ZETA (fusion reactor) - meaning and definition. What is ZETA (fusion reactor)
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What (who) is ZETA (fusion reactor) - definition

FUSION REACTOR
Zero Energy Thermonuclear Assembly; Zero-Energy Toroidal Assembly; Zero-Energy Toroidal Thermonuclear Assembly; Zero Energy Toroidal Assembly
  • induction lamp]] is a low-temperature version of a toroidal plasma tube. At these temperatures the plasma can hit the tube walls without harm; further confinement is not needed.
  • The ZETA release was front-page news around the world.
  • This lightning rod was crushed when a large current passed through it. Studying this phenomenon led to the discovery of the [[pinch effect]].
  • A photograph of the [[kink instability]] in an early experiment at Aldermaston. The dark rectangle on the right is the induction magnet.
  • DIDO reactor]].
  • To test the basic concept of stabilised pinch, additional magnets were added to the earlier Mark 2 Torus, seen here as the wires wound around the vacuum chamber.
  • Mike Forrest operates a hand-built laser that is part of a Thomson scattering system used to measure temperatures in ZETA. This became a major diagnostic technique in the fusion field, used to this day.
  • A "shot" using deuterium is being prepared at the operator's station. Peter Thonemann is in the foreground. The reactor can be seen through the window.
  • Close-up of the ZETA reactor while undergoing maintenance. The main toroidal vacuum chamber is in the lower left, wound around by the current cables of the stabilising magnets. The larger device on the right is the main induction magnet, which created the pinch current in the plasma.
  • A team of reporters asks Cockcroft (centre) questions about ZETA. It was during this interview that Cockcroft offered his assessment that he was 90% sure the neutrons seen from the device were caused by fusion.
  • ZETA as seen from above in late 1957
  • The ZETA device at Harwell, United Kingdom. The toroidal confinement tube is roughly centred. The larger device on the right encircling the tube is the magnet used to induce the pinch current.
  • [[Elizabeth II]], guided by UKAEA Research Director [[John Cockcroft]], visits the ZETA fusion reactor while it is under construction. The main induction magnet dominates the left side of the image, the toroidal vacuum chamber has not yet been installed.
  • [[Bas Pease]] (centre) and Bob Carruthers (right) are interviewed by the BBC in front of the ZETA reactor.

ZETA (fusion reactor)         
ZETA, short for Zero Energy Thermonuclear Assembly, was a major experiment in the early history of fusion power research. Based on the pinch plasma confinement technique, and built at the Atomic Energy Research Establishment in the United Kingdom, ZETA was larger and more powerful than any fusion machine in the world at that time.
Fusion power         
EXPERIMENTAL TYPE OF ELECTRICITY GENERATION USING NUCLEAR FUSION
Fusion reactor; Controlled thermonuclear fusion; Fusion reactors; Fusion energy; Fusion Power; Nuclear fusion power; Thermonuclear energy; D-t cycle; Fusion generator; Thermonuclear reactor; Fusion Energy; Fusion energy calculation; Fusion Energy Calculation; D-T reaction; Nuclear fusion reactor; D-D fusion; Fusion research; Controlled fusion; Fusion electricity; History of fusion power
Fusion power is a proposed form of power generation that would generate electricity by using heat from nuclear fusion reactions. In a fusion process, two lighter atomic nuclei combine to form a heavier nucleus, while releasing energy.
Zéta         
VARIETY OF GRAPE
Orémus (grape); Oremus (grape); Orémus grape; Oremus grape; Zeta grape
Zéta is a Hungarian wine grape, a crossing of Furmint and Bouvier. It was introduced to the Tokaj-Hegyalja wine region of Hungary in 1951 and authorized for production in 1990.

Wikipedia

ZETA (fusion reactor)

ZETA, short for Zero Energy Thermonuclear Assembly, was a major experiment in the early history of fusion power research. Based on the pinch plasma confinement technique, and built at the Atomic Energy Research Establishment in the United Kingdom, ZETA was larger and more powerful than any fusion machine in the world at that time. Its goal was to produce large numbers of fusion reactions, although it was not large enough to produce net energy.

ZETA went into operation in August 1957 and by the end of the month it was giving off bursts of about a million neutrons per pulse. Measurements suggested the fuel was reaching between 1 and 5 million kelvins, a temperature that would produce nuclear fusion reactions, explaining the quantities of neutrons being seen. Early results were leaked to the press in September 1957, and the following January an extensive review was released. Front-page articles in newspapers around the world announced it as a breakthrough towards unlimited energy, a scientific advance for Britain greater than the recently launched Sputnik had been for the Soviet Union.

US and Soviet experiments had also given off similar neutron bursts at temperatures that were not high enough for fusion. This led Lyman Spitzer to express his scepticism of the results, but his comments were dismissed by UK observers as jingoism. Further experiments on ZETA showed that the original temperature measurements were misleading; the bulk temperature was too low for fusion reactions to create the number of neutrons being seen. The claim that ZETA had produced fusion had to be publicly withdrawn, an embarrassing event that cast a chill over the entire fusion establishment. The neutrons were later explained as being the product of instabilities in the fuel. These instabilities appeared inherent to any similar design, and work on the basic pinch concept as a road to fusion power ended by 1961.

In spite of ZETA's failure to achieve fusion, the device went on to have a long experimental lifetime and produced numerous important advances in the field. In one line of development, the use of lasers to more accurately measure the temperature was tested on ZETA, and was later used to confirm the results of the Soviet tokamak approach. In another, while examining ZETA test runs it was noticed that the plasma self-stabilised after the power was turned off. This has led to the modern reversed field pinch concept. More generally, studies of the instabilities in ZETA have led to several important theoretical advances that form the basis of modern plasma theory.