Fusion experiments on:
[Wikipedia]
[Google]
[Amazon]
Experiments directed toward developing fusion power are invariably done with dedicated machines which can be classified according to the principles they use to confine the plasma (physics), plasma fuel and keep it hot.
The major division is between Magnetic confinement fusion, magnetic confinement and Inertial confinement fusion, inertial confinement. In magnetic confinement, the tendency of the hot plasma to expand is counteracted by the Lorentz force between currents in the plasma and magnetic fields produced by external coils. The particle densities tend to be in the range of to and the linear dimensions in the range of . The particle and energy confinement times may range from under a millisecond to over a second, but the configuration itself is often maintained through input of particles, energy, and current for times that are hundreds or thousands of times longer. Some concepts are capable of maintaining a plasma indefinitely.
In contrast, with inertial confinement, there is nothing to counteract the expansion of the plasma. The confinement time is simply the time it takes the plasma pressure to overcome the inertia of the particles, hence the name. The densities tend to be in the range of to and the plasma radius in the range of 1 to 100 micrometers. These conditions are obtained by irradiation, irradiating a millimeter-sized solid pellet with a nanosecond laser or ion pulse. The outer layer of the pellet is ablation, ablated, providing a reaction force that compresses the central 10% of the fuel by a factor of 10 or 20 to 103 or times solid density. These microplasmas disperse in a time measured in nanoseconds. For a fusion power reactor, a repetition rate of several per second will be needed.
Experiments directed toward developing fusion power are invariably done with dedicated machines which can be classified according to the principles they use to confine the plasma (physics), plasma fuel and keep it hot.
The major division is between Magnetic confinement fusion, magnetic confinement and Inertial confinement fusion, inertial confinement. In magnetic confinement, the tendency of the hot plasma to expand is counteracted by the Lorentz force between currents in the plasma and magnetic fields produced by external coils. The particle densities tend to be in the range of to and the linear dimensions in the range of . The particle and energy confinement times may range from under a millisecond to over a second, but the configuration itself is often maintained through input of particles, energy, and current for times that are hundreds or thousands of times longer. Some concepts are capable of maintaining a plasma indefinitely.
In contrast, with inertial confinement, there is nothing to counteract the expansion of the plasma. The confinement time is simply the time it takes the plasma pressure to overcome the inertia of the particles, hence the name. The densities tend to be in the range of to and the plasma radius in the range of 1 to 100 micrometers. These conditions are obtained by irradiation, irradiating a millimeter-sized solid pellet with a nanosecond laser or ion pulse. The outer layer of the pellet is ablation, ablated, providing a reaction force that compresses the central 10% of the fuel by a factor of 10 or 20 to 103 or times solid density. These microplasmas disperse in a time measured in nanoseconds. For a fusion power reactor, a repetition rate of several per second will be needed.
Magnetic confinement
Within the field of magnetic confinement fusion, magnetic confinement experiments, there is a basic division between torus, toroidal and open magnetic field topology, topologies. Generally speaking, it is easier to contain a plasma in the direction perpendicular to the field than parallel to it. Parallel confinement can be solved either by bending the field lines back on themselves into circles or, more commonly, toroidal surfaces, or by constricting the bundle of field lines at both ends, which causes some of the particles to be reflected by the magnetic mirror, mirror effect. The toroidal geometries can be further subdivided according to whether the machine itself has a toroidal geometry, i.e., a solid core through the center of the plasma. The alternative is to dispense with a solid core and rely on currents in the plasma to produce the toroidal field. Mirror machines have advantages in a simpler geometry and a better potential for direct conversion of particle energy to electricity. They generally require higher magnetic fields than toroidal machines, but the biggest problem has turned out to be confinement. For good confinement there must be more particles moving perpendicular to the field than there are moving parallel to the field. Such a non-Maxwell–Boltzmann distribution, Maxwellian velocity distribution is, however, very difficult to maintain and energetically costly. The mirrors' advantage of simple machine geometry is maintained in machines which produce compact toroids, but there are potential disadvantages for stability in not having a central conductor and there is generally less possibility to control (and thereby optimize) the magnetic geometry. Compact toroid concepts are generally less well developed than those of toroidal machines. While this does not necessarily mean that they cannot work better than mainstream concepts, the uncertainty involved is much greater. Somewhat in a class by itself is the Z-pinch, which has circular field lines. This was one of the first concepts tried, but it did not prove very successful. Furthermore, there was never a convincing concept for turning the pulsed machine requiring electrodes into a practical reactor. The dense plasma focus is a controversial and "non-mainstream" device that relies on currents in the plasma to produce a toroid. It is a pulsed device that depends on a plasma that is not in equilibrium and has the potential for direct conversion of particle energy to electricity. Experiments are ongoing to test relatively new theories to determine if the device has a future.Toroidal machine
Toroidal machines can be axially symmetric, like the tokamak and the reversed field pinch (RFP), or asymmetric, like the stellarator. The additional degree of freedom gained by giving up toroidal symmetry might ultimately be usable to produce better confinement, but the cost is complexity in the engineering, the theory, and the experimental diagnostics. Stellarators typically have a periodicity, e.g. a fivefold rotational symmetry. The RFP, despite some theoretical advantages such as a low magnetic field at the coils, has not proven very successful.Tokamak
Stellarator
Magnetic mirror
* Tabletop/Toytop, Lawrence Livermore National Laboratory, Livermore CA. * DCX/DCX-2, Oak Ridge National Laboratory * ORGA, Akademgorodok, Russia. * Baseball I/Baseball II Lawrence Livermore National Laboratory, Livermore CA. * 2X/2XIII/2XIII-B, Lawrence Livermore National Laboratory, Livermore CA. * Tandem Mirror Experiment, TMX, TMX-U Lawrence Livermore National Laboratory, Livermore CA. * Mirror Fusion Test Facility, MFTF Lawrence Livermore National Laboratory, Livermore CA. * Gas Dynamic Trap at Budker Institute of Nuclear Physics, Akademgorodok, Russia.Toroidal Z-pinch
* Perhapsatron (1953, USA) * ZETA (fusion reactor), ZETA (Zero Energy Thermonuclear Assembly) (1957, United Kingdom)Reversed field pinch (RFP)
* ETA-BETA II in Padua, Italy (1979–1989) * Reversed-Field eXperiment, RFX (Reversed-Field eXperiment), Consorzio RFX, Padova, Italy * Madison Symmetric Torus, MST (Madison Symmetric Torus), University of Wisconsin–Madison, United States * T2R, Royal Institute of Technology, Stockholm, Sweden * TPE-RX, National Institute of Advanced Industrial Science and Technology, AIST, Tsukuba, Japan * KTX (Keda Torus eXperiment) in China (since 2015)Spheromak
* Sustained Spheromak Physics ExperimentField-reversed configuration (FRC)
* C-2 Tri Alpha Energy * C-2U Tri Alpha Energy * C-2W TAE Technologies * LSX University of Washington * IPA University of Washington * HF University of Washington * IPA- HF University of WashingtonOpen field lines
Pinch (plasma physics), Plasma pinch
* Trisops – 2 facing theta-pinch guns * FF-2B, Lawrenceville Plasma Physics, United StatesLevitated dipole
* Levitated Dipole Experiment (LDX), MIT/Columbia University, United StatesInertial confinement
Laser-driven
Z-pinch
*Z Pulsed Power Facility *ZEBRA device at the University of Nevada's Nevada Terawatt Facility *Saturn accelerator at Sandia National Laboratory * MAGPIE at Imperial College London *COBRA at Cornell University *PULSOTRONInertial electrostatic confinement
*Fusor ** List of fusor examples *PolywellMagnetized target fusion
*FRX-L *FRCHX *General Fusion – under development *LINUS (fusion experiment), LINUS projectReferences
See also
* List of nuclear reactors {{Fusion power Fusion power Magnetic confinement fusion devices