Difference between revisions of "Forest Detectors"
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| + | The common mechanism behind most detectors involves the "jiggling" of atomic electrons. | ||
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| + | In the case of the He-3 tube above the electrons were "jiggled" hard enough that they were no longer bound to the atom. | ||
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[[Forest_He-3_Tubes]] | [[Forest_He-3_Tubes]] | ||
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| + | In the case of scintillator, the "jiggling" excites the electrons in the scintillator atoms such that the atoms give off light when they de-excite. | ||
[[Forest_Scintilaltors]] | [[Forest_Scintilaltors]] | ||
[[Forest_IonizationChambers]] | [[Forest_IonizationChambers]] | ||
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| + | In semi-conductor (solid state) detectors, the electrons move into the conduction band of the material when they are "jiggled" by incident radiation. | ||
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[[Forest_SolidState_Detectors]] | [[Forest_SolidState_Detectors]] | ||
Revision as of 17:18, 8 June 2008
The common mechanism behind most detectors involves the "jiggling" of atomic electrons.
In the case of the He-3 tube above the electrons were "jiggled" hard enough that they were no longer bound to the atom.
In the case of scintillator, the "jiggling" excites the electrons in the scintillator atoms such that the atoms give off light when they de-excite.
In semi-conductor (solid state) detectors, the electrons move into the conduction band of the material when they are "jiggled" by incident radiation.