Twisting magnetic fields for extreme plasma compression
Date:
July 15, 2020
Source:
University of Michigan
Summary:
A new spin on the magnetic compression of plasmas could improve
materials science, nuclear fusion research, X-ray generation and
laboratory astrophysics.
FULL STORY ==========================================================================
A new spin on the magnetic compression of plasmas could improve materials science, nuclear fusion research, X-ray generation and laboratory
astrophysics, research led by the University of Michigan suggests.
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The study shows that a spring-shaped magnetic field reduces the amount
of plasma that slips out between the magnetic field lines.
Known as the fourth state of matter, plasma is a gas so hot that electrons
rip free of their atoms. Researchers use magnetic compression to study
extreme plasma states in which the density is high enough for quantum mechanical effects to become important. Such states occur naturally
inside stars and gas giant planets due to compression from gravity.
The research group led by Ryan McBride, an associate professor of
nuclear engineering and radiological sciences at U-M, tests ways to
achieve states like this by imploding plasma cylinders with magnetic
fields. These cylinders have a tendency to break up in a "sausage link"
fashion when the magnetic field finds tiny divots in the cylinder's
surface and cuts into them. (The technical term is "sausage instability.") "It's like trying to squeeze a stick of soft butter with your hands," said McBride. "The butter squishes out between your fingers." The butter in McBride's analogy is plasma and the fingers are magnetic field lines. His
group looked for a way to keep the magnetic field from digging into the imperfections in the cylinder, instead causing the field to press more uniformly on the cylinder's outer surface. They did this by twisting
the magnetic field into a helix, that spring-like shape, and varying
the angle at which the helix pressed on the plasma cylinder. This made
it harder for the magnetic field to slice in -- the field moved across
many divots rather than pressing into any one divot for too long.
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The most twisted magnetic configurations tested in these experiments
reduced the length of the escaping plasma tentacles by about 70%. The
research was done in collaboration with Sandia National Laboratories
and the Laboratory of Plasma Studies at Cornell University.
The team changed the shape of the magnetic field by changing the way
that the electrical current -- over 1 million amperes -- ran through
the compression device. The electrical current typically runs up
through the central cylinder that is to be compressed and then back
down through straight "return current" columns that surround the central cylinder. This produces a cylindrical magnetic field that surrounds the
central cylinder. To transform the cylindrical field into a helix, the
team twisted the return-current columns around the central cylinder. The central cylinder starts out as a metal foil, but the huge electrical
current quickly transforms the metal into a plasma.
They ran the experiments on the Cornell Beam Research Accelerator.
"Designing the return current structures was an interesting balancing
act," said Paul Campbell, first author on the paper and a Ph.D. student
in nuclear engineering and radiological sciences at U-M. "We weren't sure
we could even get these structures machined, but fortunately, metal 3D
printing has advanced far enough that we were able to get them printed instead." Campbell explained that when the structures are more twisted,
less current runs through them, so the columns had to be placed closer to
the imploding plasma to compensate. At the same time, they needed gaps in
the structure so that they could see what was going on with the implosion.
In line with replicating the conditions inside stars, magnetic compression
is a method for compressing nuclear fusion fuel -- typically variants of hydrogen - - to study the processes that power stars. The technique can
also generate powerful X-ray bursts and simulate astrophysical phenomena
such as plasma jets near black holes.
A paper on this research, "Stabilization of liner implosions via
a dynamic screw pinch," is accepted by the journal Physical Review
Letters. The research will also be featured in an invited talk at the
annual conference of the American Physical Society's Division of Plasma
Physics in November 2020.
The study was funded by the National Science Foundation and the Department
of Energy. The opinions, findings and conclusions or recommendations
expressed are those of the authors and do not necessarily reflect the
views of the National Science Foundation or the U.S. Department of Energy.
========================================================================== Story Source: Materials provided by University_of_Michigan. Original
written by Kate McAlpine. Note: Content may be edited for style and
length.
========================================================================== Journal Reference:
1. Paul C. Campbell, T. M. Jones, J. M. Woolstrum, N. M. Jordan, P. F.
Schmit, J. B. Greenly, W. M. Potter, E. S. Lavine, B. R. Kusse,
D. A.
Hammer, and R. D. McBride. Stabilization of liner implosions via
a dynamic screw pinch. Phys. Rev. Lett., 2020 (Accepted) [abstract] ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2020/07/200715142402.htm
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