Tungsten isotope helps study how to armor future fusion reactors

Date:
August 28, 2020
Source:
DOE/Oak Ridge National Laboratory
Summary:
Researchers working with tungsten to armor the inside of future
fusion reactors had some surprising results when looking at the
probability of contamination.



FULL STORY ==========================================================================
The inside of future nuclear fusion energy reactors will be among the
harshest environments ever produced on Earth. What's strong enough to
protect the inside of a fusion reactor from plasma-produced heat fluxes
akin to space shuttles reentering Earth's atmosphere?

==========================================================================
Zeke Unterberg and his team at the Department of Energy's Oak Ridge
National Laboratory are currently working with the leading candidate:
tungsten, which has the highest melting point and lowest vapor pressure of
all metals on the periodic table, as well as very high tensile strength
-- properties that make it well-suited to take abuse for long periods of
time. They're focused on understanding how tungsten would work inside a
fusion reactor, a device that heats light atoms to temperatures hotter
than the sun's core so that they fuse and release energy. Hydrogen gas
in a fusion reactor is converted into hydrogen plasma -- a state of
matter that consists of partially ionized gas -- that is then confined
in a small region by strong magnetic fields or lasers.

"You don't want to put something in your reactor that only lasts a
couple of days," said Unterberg, a senior research scientist in ORNL's
Fusion Energy Division. "You want to have sufficient lifetime. We
put tungsten in areas where we anticipate there will be very high
plasma bombardment." In 2016, Unterberg and the team began conducting experiments in the tokamak, a fusion reactor that uses magnetic-fields
to contain a ring of plasma, at the DIII-D National Fusion Facility,
a DOE Office of Science user facility in San Diego. They wanted to know
whether tungsten could be used to armor the tokamak's vacuum chamber -- protecting it from rapid destruction caused by the effects of plasma --
without heavily contaminating the plasma itself. This contamination, if
not sufficiently managed, could ultimately extinguish the fusion reaction.

"We were trying to determine what areas in the chamber would be
particularly bad: where the tungsten was most likely to generate
impurities that can contaminate the plasma," Unterberg said.

To find that, the researchers used an enriched isotope of tungsten,
W-182, along with the unmodified isotope, to trace the erosion, transport
and redeposition of tungsten from within the divertor. Looking at the
movement of tungsten within the divertor -- an area within the vacuum
chamber designed to divert plasma and impurities -- gave them a clearer
picture of how it erodes from surfaces within the tokamak and interacts
with the plasma. The enriched tungsten isotope has the same physical and chemical properties as regular tungsten. The experiments at DIII-D used
small metal inserts coated with the enriched isotope placed close to,
but not at, the highest heat flux zone, an area in the vessel typically
called the divertor far-target region. Separately, at a divertor region
with the highest fluxes, the strike-point, researchers used inserts with
the unmodified isotope. The remainder of the DIII-D chamber is armored
with graphite.



==========================================================================
This setup allowed the researchers to collect samples on special probes temporarily inserted in the chamber for measuring impurity flow to
and from the vessel armor, which could give them a more precise idea
of where the tungsten that had leaked away from the divertor into the
chamber had originated.

"Using the enriched isotope gave us a unique fingerprint," Unterberg said.

It was the first such experiment conducted in a fusion device. One goal
was to determine the best materials and location for these materials for chamber armoring, while keeping impurities caused by plasma-material interactions largely contained to the divertor and not contaminating
the magnet-confined core plasma used to produce fusion.

One complication with the design and operation of divertors is impurity contamination in the plasma caused by edge-localized modes, or ELMs. Some
of these fast, high-energy events, akin to solar flares, can damage or
destroy vessel components such as divertor plates. The frequency of the
ELMs, the times per second these events occur, is an indicator of the
amount of energy released from the plasma to the wall. High-frequency
ELMs can release low amounts of plasma per eruption, but if the ELMs
are less frequent, the plasma and energy released per eruption is high,
with a greater probability for damage. Recent research has looked at
ways to control and increase the frequency of ELMs, such as with pellet injection or additional magnetic fields at very small magnitudes.

Unterberg's team found, as they expected, that having the tungsten far
from the high-flux strike-point greatly increased the probability of contamination when exposed to low-frequency ELMs that have higher energy content and surface contact per event. Additionally, the team found that
this divertor far-target region was more prone to contamination the SOL
even though it generally has lower fluxes than the strike-point. These seemingly counterintuitive results are being confirmed by ongoing divertor modeling efforts in relation to this project and future experiments
on DIII-D.



==========================================================================
This project involved a team of experts from across North America,
including collaborators from Princeton Plasma Physics Laboratory, Lawrence Livermore National Laboratory, Sandia National Laboratories, ORNL, General Atomics, Auburn University, the University of California at San Diego,
the University of Toronto, the University of Tennessee -- Knoxville,
and the University of Wisconsin-Madison, as it provided a significant
tool for plasma-material interaction research. DOE's Office of Science
(Fusion Energy Sciences) provided support for the study.

The team published research online earlier this year in the journal
Nuclear Fusion.

The research could immediately benefit the Joint European Torus, or JET,
and ITER, now under construction in Cadarache, France, both of which
use tungsten armor for the divertor.

"But we're looking at things beyond ITER and JET -- we're looking at
the fusion reactors of the future," Unterberg said. "Where is it best
to put tungsten, and where should you not put tungsten? Our ultimate
goal is to armor our fusion reactors, when they come, in a smart way." Unterberg said ORNL's unique Stable Isotopes Group, which developed and
tested the enriched isotope coating before putting it in a form useful
for the experiment, made the research possible. That isotope would not
have been available anywhere but from the National Isotope Development
Center at ORNL, which maintains a stockpile of almost every element isotopically separated, he said.

"ORNL has unique expertise and particular desires for this type of
research," Unterberg said. "We have a long legacy of developing isotopes
and using those in all kinds of research in different applications around
the world." In addition, ORNL manages US ITER.

Next, the team will look at how putting tungsten into differently shaped divertors might affect contamination of the core. Different divertor
geometries could minimize the effects of plasma-material interactions
on the core plasma, they have theorized. Knowing the best shape for a
divertor -- a necessary component for a magnetic-confined plasma device -- would put scientists one step closer to a viable plasma reactor.

"If we, as a society, say we want nuclear energy to happen, and we want to
move to the next stage," Unterberg said, "fusion would be the holy grail."

========================================================================== Story Source: Materials provided by
DOE/Oak_Ridge_National_Laboratory. Note: Content may be edited for style
and length.


========================================================================== Journal Reference:
1. E.A. Unterberg, T. Abrams, I. Bykov, D.C. Donovan, J.D. Duran, J.D.

Elder, H.Y. Guo, E.M. Hollmann, C.J. Lasnier, A.W. Leonard,
A.L. Moser, J.H. Nichols, R.E. Nygren, D.L. Rudakov, P.C. Stangeby,
D.M. Thomas, B.S.

Victor, J.G. Watkins, W.R. Wampler, M.P. Zach, S.L. Allen,
J.L. Barton, L.R. Baylor, J.A. Boedo, A.R. Briesemeister,
D.A. Buchenauer, J.D.

Coburn, C.P. Chrobak, R. Ding, D.A. Ennis, B.A. Grierson,
E.T. Hinson, C.A. Johnson, A.G. McLean, T.W. Petrie, O. Schmitz,
D. Shiraki, H.Q.

Wang, R.S. Wilcox, S. Zamperini. Localized divertor leakage
measurements using isotopic tungsten sources during edge-localized
mode-y H-mode discharges on DIII-D. Nuclear Fusion, 2020; 60 (1):
016028 DOI: 10.1088/ 1741-4326/ab537b ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2020/08/200828122725.htm

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