Multi-energy X-ray imaging enabled by ΔE-E telescope scintillator

Tengyue He; Wenyi Shao; Jun Yin; Hongyun Wang; Yang Zhou; Jian Xin Wang; Peng Yuan; Luis Gutiérrez-Arzaluz; Wentao Wu; Renqian Zhou; Bingyao Shao; Xiaochuan Xia; Hongwei Liang; Osman M. Bakr; Omar F. Mohammed

doi:10.1016/j.matt.2024.05.029

Multi-energy X-ray imaging enabled by ΔE-E telescope scintillator

Tengyue He, Wenyi Shao, Jun Yin, Hongyun Wang, Yang Zhou, Jian Xin Wang, Peng Yuan, Luis Gutiérrez-Arzaluz, Wentao Wu, Renqian Zhou, Bingyao Shao, Xiaochuan Xia, Hongwei Liang, Osman M. Bakr, Omar F. Mohammed

Research output: Journal article publication › Journal article › Academic research › peer-review

15 Citations (Scopus)

Abstract

In this work, we developed a true-color multi-energy X-ray imaging technology centered around multiple scintillators with a six-layer ΔE-E telescope configuration to achieve energy discrimination and substance identification capability, which cannot be accessed by conventional X-ray imaging technology. Using three distinct scintillator layers, X-rays with different energy bins are sequentially converted into trichromatic channels. A careful selection of three interlayer filters not only filters X-ray energy but also ensures that radioluminescence spans the entire visible spectrum without overlap. This allows easy and direct discrimination of substances with varying computed tomography numbers based on their corresponding color. Interestingly, the high optical transparency of the ΔE-E telescope scintillator enables it to achieve an impressive spatial imaging resolution of 22 lp mm⁻¹, surpassing that of the typical scintillators found on the X-ray imaging market. In a conceptual experiment of baggage inspections, complex objects were successfully imaged and differentiated without missing any intricate details.

Original language	English
Pages (from-to)	2521-2535
Number of pages	15
Journal	Matter
Volume	7
Issue number	7
DOIs	https://doi.org/10.1016/j.matt.2024.05.029
Publication status	Published - 3 Jul 2024

Keywords

emerging scintillation materials
MAP 2: Benchmark
metal halides
multi-energy X-ray imaging
security checks

ASJC Scopus subject areas

General Materials Science

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10.1016/j.matt.2024.05.029

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@article{23c9e2cead574a5dbccad36fa8f81068,

title = "Multi-energy X-ray imaging enabled by ΔE-E telescope scintillator",

abstract = "In this work, we developed a true-color multi-energy X-ray imaging technology centered around multiple scintillators with a six-layer ΔE-E telescope configuration to achieve energy discrimination and substance identification capability, which cannot be accessed by conventional X-ray imaging technology. Using three distinct scintillator layers, X-rays with different energy bins are sequentially converted into trichromatic channels. A careful selection of three interlayer filters not only filters X-ray energy but also ensures that radioluminescence spans the entire visible spectrum without overlap. This allows easy and direct discrimination of substances with varying computed tomography numbers based on their corresponding color. Interestingly, the high optical transparency of the ΔE-E telescope scintillator enables it to achieve an impressive spatial imaging resolution of 22 lp mm−1, surpassing that of the typical scintillators found on the X-ray imaging market. In a conceptual experiment of baggage inspections, complex objects were successfully imaged and differentiated without missing any intricate details.",

keywords = "emerging scintillation materials, MAP 2: Benchmark, metal halides, multi-energy X-ray imaging, security checks",

author = "Tengyue He and Wenyi Shao and Jun Yin and Hongyun Wang and Yang Zhou and Wang, \{Jian Xin\} and Peng Yuan and Luis Guti{\'e}rrez-Arzaluz and Wentao Wu and Renqian Zhou and Bingyao Shao and Xiaochuan Xia and Hongwei Liang and Bakr, \{Osman M.\} and Mohammed, \{Omar F.\}",

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day = "3",

doi = "10.1016/j.matt.2024.05.029",

language = "English",

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T1 - Multi-energy X-ray imaging enabled by ΔE-E telescope scintillator

AU - He, Tengyue

AU - Shao, Wenyi

AU - Yin, Jun

AU - Wang, Hongyun

AU - Zhou, Yang

AU - Wang, Jian Xin

AU - Yuan, Peng

AU - Gutiérrez-Arzaluz, Luis

AU - Wu, Wentao

AU - Zhou, Renqian

AU - Shao, Bingyao

AU - Xia, Xiaochuan

AU - Liang, Hongwei

AU - Bakr, Osman M.

AU - Mohammed, Omar F.

PY - 2024/7/3

Y1 - 2024/7/3

N2 - In this work, we developed a true-color multi-energy X-ray imaging technology centered around multiple scintillators with a six-layer ΔE-E telescope configuration to achieve energy discrimination and substance identification capability, which cannot be accessed by conventional X-ray imaging technology. Using three distinct scintillator layers, X-rays with different energy bins are sequentially converted into trichromatic channels. A careful selection of three interlayer filters not only filters X-ray energy but also ensures that radioluminescence spans the entire visible spectrum without overlap. This allows easy and direct discrimination of substances with varying computed tomography numbers based on their corresponding color. Interestingly, the high optical transparency of the ΔE-E telescope scintillator enables it to achieve an impressive spatial imaging resolution of 22 lp mm−1, surpassing that of the typical scintillators found on the X-ray imaging market. In a conceptual experiment of baggage inspections, complex objects were successfully imaged and differentiated without missing any intricate details.

AB - In this work, we developed a true-color multi-energy X-ray imaging technology centered around multiple scintillators with a six-layer ΔE-E telescope configuration to achieve energy discrimination and substance identification capability, which cannot be accessed by conventional X-ray imaging technology. Using three distinct scintillator layers, X-rays with different energy bins are sequentially converted into trichromatic channels. A careful selection of three interlayer filters not only filters X-ray energy but also ensures that radioluminescence spans the entire visible spectrum without overlap. This allows easy and direct discrimination of substances with varying computed tomography numbers based on their corresponding color. Interestingly, the high optical transparency of the ΔE-E telescope scintillator enables it to achieve an impressive spatial imaging resolution of 22 lp mm−1, surpassing that of the typical scintillators found on the X-ray imaging market. In a conceptual experiment of baggage inspections, complex objects were successfully imaged and differentiated without missing any intricate details.

KW - emerging scintillation materials

KW - MAP 2: Benchmark

KW - metal halides

KW - multi-energy X-ray imaging

KW - security checks

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U2 - 10.1016/j.matt.2024.05.029

DO - 10.1016/j.matt.2024.05.029

M3 - Journal article

AN - SCOPUS:85197351990

SN - 2590-2393

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SP - 2521

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JO - Matter

JF - Matter

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ER -

Multi-energy X-ray imaging enabled by ΔE-E telescope scintillator

Abstract

Keywords

ASJC Scopus subject areas

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