Presentation is loading. Please wait.

Presentation is loading. Please wait.

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

Published byLorraine Byrd Modified over 9 years ago

Similar presentations

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

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

Similar presentations

Dispersive property of a G-M tube HV - + In the proportional region a G-M tube has dispersive properties 0 250 500 750 1 10 2 10 4 10 6 10 810 tube voltage.

Dispersive property of a G-M tube HV - + In the proportional region a G-M tube has dispersive properties tube voltage.
Radiation Detectors / Particle Detectors

Radiation Detectors / Particle Detectors
Scintillators. When radiation interacts with certain types of materials, it produces flashes of light (scintillation) Materials that respond this way.

Scintillators. When radiation interacts with certain types of materials, it produces flashes of light (scintillation) Materials that respond this way.
Course: ETE 107 Electronics 1 Course Instructor: Rashedul Islam

Course: ETE 107 Electronics 1 Course Instructor: Rashedul Islam
Energy Band View of Semiconductors Conductors, semiconductors, insulators: Why is it that when individual atoms get close together to form a solid – such.

Energy Band View of Semiconductors Conductors, semiconductors, insulators: Why is it that when individual atoms get close together to form a solid – such.
Doped Semiconductors Group IVA semiconductors can be “doped” by adding small amounts of impurities with more or fewer than 4 valence electrons. e.g. add.

Doped Semiconductors Group IVA semiconductors can be “doped” by adding small amounts of impurities with more or fewer than 4 valence electrons. e.g. add.
P461 - Semiconductors1 Semiconductors Filled valence band but small gap (~1 eV) to an empty (at T=0) conduction band look at density of states D and distribution.

P461 - Semiconductors1 Semiconductors Filled valence band but small gap (~1 eV) to an empty (at T=0) conduction band look at density of states D and distribution.
Lesson 17 Detectors. Introduction When radiation interacts with matter, result is the production of energetic electrons. (Neutrons lead to secondary processes.

Lesson 17 Detectors. Introduction When radiation interacts with matter, result is the production of energetic electrons. (Neutrons lead to secondary processes.
Scintillators.

Scintillators.
High Energy Detection. High Energy Spectrum High energy EM radiation:  (nm)E (eV) Soft x-rays 10100 X-rays 0.110 K Soft gamma rays 0.0011 M Hard gamma.

High Energy Detection. High Energy Spectrum High energy EM radiation:  (nm)E (eV) Soft x-rays X-rays K Soft gamma rays M Hard gamma.
P and n type semiconductors. Semiconductors Semiconductors are also referred to as metalloids. Metalloids occur at the division between metals and non-metals.

P and n type semiconductors. Semiconductors Semiconductors are also referred to as metalloids. Metalloids occur at the division between metals and non-metals.
Radiation Safety level 5 Frits Pleiter 02/07/2015radiation safety - level 51.

Radiation Safety level 5 Frits Pleiter 02/07/2015radiation safety - level 51.
Main detector types Scintillation Detector Spectrum.

Main detector types Scintillation Detector Spectrum.
Putting Electrons to Work Doping and Semiconductor Devices.

Putting Electrons to Work Doping and Semiconductor Devices.
Unit-II Physics of Semiconductor Devices. Formation of PN Junction and working of PN junction. Energy Diagram of PN Diode, I-V Characteristics of PN Junction,

Unit-II Physics of Semiconductor Devices. Formation of PN Junction and working of PN junction. Energy Diagram of PN Diode, I-V Characteristics of PN Junction,
Radiation Sensors Zachariadou K. | TEI of Piraeus.

Radiation Sensors Zachariadou K. | TEI of Piraeus.
Lecture 3. Intrinsic Semiconductor When a bond breaks, an electron and a hole are produced: n 0 = p 0 (electron & hole concentration) Also:n 0 p 0 = n.

Lecture 3. Intrinsic Semiconductor When a bond breaks, an electron and a hole are produced: n 0 = p 0 (electron & hole concentration) Also:n 0 p 0 = n.
An Introduction to Semiconductor Materials

An Introduction to Semiconductor Materials
Radiation Detection and Measurement II IRAD 2731.

Radiation Detection and Measurement II IRAD 2731.
SEMICONDUCTORS.

SEMICONDUCTORS.

Similar presentations

Ads by Google