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Detectors The energy loss of particles in matter can be used detect and identify those particles. There are different types of “detectors”: - Gas-filled.

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Presentation on theme: "Detectors The energy loss of particles in matter can be used detect and identify those particles. There are different types of “detectors”: - Gas-filled."— Presentation transcript:

1 Detectors The energy loss of particles in matter can be used detect and identify those particles. There are different types of “detectors”: - Gas-filled counters - Semi-conductor counters (Germanium, Silicon, NaI,….) - Scintillation counters (Organic & Inorganic: Solid, liquid) Figures in this presentation are from “Introductory nuclear physics” by Keneth Krane.

2 Gas-filled counters An electric field is used to separate and count the ions (or electrons) formed by the passage of radiation through the detector

3 Proportional counter – Geiger Mueller Counter Position sensitive PPAC In the proportional counter the amplitude of the signal formed is proportional to the energy deposited.

4 Scintillation detectors The disadvantage of gas filled counters is their low efficiency. This can be overcome by going to detectors with higher densities (solids, liquids). However to be a workable solid detector we need: 1) material must support high E (to collect the e - and ions) 2) little or no current must flow in the absence of radiation 3) e - must be easily removed by radiation and must be able to travel (1) & (2): Insulator(3): conductor SEMICONDUCTORS Bulk material in large size was long unavailable.  Scintillation counters (1950) e - formed by the ionization  e - that form the pulse

5 Principle of scintillation detectors 1)Incident radiation interact with material 2)Atoms are raised to excited states 3)Excited states emit visible light: fluorescence 4)Light strikes photosensitive a surface 5)Release of a photoelectron multiplication There are organic (liquid or solid) and inorganic scintillators (NaI)

6 Semiconductor detectors Ge and Si are solid semiconductor materials (they form solid crystals with valence- 4 atoms). They can be “doped” to control electrical conductions With valence 3 or 5 atoms introduced into the lattice Donor states: n-type semiconductor Acceptor states: p-type semiconductor n- and p- type brought into contact Junction under reverse bias

7 Energy measurement When the detector has a large size What is the shape of the spectrum for a large detector?

8 Coincidence measurement

9 Magnetic spectrographs & counter telescopes

10

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