Magnetic mirror

A magnetic mirror, also known as a magnetic trap or sometimes as a pyrotron, is a type of magnetic confinement fusion device used in fusion power to trap high temperature plasma using magnetic fields. The mirror was one of the earliest major approaches to fusion power, along with the stellarator and z-pinch machines.

In a classic magnetic mirror, a configuration of electromagnets is used to create an area with an increasing density of magnetic field lines at either end of a confinement volume. Particles approaching the ends experience an increasing force that eventually causes them to reverse direction and return to the confinement area.^[1] This mirror effect will occur only for particles within a limited range of velocities and angles of approach, while those outside the limits will escape, making mirrors inherently "leaky".

An analysis of early fusion devices by Edward Teller pointed out that the basic mirror concept is inherently unstable. In 1960, Soviet researchers introduced a new "minimum-B" configuration to address this, which was then modified by UK researchers into the "baseball coil" and by the US to "yin-yang magnet" layout. Each of these introductions led to further increases in performance, damping out various instabilities, but requiring ever-larger magnet systems. The tandem mirror concept, developed in the US and Russia at about the same time, offered a way to make energy-positive machines without requiring enormous magnets and power input.

By the late 1970s, many of the design problems were considered solved, and Lawrence Livermore Laboratory began the design of the Mirror Fusion Test Facility (MFTF) based on these concepts. The machine was completed in 1986, but by this time, experiments on the smaller Tandem Mirror Experiment revealed new problems. In a round of budget cuts, MFTF was mothballed, and eventually scrapped. A fusion reactor concept called the Bumpy torus made use of a series of magnetic mirrors joined in a ring. It was investigated at the Oak Ridge National Laboratory until 1986.^[2] The mirror approach has since seen less development, in favor of the tokamak, but mirror research continues today in countries like Japan and Russia.^[3]

^ Fitzpatrick, Richard. "Magnetic Mirrors." Home Page for Richard Fitzpatrick. The University of Texas at Austin, 31 Mar. 2011. Web. 19 July 2011.
^ Uckan; Dandl; Hendrick; Bettis; Lidsky; McAlees; Santoro; Watts; Yeh (January 1977). "The Elmo Bumpy Torus (EBT) Reactor". osti dot gov. Oak Ridge National Laboratory. Retrieved June 1, 2017.
^ T.C. Simonen, Three game changing discoveries: a simpler fusion concept? J. Fusion Energ., February 2016, Volume 35, Issue 1, pp 63-68. doi:10.1007/s10894-015-0017-2

[1] Fitzpatrick, Richard. "Magnetic Mirrors." Home Page for Richard Fitzpatrick. The University of Texas at Austin, 31 Mar. 2011. Web. 19 July 2011.

[2] Uckan; Dandl; Hendrick; Bettis; Lidsky; McAlees; Santoro; Watts; Yeh (January 1977). "The Elmo Bumpy Torus (EBT) Reactor". osti dot gov. Oak Ridge National Laboratory. Retrieved June 1, 2017.

[3] T.C. Simonen, Three game changing discoveries: a simpler fusion concept? J. Fusion Energ., February 2016, Volume 35, Issue 1, pp 63-68. doi:10.1007/s10894-015-0017-2

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