Vojtech Vanecek, Katerina Decka, Eva Mihokova, Vaclav Cuba, Robert Kral, Martin Nikl
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Advanced Halide Scintillators: From the Bulk to Nano
Halide scintillators play a crucial role in the detection of ionizing
radiation since the discovery of scintillation in NaI:Tl in 1948. The discovery
of NaI:Tl motivated the research and development (R&D) of halide scintillators
resulting in the development of CsI:Tl, CsI:Na, CaF2:Eu, etc. Later, the R&D
shifted toward oxide materials due to their high mechanical and chemical
stability, good scintillation properties, and relative ease of bulk single
crystal growth. However, the development in crystal growth technology allowed
for the growth of high-quality single crystals of hygroscopic and mechanically
fragile materials including SrI2 and LaBr3. Scintillators based on these
materials exhibit excellent performance and push the limits of inorganic
scintillators. These results motivated intense research of a large variety of
halide-based scintillators. Moreover, materials based on lead halide
perovskites found application in the fields of photovoltaics, solid-state
lighting, and lasers. The first studies show also the significant potential of
lead halide perovskites as ultrafast scintillators in the form of NCs. The
purpose of this review is to summarize the R&D in the field of halide
scintillators during the last decade and to highlight perspectives for future
development.
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