High-throughput production of LuAG-based highly luminescent thick film scintillators for radiation detection and imaging

Matsumoto, Shogen; Ito, Akihiko

doi:10.1038/s41598-022-23839-w

Cited by 11 publications

(8 citation statements)

References 29 publications

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“…The light yield of the developed transparent Lu‐α‐SiAlON ceramics was calculated as 1300 photons 5.5 MeV −1 . This value is lower than those reported for transparent or translucent α‐ray‐scintillator such as ZnO ceramics 39 (prepared by spark plasma sintering, 44200 photons 5.5 MeV −1 ), ZnO:Cd film 8 (by liquid phase epitaxy method, 18000 photons 5.5 MeV −1 ), Lu 3 Al 5 O 12 (LuAG) film 30 (by CVD, 31000 photons 5.5 MeV −1 ), and LuAG single crystal 30 (21000 photons 5.5 MeV −1 ). A phenomenological model is usually used to explain the observed light yield, 1,6,40 which is formulated as:

\begin{equation}LY\ = \frac{E}{{{{E}_{\mathrm{g}}}\beta }}\ \times S \times Q\end{equation}

where,

LY

is the scintillation light yield,

E

is the deposited energy of ionizing radiation,

\beta

is the constant parameter,

{{E}_{\mathrm{g}}}

is the band‐gap energy,

S

is the energy migration efficiency from the host to emission centers, and

Q

is the quantum efficiency which is equal to the photoluminescence quantum efficiency.…”

Section: Resultsmentioning

confidence: 65%

“…The light yield of the developed transparent Lu-α-SiAlON ceramics was calculated as 1300 photons 5.5 MeV −1 . This value is lower than those reported for transparent or translucent α-ray-scintillator such as ZnO ceramics 39 (prepared by spark plasma sintering, 44200 photons 5.5 MeV −1 ), ZnO:Cd film 8 (by liquid phase epitaxy method, 18000 photons 5.5 MeV −1 ), Lu 3 Al 5 O 12 (LuAG) film 30 (by CVD, 31000 photons 5.5 MeV −1 ), and LuAG single crystal 30 (21000 photons 5.5 MeV −1 ). A phenomenological model is usually used to explain the observed light yield, 1,6,40 which is formulated as:…”

Section: Cut-off Wavelength Of the Short-pass Filter None 550 Nm 525 ...mentioning

confidence: 63%

“…The measurement procedures of the scintillation properties were previously reported 30 . 241 Am source was used as a 5.5‐MeV α‐ray source.…”

Section: Methodsmentioning

confidence: 99%

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Scintillation properties of transparent Lu‐α‐SiAlON:Ce³⁺ ceramics

Aminaka,

Tatami,

Iijima

et al. 2024

Int J Applied Ceramic Tech

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The high durability under harsh environment including high temperature, high humidity, and high radiation is required for scintillators used for decommissioning of nuclear facilities and radiation monitoring in nuclear fusion reactors. α‐SiAlON ceramics are highly potential for such scintillators because of their thermal and mechanical durability and luminescence corresponding to doped rare‐earth ion. In this study, scintillation properties of transparent Lu‐α‐SiAlON:Ce3+ ceramics were investigated for the first time. Lu‐α‐SiAlON:Ce3+ showed the scintillation responses to α‐rays and X‐rays. The α‐rays‐induced scintillation decay curve consists of two components whose decay time are 48 and 652 ns. The faster decay component most presumably results from 4f‐5d transition of Ce3+, whereas the origin of the slower one is unclear but may be defects in α‐SiAlON. The light yield of the Lu‐α‐SiAlON:Ce3+ ceramics was 1300 photons 5.5 MeV−1.

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\begin{equation}LY\ = \frac{E}{{{{E}_{\mathrm{g}}}\beta }}\ \times S \times Q\end{equation}

where,

LY

is the scintillation light yield,

E

is the deposited energy of ionizing radiation,

\beta

is the constant parameter,

{{E}_{\mathrm{g}}}

is the band‐gap energy,

S

is the energy migration efficiency from the host to emission centers, and

Q

is the quantum efficiency which is equal to the photoluminescence quantum efficiency.…”

Section: Resultsmentioning

confidence: 65%

Section: Cut-off Wavelength Of the Short-pass Filter None 550 Nm 525 ...mentioning

confidence: 63%

See 1 more Smart Citation

Scintillation properties of transparent Lu‐α‐SiAlON:Ce³⁺ ceramics

Aminaka,

Tatami,

Iijima

et al. 2024

Int J Applied Ceramic Tech

Self Cite

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“…34) X-ray imaging test using CVD-Ce 3+ :LuAG thick film scintillator as a scintillation screen will be reported elsewhere. 35)…”

Section: Resultsmentioning

confidence: 99%

Chemically vapor deposited oxide-based thick film scintillators

Ito

Matsumoto

2022

Jpn. J. Appl. Phys.

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Radiation detection and imaging are used for nondestructive testing in the field of production technology, diagnosis and treatment in the medical field, and security activities at airports and nuclear facilities. To improve sensitivity and resolution in radiation detection and imaging, light scattering and self-absorption in scintillator media should be suppressed. Thick film scintillators with a thickness of several tens of micrometers have recently attracted attention; however, mechanical thinning of single crystal bulk or sintered polycrystalline transparent ceramics is costly. In this review, we discuss advantages of thick film scintillators for α-particle detection and X-ray imaging with numerical simulations and introduce a novel process that enables direct and rapid synthesis of thick film scintillators of tungsten- and lutetium-based practical oxide materials using a chemical vapor deposition method.

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“…Moreover, although LaBr 3 :Ce is hygroscopic, it receives great scientific attention because of its rapid response to incident photons (~20 ns [22]). Likewise, CZT is a material that is under investigation as an adequate X-ray CT system detector since it presents decreased electronic noise (a magnitude of nA [23]) and an increased signal-to-noise ratio [11,[24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Novel Detector Configurations in Cone-Beam CT Systems: A Simulation Study

Karali,

Michail,

Fountos

et al. 2024

Crystals

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Cone-beam computed tomography (CBCT) has emerged in recent years as an adequate alternative to mammography and tomosynthesis due to the several advantages over traditional mammography, including its ability to provide 3D images, its reduced radiation dose, and its ability to image dense breasts more effectively and conduct more effective breast compressions, etc. Furthermore, CBCT is capable of providing images with high sensitivity and specificity, allowing a more accurate evaluation, even of dense breasts, where mammography and tomosynthesis may lead to a false diagnosis. Clinical and experimental CBCT systems rely on cesium iodine (CsI:Tl) scintillators for X-ray energy conversion. This study comprises an investigation among different novel CBCT detector technologies, consisting either of scintillators (BGO, LSO:Ce, LYSO:Ce, LuAG:Ce, CaF2:Eu, LaBr3:Ce) or semiconductors (Silicon, CZT) in order to define the optimum detector design for a future experimental setup, dedicated to breast imaging. For this purpose, a micro-CBCT system was adapted, using GATE v9.2.1, consisting of the aforementioned various detection schemes. Two phantom configurations were selected: (a) an aluminum capillary positioned at the center of the field of view in order to calculate the system’s spatial resolution and (b) a breast phantom consisting of spheres of different materials, such that their characteristics are close to the breast composition. Breast phantom contrast-to-noise ratios (CNRs) were extracted from the phantom’s tomographic images. The images were reconstructed with filtered back projection (FBP) and ordered subsets expectation-maximization (OSEM) algorithms. The semiconductors acted satisfactorily in low-density matter, while LYSO:Ce, LaBr3:Ce, and LuAG:Ce presented adequate CNRs for all the different spheres’ densities. The energy converters that are presented in this study were evaluated for their performance against the standard CsI:Tl crystal.

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High-throughput production of LuAG-based highly luminescent thick film scintillators for radiation detection and imaging

Cited by 11 publications

References 29 publications

Scintillation properties of transparent Lu‐α‐SiAlON:Ce³⁺ ceramics

Scintillation properties of transparent Lu‐α‐SiAlON:Ce³⁺ ceramics

Chemically vapor deposited oxide-based thick film scintillators

Novel Detector Configurations in Cone-Beam CT Systems: A Simulation Study

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High-throughput production of LuAG-based highly luminescent thick film scintillators for radiation detection and imaging

Cited by 11 publications

References 29 publications

Scintillation properties of transparent Lu‐α‐SiAlON:Ce3+ ceramics

Scintillation properties of transparent Lu‐α‐SiAlON:Ce3+ ceramics

Chemically vapor deposited oxide-based thick film scintillators

Novel Detector Configurations in Cone-Beam CT Systems: A Simulation Study

Contact Info

Product

Resources

About

Scintillation properties of transparent Lu‐α‐SiAlON:Ce³⁺ ceramics

Scintillation properties of transparent Lu‐α‐SiAlON:Ce³⁺ ceramics