1.4 summarizes typical emission mechanisms in a scintillator, and the same classification is also possible for dosimeter materials. There are two kinds of luminescence in scintillators, namely intrinsic and extrinsic emissions. The intrinsic luminescence represents free‐exciton luminescence, self‐trapped exciton (STE) luminescence, Auger free luminescence, and self‐activation luminescence. The free exciton luminescence is observed in wide band‐gap semiconductor materials having direct transitions. In this type, common examples are ZnO [16] and GaN [17]. Scintillation due to free exciton is characterized by fast scintillation decay (1–10 ns) with a sharp emission peak in the spectrum. Recently, Ga2O3 is found to have fast and very intense scintillation upon γ‐ray irradiation [18]. Although Ga2O3 is still under discussion, whether it is a direct‐ or indirect‐transition type of semiconductor, it shows an attractive scintillation performance.
Figure 1.4 Typical emission mechanisms of scintillation.
STE is observed in wide‐band‐gap insulator materials, such as undoped alkali halides. Common properties of STE are summarized as follows: a broad emission peak in the emission spectrum, a large Stokes shift, a relatively high light yield in scintillation, a relatively fast decay time from several hundred ns to a few μs, and a large temperature dependence of the scintillation light yield. The most common materials are BaF2 [8], SrF2 [19], CaF2 [20], and their mixed compounds.
AFL is observed in some materials which have a larger band‐gap energy than the energy between the core and the valence bands [21]. AFL generally shows a very fast luminescence decay (~1 ns) with a short emission wavelength (VUV‐UV). The common materials are BaF2 [8], BaMgF4 [22], CsF [23], and Cs2ZnCl4 [24]. Up to now, AFL has been observed in halide materials, and a search for other compounds (oxides and nitrides) is an interesting research topic. Conventionally, it was considered that they have no temperature dependence concerning the scintillation light yield [25], but we recently revealed that AFL materials also show temperature dependence [26]. The disadvantage of AFL scintillators is a relatively low scintillation light yield. The details of AFL are described in Chapter 4.
Self‐activation type scintillators are composed only of the host, and this type can be classified as belonging to the intrinsic luminescence‐type materials. The difference from other intrinsic‐type materials is that the host material contains luminescent ions as a main element. Common scintillators of this type are BGO [7], CeF3 [27], and CeBr3 [28]. Scintillations from BGO are caused by ns2 transitions of Bi3+, and those of the latter two materials are due to the 5d‐4f transitions of Ce3+. Although the emission mechanism is not fully understood, recent results of Tl‐based crystals, such as TlMgCl3 and (Tl1−xAx)MgCl3 (where A = alkali metal), show very high scintillation light yields [29, 30], and their emission will relate to Tl+. In these materials, the emission properties are governed by the luminescent ions of the host, but this class of materials do not suffer from concentration quenching.
Then, the topic moves to materials with extrinsic luminescence. The first one is defect‐based luminescent materials, and the most common defect relating to luminescence is the F‐center, which is characterized by one electron captured at an anion vacancy. Materials containing F‐centers sometimes show scintillation. Common materials with an F‐center are simple oxide materials, such as MgO [31] and Al2O3 [32]. In addition to F‐centers, there are some other defect‐based luminescence centers, for example, F+‐ and F−‐centers. Although defects are not exactly activators, defect‐based luminescence is sometimes categorized as extrinsic emission.
Luminescence due to the ns2 ↔ nsnp transition is one of the common electron transitions involved in many scintillators, such as Tl‐doped NaI [6] and Tl‐doped CsI [33], which are very traditional scintillators. These traditional scintillators were discovered around 1940, and ns2 ions have become a familiar dopant in this field. The spectral feature of the ns2 ↔ nsnp transition is characterized by a broad emission band, and the emission wavelength is from near UV to VIS. Because the decay time is from several hundred ns to several μs, it is acceptable for pulse‐height‐based scintillation detectors. In this type of luminescence, in addition to Tl+ and Bi3+, In+ [34] and Sn2+ [35] have shown interesting scintillation properties in recent years.
In scintillators, transitional metal ions are sometimes activated to obtain a high luminescent efficiency for integration‐type detectors. The spectrum of 3d‐3d and 4d‐4d (d‐d) transitions has a broad luminescence feature, and the decay time is typically of the ms order. Among the transitional metal elements, Mn2+ [36] and Cr3+ [37] are sometimes selected for scintillation detectors due to a good spectral matching with Si‐PD.
Electron transitions of the 4f‐4f and 5f‐5f levels are called f‐f transitions, and some scintillators use the 4f‐4f transitions of rare‐earth elements because they typically exhibit a high emission intensity with acceptable decay time of several μs to few ms. The most common scintillator based on the 4f‐4f transition is Pr3+‐doped Gd2O2S (GOS) ceramic [38], which is often part of the equipment used in medical X‐ray CTs. The Pr‐doped GOS shows a very high scintillation intensity with a decay time in the medium range (several μs). The luminescence due to the 4f‐4f transitions of Pr3+ appears in yellow‐green, which is well‐matched with the spectral sensitivity of Si‐PD. For practical uses, Ce3+ is co‐doped to suppress the afterglow level. Recently, Eu3+‐doped (Lu,Gd)2O3 [39] has attracted much attention for X‐ray CT. The emission intensity is higher than other materials, and the emission wavelength is in red where Si‐PD has a high sensitivity. In addition to these materials, we have investigated doping with other rare‐earth ions in order to develop near‐infrared emitting scintillators. For this purpose, Nd3+, Ho3+, Er3+ Tm3+, and Yb3+ have been selected as the emission center.
Emission due to 5d‐4f transitions of trivalent and divalent rare‐earth ions are very important in recent scintillation detectors because they show intense and fast emissions by the spin‐ and parity‐allowed transitions. The most common emission center is Ce3+, and examples of commercial scintillators are Ce‐doped Lu2SiO5 (LSO) [40], (Lu,Y)2SiO5 (LYSO) [41], Gd3(Al,Ga)5O12 (GAGG) [42], Y3Al5O12 (YAG) [43], YAlO3 (YAP) [44], LaBr3 [45], and Cs2LiYCl6 [46]. Except for garnet materials, including GAGG, most scintillators have emission wavelengths of 300–400 nm with 30–60 ns decay times, and these properties are suitable for conventional PMT readouts. In addition to Ce3+, Pr3+ can also show luminescence due to the 5d‐4f transition in some host materials. The appearance of the 5d‐4f transition depends on the relative positions between the lowest 5d and 1S0 levels. Common Pr‐doped scintillators are Pr‐doped LuAG [47], Lu2Si2O7 (LPS) [48], and YAP [49], which show light yields of 10 000–20 000 ph/MeV with a 20 ns decay time. Compared with Ce‐doped scintillators, the emission of Pr‐doped materials appears in the shorter wavelength range, typically at 250–350 nm. Some other trivalent rare‐earth ions show 5d‐4f transitions only in hosts with a wide‐band gap energy, and the emission wavelength is in VUV. A common example is Nd‐doped LaF3, which has an emission wavelength at 175 nm with a few‐ns decay time [50] due to the 5d‐4f transition of Nd3+. Divalent Eu also shows a very high scintillation light yield with a typically ~1 μs decay time, which is acceptable for the photon counting type detectors. Typical examples are Eu2+‐doped SrI2 [51], CaF2 [52], LiI [53], and LiCaAlF6 [54]. Recently, luminescence due