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Particle detector

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(Redirected from Radiation Detector) Device used to detect, track, and/or identify ionising particles This article is about detection of ionizing radiation. For detection of non-ionizing particles, see particle counter.

In experimental and applied particle physics, nuclear physics, and nuclear engineering, a particle detector, also known as a radiation detector, is a device used to detect, track, and/or identify ionizing particles, such as those produced by nuclear decay, cosmic radiation, or reactions in a particle accelerator. Detectors can measure the particle energy and other attributes such as momentum, spin, charge, particle type, in addition to merely registering the presence of the particle.

Examples and types

Summary of particle detector types

Many of the detectors invented and used so far are ionization detectors (of which gaseous ionization detectors and semiconductor detectors are most typical) and scintillation detectors; but other, completely different principles have also been applied, like Čerenkov light and transition radiation.

Cloud chambers visualize particles by creating a supersaturated layer of vapor. Particles passing through this region create cloud tracks similar to condensation trails of planes
Recording of a bubble chamber at CERN

Historical examples

Detectors for radiation protection

The following types of particle detector are widely used for radiation protection, and are commercially produced in large quantities for general use within the nuclear, medical, and environmental fields.

Commonly used detectors for particle and nuclear physics

Modern detectors

Main article: Hermetic detector

Modern detectors in particle physics combine several of the above elements in layers much like an onion.

Research particle detectors

Detectors designed for modern accelerators are huge, both in size and in cost. The term counter is often used instead of detector when the detector counts the particles but does not resolve its energy or ionization. Particle detectors can also usually track ionizing radiation (high energy photons or even visible light). If their main purpose is radiation measurement, they are called radiation detectors, but as photons are also (massless) particles, the term particle detector is still correct.

At colliders

Under construction

Without colliders

On spacecraft

Theoretical Models of Particle Detectors

Beyond their experimental implementations, theoretical models of particle detectors are also of great importance to theoretical physics. These models consider localized non-relativistic quantum systems coupled to a quantum field. They receive the name of particle detectors because when the non-relativistic quantum system is measured in an excited state, one can claim to have detected a particle. The first instance of particle detector models in the literature dates from the 80's, where a particle in a box was introduced by W. G. Unruh in order to probe a quantum field around a black hole. Shortly after, Bryce DeWitt proposed a simplification of the model, giving rise to the Unruh-DeWitt detector model.

Beyond their applications to theoretical physics, particle detector models are related to experimental fields such as quantum optics, where atoms can be used as detectors for the quantum electromagnetic field via the light-matter interaction. From a conceptual side, particle detectors also allow one to formally define the concept of particles without relying on asymptotic states, or representations of a quantum field theory. As M. Scully puts it, from an operational viewpoint one can state that "a particle is what a particle detector detects", which in essence defines a particle as the detection of excitations of a quantum field.

See also

References

  1. Martín-Martínez, Eduardo; Montero, Miguel; del Rey, Marco (2013-03-25). "Wavepacket detection with the Unruh-DeWitt model". Physical Review D. 87 (6): 064038. arXiv:1207.3248. Bibcode:2013PhRvD..87f4038M. doi:10.1103/PhysRevD.87.064038. S2CID 19334396.
  2. ^ Unruh, W. G. (1976-08-15). "Notes on black-hole evaporation". Physical Review D. 14 (4): 870–892. Bibcode:1976PhRvD..14..870U. doi:10.1103/PhysRevD.14.870.
  3. Unruh, William G.; Wald, Robert M. (1984-03-15). "What happens when an accelerating observer detects a Rindler particle". Physical Review D. 29 (6): 1047–1056. Bibcode:1984PhRvD..29.1047U. doi:10.1103/PhysRevD.29.1047.
  4. Irvine, J M (May 1980). "General Relativity – An Einstein Centenary Survey". Physics Bulletin. 31 (4): 140. doi:10.1088/0031-9112/31/4/029. ISSN 0031-9112.
  5. Scully, Marlan O. (2009), Muga, Gonzalo; Ruschhaupt, Andreas; del Campo, Adolfo (eds.), "The Time-Dependent Schrödinger Equation Revisited: Quantum Optical and Classical Maxwell Routes to Schrödinger's Wave Equation", Time in Quantum Mechanics - Vol. 2, Lecture Notes in Physics, vol. 789, Berlin, Heidelberg: Springer, pp. 15–24, doi:10.1007/978-3-642-03174-8_2, ISBN 978-3-642-03174-8, retrieved 2022-08-19

Further reading

Filmstrips
  • "Radiation detectors". H. M. Stone Productions, Schloat. Tarrytown, N.Y., Prentice-Hall Media, 1972.
General Information
  • Grupen, C. (June 28 – July 10, 1999). "Physics of Particle Detection". AIP Conference Proceedings, Instrumentation in Elementary Particle Physics, VIII. Vol. 536. Istanbul: Dordrecht, D. Reidel Publishing Co. pp. 3–34. arXiv:physics/9906063. doi:10.1063/1.1361756.
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