fusion scientists, as a key source of this discrepancy.
The new research aims to account for these “boundary effects” and could potentially lead to new advancements in plasma confinement, offering a crucial step toward attaining sustained energy production in fusion reactors.
Predicting Plasma Behavior
The research, detailed in a new study by physicists Mingyun Cao and Patrick Diamond, focuses on the donut-shaped reactors known as tokamaks, which use magnetic fields to confine high-energy plasma during fusion reactions.
The extremely energetic nature of tokamak plasma confinement relies on sophisticated simulations that help physicists predict plasma behavior. However, these models have had difficulties in the past when it comes to accurately capturing the width of the turbulent region that forms between the core and edge of the plasma.
For Cao and Diamond, this gap in understanding may be due to an incomplete understanding of the impact of edge instabilities, a factor that they say is “critically important to the optimization of magnetically confined fusion plasmas.”
“Since early proposals, there has been persistent speculation that inward propagation of turbulence from the boundary is a possible means to energize the edge-core coupling region,” Cao and Diamond write in their new study’s abstract. “However, the detailed mechanism of this process has remained a mystery until recent experiments observed that regular, intense gradient relaxation events generated blob-void pairs very close to the last closed flux surface.”
“Blobs” and “Voids”
Under ideal conditions, a tokamak maintains a sharp gradient in plasma temperature and density at its outer boundary. That’s not necessarily the case in the real world, where plasmas frequently encounter what physicists call a gradient relaxation event, where the plasma edge fragments into outward-moving “blobs” and inward-moving “voids.”
While “blobs” have been extensively studied because of their interactions with tokamak walls, “voids” have proven to be more elusive during observations—until now.
By developing a first-principles model that treats the voids as coherent structures possessing particle-like properties, Cao and Diamond observed that as voids move inward through the plasma, they generate what is known as plasma drift waves. These waves involve oscillations similar to the electromagnetic radiation emitted by fast-moving charged particles in a medium. Once they manifest, the drift waves can encourage local turbulence.
Based on the team’s calculations, it is now believed that the drift waves help to broaden the turbulent layer beyond the predictions of existing models.
In their paper’s abstract, they write that their new model “shows promise to resolve several questions surrounding the shortfall problem and the strong turbulence in the edge-core coupling region.” Cao and Diamond are conducting further studies to validate their new findings by comparing theoretical predictions with recent experimental data.
If they confirm their findings, the insights they glean could ultimately help refine future tokamak designs and may even help advance practical fusion energy closer to reality.
Cao and Diamond’s new paper, “Physics of Edge-Core Coupling by Inward Turbulence Propagation, was published in Physics Review Letters on June 11, 2025.
Micah Hanks is the Editor-in-Chief and Co-Founder of The Debrief. He can be reached by email at micah@thedebrief.org. Follow his work at micahhanks.com and on X: @MicahHanks.