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Zpinch

The z-pinch is a plasma confinement and compression technique in which a strong axial current is passed through a plasma column or a wire array. The current generates an azimuthal magnetic field around the plasma, and the resulting magnetic pressure acts inward to compress the plasma radially. This magnetic confinement is brief, occurring on nanosecond to microsecond timescales in pulsed-power devices.

Configurations of the z-pinch commonly include wire-array z-pinches, where many fine metal wires are arranged in

The z-pinch is noted for producing high temperatures and densities, making it a useful source of X-rays

A major challenge for z-pinch devices is plasma instability. Sausage (m=0) and kink (m=1) instabilities can distort

a
cylinder
and
a
rapid
current
vaporizes
and
ionizes
them;
and
gas-pillared
or
gas-fed
z-pinches,
where
plasma
is
formed
in
a
gas
or
low-density
medium
inside
a
coaxial
chamber.
In
both
cases,
the
current
is
directed
along
the
axial
direction
(the
z-axis),
and
the
resulting
magnetic
forces
drive
an
inward
collapse
of
the
plasma.
and
a
platform
for
high-energy-density
physics
experiments.
Pulsed-power
facilities,
such
as
the
Z-machine
at
Sandia
National
Laboratories,
generate
currents
of
tens
of
megaamperes
in
nanoseconds
to
create
intense
X-ray
pulses
used
for
imaging
and
for
inertial
confinement
fusion
research.
The
same
principles
underpin
laboratory
studies
in
radiation-dominated
plasmas
and
dynamic
hohlraums.
the
plasma
column
and
disrupt
confinement,
limiting
performance
and
uniformity.
Researchers
investigate
stability
control,
tailored
current
rise,
and
electrode
design
to
mitigate
these
effects.
Despite
difficulties,
the
z-pinch
remains
a
prominent
concept
in
pulsed-power
physics
and
high-energy-density
experiments.