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Название: Phosphors for Radiation Detectors

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Отраслевые издания

Серия:

isbn: 9781119583387

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СКАЧАТЬ in the nondestructive study of humans (e.g., dental application) or objects. The storage phosphors used for such applications are mainly classified into three types by emission mechanisms, namely optically stimulated luminescence (OSL) [3], thermally stimulated luminescence (TSL) [4], and radiophotoluminescence (RPL) [5] materials. Hereafter, the two kinds of luminescent materials (scintillators and storage phosphors) are focused. Although the emission mechanisms of storage phosphors are different from those of scintillators, the readout system of dosimeters is similar to that of scintillation detectors. Their emissions are typically read out by PMT under photo‐ or thermal‐stimulation (excitation). Details are described in later chapters.

      Typically, luminescent materials for ionizing radiation measurements consist of the host material and the dopant for luminescence centers. For example, Tl‐doped NaI is the most common scintillator [6], NaI is the host which is generally an insulator or semiconductor, and Tl is the dopant with a typically very low concentration. In these kind of materials, the host has a role to absorb the target ionizing radiation efficiently, and the dopant has a role to emit photons whose number is proportional to the incident radiation energy or amount. The combination of the host and the dopant is one of the more recent trends of R&D in this field. The same trend is true, not only for scintillators, but also for storage phosphors for dosimeters.

      α‐rays (He nucleus) are common charged particle and have a high interaction probability with many materials, and a thin sheet of paper is enough to absorb these rays. In practical applications, a thin plate with a thickness of a few to several tens of μm scintillators are used as α‐ray detectors, and the most common scintillator for this use is Ag‐doped ZnS [10]. The weak point of the conventional Ag‐doped ZnS powder is poor energy resolution without a clear full‐energy deposited peak in pulse height spectrum. Generally, experimental environments of α‐ray detection contain so much X‐ and γ‐ray background, that detectors with Ag‐doped ZnS have difficulty in discriminating the level of signal and noise. In order to solve this problem, some new approaches were recently proposed [11, 12].

      High energy photons, such as X‐ and γ‐rays, are the most useful ionizing radiation in practical applications, and one of their characteristics is a high penetrative power. In order to absorb X‐ and γ‐rays efficiently, we must prepare enough large and heavy materials such as Pb and Fe block. Generally, we use the density (ρ) and the effective atomic number (Zeff) to evaluate the detection efficiency of X‐ and γ‐ray detectors. Here, Zeff is defined as

      (1.1)

      where wi is the weight ratio of the i‐th element of the detector material, and Zi is the atomic number (Z) of the i‐th element. The power in the formula depends on its application. In the case of the scintillation detector, generally we evaluate the detection efficiency by Zeff4, since the interaction probability of the photoelectric absorption event is proportional to ~ρ Zeff4, while we use the power of ~3 (sometimes 2.94) for individual dosimeter applications. It must be noted that Zeff in scintillator and dosimeter fields can vary. In scintillators for X‐ and γ‐ray detectors, generally, high ρ and Zeff are preferable. On the other hand, light materials with Zeff close to 7.1 are preferable for individual dosimeter applications, because Zeff of the human body is around 7.

      In the case of neutrons, the tendency is largely that of differently charged particles and photons. Although neutrons have a high penetrative power when applied to paper, thin metal plate, and heavy block, they have a high interaction probability with H, so H2O is an effective material to interact with neutrons. In neutrons, some specific elements, such as H, 3He, 6Li, and 10B, have a high interaction probability, and in order to detect neutrons efficiently, and detector materials should contain these elements. Especially, a 3He‐filled gas proportional counter is the standard detector for thermal neutron detectors.

      1.3.1 Energy Conversion Mechanism