Physics:Digicon

Short description: Photoelectric effect-derived light detector

A digicon detector is a spatially resolved light detector using the photoelectric effect directly. It uses magnetic and electric fields operating in a vacuum to focus the electrons released from a photocathode by incoming light onto a collection of silicon diodes. It is a photon-counting instrument, so most useful for weak sources.^[1] One of digicon's advantages is its very large dynamic range and it results from the short response and decay times of silicon diodes.^[2]

Development

In 1971, E.A. Beaver and Carl McIlwain successfully demonstrated a way in which silicon diodes can be used in digital tube by placing a silicon diode array that contained 38 elements in the same chamber as a photocathode.^[2] The design and manufacture of the Digicon tube is attributed to John Choisser of the Electronic Vision Corporation.^[3]

Digicon detectors were used on the original instruments for the Hubble Space Telescope, but are very rarely used in new designs, where CMOS active-pixel detectors can achieve the same performance without the need for large electric fields or complicated vacuum assemblies.^{[citation needed]} For instance, there were two pulse-counting Digicon detectors in the Goddard High Resolution Spectrograph installed on the Hubble Space Telescope from 1990–1997, used to record ultraviolet spectra.^[4] Digicon is also used in digital imaging such as the case of a scanning gage using Digicon imaging tube, which generates a two-dimensional view with high spatial resolution when an object is scanned past the Digicon.^[5]

References

↑ "The Digicon Detectors". http://www.stsci.edu/instrument-news/handbooks/ghrs/GHRS_35.html.
↑ ^2.0 ^2.1 Meaburn, J. (2012). Detection and Spectrometry of Faint Light. Dordrecht: Springer Science+Business Media, B.V.. pp. 36. ISBN 9789027711984.
↑ Morgan, B.L.; Airey, R.W.; McMullan, D. (1976). Advances in Electronics and Electron Physics. London: Academic Press. pp. 761. ISBN 0120145545.
↑ Böhme, S.; Esser, U.; Hefele, H.; Heinrich, I.; Hofmann, W.; Krahn, D.; Matas, V. R.; Schmadel, L. D. et al. (2013). Astronomy and Astrophysics Abstracts: Volume 42 Literature 1986. Springer Science & Business Media. p. 186. ISBN 978-3-662-12382-9. https://books.google.com/books?id=67joCAAAQBAJ&pg=PA186.
↑ Berger, Harold (1976). Practical Applications of Neutron Radiography and Gaging. Philadelphia, PA: ASTM International. pp. 72. ISBN 0803105355.

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[1] "The Digicon Detectors". http://www.stsci.edu/instrument-news/handbooks/ghrs/GHRS_35.html.

[:0-2] 2.0 ^2.1 Meaburn, J. (2012). Detection and Spectrometry of Faint Light. Dordrecht: Springer Science+Business Media, B.V.. pp. 36. ISBN 9789027711984.

[3] Morgan, B.L.; Airey, R.W.; McMullan, D. (1976). Advances in Electronics and Electron Physics. London: Academic Press. pp. 761. ISBN 0120145545.

[4] Böhme, S.; Esser, U.; Hefele, H.; Heinrich, I.; Hofmann, W.; Krahn, D.; Matas, V. R.; Schmadel, L. D. et al. (2013). Astronomy and Astrophysics Abstracts: Volume 42 Literature 1986. Springer Science & Business Media. p. 186. ISBN 978-3-662-12382-9. https://books.google.com/books?id=67joCAAAQBAJ&pg=PA186.

[5] Berger, Harold (1976). Practical Applications of Neutron Radiography and Gaging. Philadelphia, PA: ASTM International. pp. 72. ISBN 0803105355.

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