magnetic confinement fusion

Improving this ratio is a major goal of all magnetic confinement fusion devices.

While not currently economically viable, magnetic confinement fusion shows promise as a future energy source.

I'd read something one time about the density of plasma inside an magnetic confinement fusion experiment, and it as surprisingly low (to me, at least).

For example, a typical magnetic confinement fusion plasma is 15 keV, or 170 megakelvins.

An approach that most scientists now regard as more promising is called magnetic confinement fusion, the system embodied in the Princeton tokamak.

It is a Magnetic confinement fusion spherical tokamak with an insulating vacuum vessel.

The most widely studied configuration for terrestrial fusion is the tokamak, a form of magnetic confinement fusion.

In magnetic confinement fusion, the necessary conditions are approached by heating a plasma contained by magnetic fields.

ICF is one of two major branches of fusion energy research, the other being magnetic confinement fusion.

A Riggatron is a magnetic confinement fusion reactor design created by Robert W. Bussard in the late 1970s.

The key concept in magnetic confinement fusion is that ions and electrons in a plasma will rotate around magnetic lines of force.

Plasma rail guns are being evaluated for applications in magnetic confinement fusion for disruption mitigation and tokamak refueling.

In magnetic confinement fusion (MCF) reactor designs, the plasma is confined within a vacuum chamber using a series of magnetic fields.

A stellarator is a magnetic confinement fusion device which generates all required magnetic fields to confine high temperature plasma by external magnetic coils.

Magnetic confinement fusion devices exploit the fact that charged particles in a magnetic field experience a Lorentz force and follow helical paths along the field lines.

The Lawson criterion applies to inertial confinement fusion as well as to magnetic confinement fusion but is more usefully expressed in a different form.

The OED also records the later usage of these terms in the context of toroidally confined plasmas, as encountered in magnetic confinement fusion.

In the area of energy, the main research directions are: materials and decentralized energy systems, energy modeling and analysis (GAME), magnetic confinement fusion.

This process is the cause of solar flares and is one reason for the difficulty of magnetic confinement fusion, which requires strong electric currents in a hot plasma.

Magnetic confinement fusion is an approach to generating fusion power that uses magnetic fields to confine the hot fusion fuel in the form of a plasma.

Magnetic confinement fusion attempts to create the conditions needed for fusion energy production by using the electrical conductivity of the plasma to contain it with magnetic fields.

The polywell differs from the fusor in that the electrons are magnetically confined, so that it is also related to magnetic confinement fusion, most closely to magnetic mirrors.

Their suitability to prepare and reproduce in a microscopic volume the conditions of high temperature astrophysical plasmas and magnetic confinement fusion plasmas make them very appropriate research tools.

This was some time after the successful design of magnetic confinement fusion systems, and around the time of the particularly successful tokamak design that was introduced in the early '70s.