Dynode

A dynode is an electrode in a vacuum tube that serves as an electron multiplier through secondary emission. The first tube to incorporate a dynode was the dynatron, an ancestor of the magnetron, which used a single dynode.[1] Photomultiplier and video camera tubes generally include a series of dynodes, each at a more positive electrical potential than its predecessor. Secondary emission occurs at the surface of each dynode. Such an arrangement is able to amplify the tiny current emitted by the photocathode, typically by a factor of one million.

Two horizontal rows of arc-shaped dynodes in a photomultiplier tube.

Operation

The electrons emitted from the cathode are accelerated toward the first dynode, which is maintained 90 to 100 V positive with respect to the cathode. Each accelerated photoelectron that strikes the dynode surface produces several electrons. These electrons are then accelerated toward the second dynode, held 90 to 100 V more positive than the first dynode, and each electron that strikes the surface of the second dynode produces several more electrons, which are then accelerated toward the third dynode, and so on. By the time this process has been repeated at each of the dynodes, 105 to 107 electrons have been produced for each incident photon, dependent on the number of dynodes. For conventional dynode materials, such as BeO and MgO, a multiplication factor of 10 can normally be achieved by each dynode stage.[2]

Naming

The dynode takes its name from the dynatron. Albert Hull did not use the term dynode in his 1918 paper on the dynatron,[3] but used the term extensively in his 1922 paper.[1] In the latter paper, he defined a dynode as a "plate that emits impact electrons ... when it is part of a dynatron."

gollark: <@!221273650131763200> Are you using Go? Stop.
gollark: "I don't need to know anything, I'll just copy example code."
gollark: Virtual cloud blockchain, *but* serverless.
gollark: Go's easy to read, but not easy to understand, since it actively discourages abstraction.
gollark: If you want to return something representing nothing, that should be encoded in the type system.

See also

References

  1. Albert W. Hull, E. F. Hennelly and F. R. Elder, The Dynatron Detector -- a new heterodyne receiver for continuous and modulated waves, Proceedings of the Institute of Radio Engineers Vol. 10, No. 5 (Oct. 1922), pages 320-343
  2. Glenn F Knoll - Radiation Detection and Measurement 3rd ed, 1999, P270, ISBN 0-471-07338-5.
  3. Albert W. Hull, The Dynatron -- A vacuum tube possessing negative electric resistance, Proceedings of the Institute of Radio Engineers, Vol. 6, No. 1 (Feb. 1918); pages 5-35.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.