The probability of inducing one of the reactions useful for slow-neutron detection is expressed as the magnitude of its neutron cross section (see table). These values are relatively large for slow neutrons but decrease by several orders of magnitude for fast neutrons. Therefore, slow-neutron detectors such as the boron trifluoride tube become inefficient for the direct detection of fast neutrons. One method used to increase this efficiency is to surround the detector with a material that effectively moderates or slows down the fast neutrons. For example, a polyethylene layer with a thickness of 20 to 30 centimetres will cause some incident fast neutrons to scatter many times from the hydrogen nuclei that are present, giving up energy in the process. A fraction of these moderated neutrons may then diffuse to the detector as slow neutrons with a high interaction probability. Since the moderation process obscures any information on the original energy of the fast neutron, these devices are useful only in simple neutron-counting systems.

The preferred conversion reaction for the direct detection of fast neutrons tends to be the elastic-scattering interaction. The resulting recoil nuclei can absorb a significant fraction of the original neutron energy in a single scattering and then deposit that energy in a manner similar to that of any other charged particle. The scattered neutron, now with a lower energy, may either escape from the detector or possibly interact again elsewhere in its volume. The most common scattering target is hydrogen, and a fast neutron can transfer up to all its energy in a single collision with a hydrogen nucleus. The amount of energy transferred varies with the scattering angle, which in hydrogen covers a continuum from zero (corresponding to grazing-angle scattering) up to the full neutron energy (corresponding to a head-on collision). Thus, when monoenergetic fast neutrons strike a material containing hydrogen, a spectrum of recoil protons is produced that ranges in energy between these limits. Some information about the original energy of the neutrons can be deduced by recording the pulse height-spectrum from a hydrogen-containing detector. This process generally involves applying a computer-based deconvolution code to the measured spectrum and is one of the few methods generally available to experimentally measure fast-neutron energy spectra.

The result of a fast-neutron scattering from hydrogen is a recoiling energetic hydrogen nucleus, or recoil proton. One type of detector based on these recoil protons is a proportional counter containing a hydrogenous gas. Pure hydrogen can be used, but a more common choice is a heavier hydrocarbon such as methane in which the range of the resulting recoil protons typically is short enough to be fully stopped in the gas. Recoil protons also can be generated and detected in organic liquid or plastic scintillators. In instances such as these, many more hydrogen nuclei are present per unit volume than in a gas, so that the detection efficiency for fast neutrons can be many times larger than in a proportional counter.

Glenn F. Knoll

solid-state detector

radiation detector
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Also known as: semiconductor detector, semiconductor radiation detector
Also called:
Semiconductor Radiation Detector

solid-state detector, radiation detector in which a semiconductor material such as a silicon or germanium crystal constitutes the detecting medium. One such device consists of a p-n junction across which a pulse of current develops when a particle of ionizing radiation traverses it. In a different device, the absorption of ionizing radiation generates pairs of charge carriers (electrons and electron-deficient sites called holes) in a block of semiconducting material; the migration of these carriers under the influence of a voltage maintained between the opposite faces of the block constitutes a pulse of current. The pulses created in this way are amplified, recorded, and analyzed to determine the energy, number, or identity of the incident-charged particles. The sensitivity of these detectors is increased by operating them at low temperatures—commonly that of liquid nitrogen, −164 °C (−263 °F)—which suppresses the random formation of charge carriers by thermal vibration.

This article was most recently revised and updated by William L. Hosch.