Ultrafast hybrid nanocomposite scintillators: A review

Shevelev, Vladimir; Ищенко, А. В.; Ванецев, А. С.; Nagirnyi, V.; Omelkov, Sergey

doi:10.1016/j.jlumin.2021.118534

Cited by 26 publications

(9 citation statements)

References 148 publications

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“…For example, Sokollik et al (2009), with an unusually large magnification of M ¼ 70 (which would not be suitable for most experiments) and a time gating of δt G ¼ 4.5 ns, obtained a temporal resolution of δt ∼ 65 ps. However, even with δt G ∼ 1 ns [possible in principle if using state-of-the art scintillators and/or gating (Hu et al, 2018;Zhang et al, 2018;Shevelev et al, 2022)] and a relatively large but more typical magnification M (for instance, M ∼ 20), it is challenging to reach temporal resolutions comparable to the picosecond capabilities of RCF and TNSA sources; see Sec. II.C.4.…”

Section: B Advanced Detectorsmentioning

confidence: 99%

Proton imaging of high-energy-density laboratory plasmas

Schaeffer,

Bott,

Borghesi

et al. 2023

Rev. Mod. Phys.

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Proton imaging has become a key diagnostic for measuring electromagnetic fields in high-energydensity (HED) laboratory plasmas. Compared to other techniques for diagnosing fields, proton imaging is a measurement that can simultaneously offer high spatial and temporal resolution and the ability to distinguish between electric and magnetic fields without the protons perturbing the plasma of interest. Consequently, proton imaging has been used in a wide range of HED experiments, from

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Section: B Advanced Detectorsmentioning

confidence: 99%

Proton imaging of high-energy-density laboratory plasmas

Schaeffer,

Bott,

Borghesi

et al. 2023

Rev. Mod. Phys.

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“…A body of associated work can be found in recent reviews, those mentioned in the Introduction or also other studies. [ 293,294 ] In the following we focus on some of the most recent works.…”

Section: Halide Perovskite Ncsmentioning

confidence: 99%

Advanced Halide Scintillators: From the Bulk to Nano

Vaněček

Děcká

Mihóková

et al. 2022

Advanced Photonics Research

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Halide scintillators have been playing 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 allows 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 motivate intense research of a large variety of halide‐based scintillators. Moreover, materials based on lead halide perovskites find applications 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 nanocrystals. The purpose of this review is to summarize the R&D in the field of halide scintillators during the last decade and highlight perspectives for future development.

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“…Therefore, ultrafast single crystalline scintillators are highly demanded. [7][8][9] Currently, the scintillators applied in clinical PET scanners are required to have excellent atmospheric chemical stability, high light yield, large size, high crystallinity, high radiation stopping power and high radiation hardness. 6,[10][11][12] Since the invention of PET, the most widely applied scintillation crystals include LaBr 3 , 13 Gd 2 SiO 5 (GSO), 14 Lu 2(1Àx) Y 2x SiO 5 (LYSO), 15 Lu 2 SiO 5 (LSO), 16 and Bi 4 Ge 3 O 12 (BGO).…”

Section: Introductionmentioning

confidence: 99%

Ultrafast scintillation at room temperature achieved in CsPbCl₃-based single crystals through Br over-doping

Zhang,

Shen,

Cheng

et al. 2024

J. Mater. Chem. C

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Ultrafast hybrid nanocomposite scintillators: A review

Cited by 26 publications

References 148 publications

Proton imaging of high-energy-density laboratory plasmas

Proton imaging of high-energy-density laboratory plasmas

Advanced Halide Scintillators: From the Bulk to Nano

Ultrafast scintillation at room temperature achieved in CsPbCl₃-based single crystals through Br over-doping

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Ultrafast hybrid nanocomposite scintillators: A review

Cited by 26 publications

References 148 publications

Proton imaging of high-energy-density laboratory plasmas

Proton imaging of high-energy-density laboratory plasmas

Advanced Halide Scintillators: From the Bulk to Nano

Ultrafast scintillation at room temperature achieved in CsPbCl3-based single crystals through Br over-doping

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Product

Resources

About

Ultrafast scintillation at room temperature achieved in CsPbCl₃-based single crystals through Br over-doping