Pinch (plasma physics)


A pinch is the compression of an electrically conducting filament by magnetic forces. The conductor is usually a plasma, but could also be a solid or liquid metal. Pinches were the first type of device used for controlled nuclear fusion.
The phenomenon may also be referred to as a Bennett pinch, electromagnetic pinch, magnetic pinch, pinch effect or plasma pinch.
Pinches occur naturally in electrical discharges such as lightning bolts, the aurora, current sheets, and solar flares.

Basic mechanism

Types

Pinches exist in laboratories and in nature. Pinches differ in their geometry and operating forces. These include:
; Uncontrolled: Any time an electric current moves in large amounts a magnetic force can pull together plasma. This can be insufficient for fusion.
; Sheet pinch: An astrophysical effect, this arises from vast sheets of charge particles.
; Z-pinch: The current runs down the axis of the cylinder while the magnetic field is azimuthal
; Theta pinch: The magnetic field runs down the axis of the cylinder, while the electric field is in the azimuthal direction
; Screw pinch: A combination of a Z-pinch and theta pinch
; Reversed field pinch: This is an attempt to do a Z-pinch inside an endless loop. The plasma has an internal magnetic field. As you move out from the center of this ring, the magnetic field reverses direction. Also called a toroidal pinch.
; Inverse pinch: An early fusion concept, this device consisted of a rod surrounded by plasma. Current traveled through the plasma and returned along the center rod. This geometry was slightly different than a z-pinch in that the conductor was in the center, not the sides.
; Cylindrical pinch
; Orthogonal pinch effect
; Ware pinch: A pinch that happens inside Tokamaks. This is when particles inside the Banana orbit condense together.
; MagLIF: A Z-pinch of pre-heated, pre-magnetized fuel inside a metal liner, which could lead to ignition and practical fusion energy with a larger pulsed-power driver.

Common behavior

Pinches may become unstable. They radiate energy as light across the whole electromagnetic spectrum including radio waves, x-rays, gamma rays, synchrotron radiation, and visible light. They also produce neutrons, as a product of fusion.

Applications and devices

Pinches are used to generate X-rays and the intense magnetic fields generated are used in electromagnetic forming of metals. They also have applications in particle beams including particle beam weapons, astrophysics studies and it has been proposed to use them in space propulsion. A number of large pinch machines have been built to study fusion power; here are several:
Many high-voltage electronics enthusiasts make their own crude electromagnetic forming devices. They use pulsed power techniques to produce a theta pinch capable of crushing an aluminium soft drink can using the Lorentz forces created when large currents are induced in the can by the strong magnetic field of the primary coil.
An electromagnetic aluminium can crusher consists of four main components: a high voltage DC power supply, which provides a source of electrical energy, a large energy discharge capacitor to accumulate the electrical energy, a high voltage switch or spark gap, and a robust coil through which the stored electrical energy can be quickly discharged in order to generate a correspondingly strong pinching magnetic field.
In practice, such a device is somewhat more sophisticated than the schematic diagram suggests, including electrical components that control the current in order to maximize the resulting pinch, and to ensure that the device works safely. For more details, see the notes.

History

The first creation of a Z-pinch in the laboratory may have occurred in 1790 in Holland when Martinus van Marum created an explosion by discharging 100 Leyden jars into a wire. The phenomenon was not understood until 1905, when Pollock and Barraclough investigated a compressed and distorted length of copper tube from a lightning rod after it had been struck by lightning. Their analysis showed that the forces due to the interaction of the large current flow with its own magnetic field could have caused the compression and distortion. A similar, and apparently independent, theoretical analysis of the pinch effect in liquid metals was published by Northrupp in 1907. The next major development was the publication in 1934 of an analysis of the radial pressure balance in a static Z-pinch by Bennett.
Thereafter, the experimental and theoretical progress on pinches was driven by fusion power research. In their article on the "Wire-array Z-pinch: a powerful x-ray source for ICF", M G Haines et al., wrote on the "Early history of Z-pinches".
In 1958, the world's first controlled thermonuclear fusion experiment was accomplished using a theta-pinch machine named Scylla I at the Los Alamos National Laboratory. A cylinder full of deuterium was converted into a plasma and compressed to 15 million degrees Celsius under a theta-pinch effect. Lastly, at Imperial College in 1960, led by R Latham, the Plateau–Rayleigh instability was shown, and its growth rate measured in a dynamic Z-pinch.

Equilibrium analysis

One dimension

In plasma physics three pinch geometries are commonly studied: the θ-pinch, the Z-pinch, and the screw pinch. These are cylindrically shaped. The cylinder is symmetric in the axial direction and the azimuthal directions. The one-dimensional pinches are named for the direction the current travels.

The θ-pinch

The θ-pinch has a magnetic field directed in the z direction and a large diamagnetic current directed in the θ direction. Using Ampère's law
Since B is only a function of r we can simplify this to
So J points in the θ direction.
Thus, the equilibrium condition for the θ-pinch reads:
θ-pinches tend to be resistant to plasma instabilities; This is due in part to Alfvén's theorem.

The Z-pinch

The Z-pinch has a magnetic field in the θ direction and a current J flowing in the z direction. Again, by electrostatic Ampère's law,
Thus, the equilibrium condition,, for the Z-pinch reads:
Since particles in a plasma basically follow magnetic field lines, Z-pinches lead them around in circles. Therefore, they tend to have excellent confinement properties.

The screw pinch

The screw pinch is an effort to combine the stability aspects of the θ-pinch and the confinement aspects of the Z-pinch. Referring once again to Ampère's law,
But this time, the B field has a θ component and a z component
So this time J has a component in the z direction and a component in the θ direction.
Finally, the equilibrium condition for the screw pinch reads:

The screw pinch via colliding optical vortices

The screw pinch might be produced in laser plasma by colliding optical vortices of ultrashort duration. For this purpose optical vortices ought to be phase-conjugated.
The magnetic field distribution is given here again via Ampère's law:

Two dimensions

A common problem with one-dimensional pinches is the end losses. Most of the motion of particles is along the magnetic field. With the θ-pinch and the screw-pinch, this leads particles out of the end of the machine very quickly, leading to a loss of mass and energy. On top of this problem, the Z-pinch has major stability problems. Though particles can be reflected to some extent with magnetic mirrors, even these allow many particles to pass. A common method of beating these end losses, is to bend the cylinder around into a torus. Unfortunately this breaks θ symmetry, as paths on the inner portion of the torus are shorter than similar paths on the outer portion. Thus, a new theory is needed. This gives rise to the famous Grad–Shafranov equation. Numerical solutions to the Grad–Shafranov equation have also yielded some equilibria, most notably that of the reversed field pinch.

Three dimensions

As of 2015, there is not a coherent analytical theory for three-dimensional equilibria. The general approach to finding three-dimensional equilibria is to solve the vacuum ideal MHD equations. Numerical solutions have yielded designs for stellarators. Some machines take advantage of simplification techniques such as helical symmetry. However, for an arbitrary three-dimensional configuration an equilibrium relation, similar to that of the 1-D configurations exists:
Where κ is the curvature vector defined as:
with b the unit vector tangent to B.

Formal treatment

The Bennett relation

Consider a cylindrical column of fully ionized quasineutral plasma, with an axial electric field, producing an axial current density, j, and associated azimuthal magnetic field, B. As the current flows through its own magnetic field, a pinch is generated with an inward radial force density of j x B. In a steady state with forces balancing:
where ∇p is the magnetic pressure gradient, and pe and pi are the electron and ion pressures, respectively. Then using Maxwell's equation and the ideal gas law, we derive:
where N is the number of electrons per unit length along the axis, Te and Ti are the electron and ion temperatures, I is the total beam current, and k is the Boltzmann constant.

The generalized Bennett relation

The generalized Bennett relation considers a current-carrying magnetic-field-aligned cylindrical plasma pinch undergoing rotation at angular frequency ω. Along the axis of the plasma cylinder flows a current density jz, resulting in an azimuthal magnetίc field Βφ. Originally derived by Witalis, the generalized Bennett relation results in:
The positive terms in the equation are expansional forces while the negative terms represent beam compressional forces.

The Carlqvist relation

The Carlqvist relation, published by Per Carlqvist in 1988, is a specialization of the generalized Bennett relation, for the case that the kinetic pressure is much smaller at the border of the pinch than in the inner parts. It takes the form
and is applicable to many space plasmas.
The Carlqvist relation can be illustrated, showing the total current versus the number of particles per unit length in a Bennett pinch. The chart illustrates four physically distinct regions. The plasma temperature is quite cold, containing mainly hydrogen with a mean particle mass 3×10−27 kg. The thermokinetic energy Wk >> πa2 pk. The curves, ΔWBz show different amounts of excess magnetic energy per unit length due to the axial magnetic field Bz. The plasma is assumed to be non-rotational, and the kinetic pressure at the edges is much smaller than inside.
Chart regions: In the top-left region, the pinching force dominates. Towards the bottom, outward kinetic pressures balance inwards magnetic pressure, and the total pressure is constant. To the right of the vertical line ΔWBz = 0, the magnetic pressures balances the gravitational pressure, and the pinching force is negligible. To the left of the sloping curve ΔWBz = 0, the gravitational force is negligible. Note that the chart shows a special case of the Carlqvist relation, and if it is replaced by the more general Bennett relation, then the designated regions of the chart are not valid.
Carlqvist further notes that by using the relations above, and a derivative, it is possible to describe the Bennett pinch, the Jeans criterion, force-free magnetic fields, gravitationally balanced magnetic pressures, and continuous transitions between these states.