A key challenge for scientists striving to produce on Earth the fusion energy that powers the sun and stars is preventing what are called runaway electrons, particles unleashed in disrupted fusion experiments that can bore holes in tokamaks, the doughnut-shaped machines that house the experiments. Scientists led by researchers at the U.S. Department of Energy’s (DOE) Princeton Plasma Physics Laboratory (PPPL) have used a novel diagnostic with wide-ranging capabilities to detect the birth, and the linear and exponential growth phases of high-energy runaway electrons, which may allow researchers to determine how to prevent the electrons’ damage.
“We need to see these electrons at their initial energy rather than when they are fully grown and moving at near the speed of light,” said PPPL physicist Luis Delgado-Aparicio, who led the experiment that detected the early runaways on the Madison Symmetric Torus (MST) at the University of Wisconsin-Madison. “The next step is to optimize ways to stop them before the runaway electron population can grow into an avalanche,” said Delgado-Aparicio, lead author of a first paper that details the findings in the Review of Scientific Instruments.
Fusion reactions produce vast amounts of energy by combining light elements in the form of plasma – the hot, charged state of matter composed of free electrons and atomic nuclei that makes up 99 percent of the visible universe. Scientists the world over are seeking to produce and control fusion on Earth for a virtually inexhaustible supply of safe and clean power for generating electricity
PPPL collaborated with the University of Wisconsin to install the multi-energy pinhole camera on MST, which served as a testbed for the camera’s capabilities. The diagnostic upgrades and redesigns a camera that PPPL had previously installed on the now-shuttered Alcator C-Mod tokamak at the Massachusetts Institute of Technology (MIT), and is unique in its ability to record not only the properties of the plasma in time and space but its energy distribution as well.
That prowess enables researchers to characterize both the evolution of the superhot plasma as well as the birth of runaway electrons, which begin at low energy. “If we understand the energy content I can tell you what is the density and temperature of the background plasma as well as the amount of runaway electrons,” Delgado Aparicio said. “So by adding this new energy variable we can find out several quantities of the plasma and use it as a diagnostic.”
Use of the novel camera moves technology forward. “This certainly has been a great scientific collaboration,” said physicist Carey Forest, a University of Wisconsin professor who oversees the MST, which he describes as “a very robust machine that can produce runaway electrons that don’t endanger its operation.”
As a result, Forest said, “Luis’s ability to diagnose not only the birth location and initial linear growth phase of the electrons as they are accelerated, and then to follow how they are transported from the outside in, is fascinating. Comparing his diagnosis to modeling will be the next step and of course a better understanding may lead to new mitigation techniques in the future.”
Delgado-Aparicio is already looking ahead. “I want to take all the expertise that we have developed on MST and apply it to a large tokamak,” he said. Two post-doctoral researchers who Delgado-Aparicio oversees can build upon the MST findings but at WEST, the Tungsten (W) Environment in Steady-state Tokamak operated by the French Alternative Energies and Atomic Energy Commission (CEA) in Cadarache, France.
Range of uses
“What I want to do with my post-docs is to use cameras for a lot of different things including particle transport, confinement, radio-frequency heating and also this new twist, the diagnosis and study of runaway electrons,” Delgado-Aparicio said. “We basically would like to figure out how to give the electrons a soft landing, and that could be a very safe way to deal with them.”
Two dozen researchers participated in the research with Delgado-Aparicio and co-authored the paper about this work. Included were seven physicists from PPPL and eight from the University of Wisconsin. Joining them were a total of three researchers from the University of Tokyo, Kyushi University and the National Institutes for Quantum and Radiological Science and Technology in Japan; five members of Dectris, a Swiss manufacturer of detectors; and one physicist from Edgewood College in Madison, Wisconsin.
Support for this work comes from the DOE Office of Science.