X-Ray Imaging Performance of Gd3(Al,Ga)5O12∶Ce Scintillation Screens under Synchrotron Radiation

doi:10.16553/j.cnki.issn1000-985x.2025.0176

Abstract

Abstract: Gd₃（Al，Ga）₅O₁₂∶Ce （GAGG） scintillators， characterized by high density （6.63 g/cm³）， high light yield （>58 000 ph/MeV）， fast decay time （～90 ns）， and stable physicochemical properties， are promising candidates for high spatial resolution X-ray imaging scintillation screens. Determining the spatial resolution limit of the GAGG scintillation screen and approaching this limit cost-effectively is a significant yet challenging task. In this work， GAGG single crystals without co-doping and with Mg or Yb co-doping were grown by the Czochralski method. A series of GAGG scintillation screens were prepared by cutting and polishing， and their optical and scintillation properties were systematically characterized. The theoretical spatial resolution was calculated via Geant4 simulations， and imaging experiments were conducted at the BL13HB beamline of the Shanghai Synchrotron Radiation Facility （SSRF）. Experimental studies confirm that GAGG scintillation screens exhibit superior imaging performance in X-ray applications， particularly beneficial for medical imaging and industrial nondestructive inspection applications. The theoretical spatial resolution of GAGG scintillation screens is 0.4 μm， whereas our experiment attained 0.9 μm （555 lp/mm）， a performance level that aligns with current state-of-the-art systems in the field. Comparative analysis reveals that spatial resolution exhibits limited variation with screen thickness in the 0.3~1 mm range， but shows greater sensitivity to surface conditions and optical transmittance. Therefore， in fabricating high-resolution GAGG scintillation screens， excessive reduction in thickness below practical thresholds is unnecessary. Efforts should prioritize improving crystalline optical quality through growth process optimization （inclusion suppression） and polishing technique refinement （surface roughness control）.

Key words: GAGG∶Ce; garnet; scintillator; scintillation screen; X-ray imaging; spatial resolution

CLC Number:

O734

LI Mingqing, ZHAO Shuwen, FENG Jing, ZHENG Xiang, GUO Han, YUAN Lanying, DING Dongzhou, FENG He. X-Ray Imaging Performance of Gd₃(Al,Ga)₅O₁₂∶Ce Scintillation Screens under Synchrotron Radiation[J]. Journal of Synthetic Crystals, 2025, 54(12): 2112-2118.

Figures/Tables 9

Fig.1 Photograph of GAGG scintillation screens

Table 1 Sample ID with composition， thickness and processing details

Sample ID	Composition	Thickness/mm	Processing
GAGG-0.3D	GAGG∶1%Ce	0.3	Double-sided polishing
GAGG-1D	GAGG∶1%Ce	1.0	Double-sided polishing
GAGG-1DMg	GAGG∶1%Ce， 0.3%Mg	1.0	Double-sided polishing
GAGG-1DYb	GAGG∶1%Ce， 0.2%Yb	1.0	Double-sided polishing
GAGG-0.3S	GAGG∶1%Ce	0.3	Single-sided polishing
GAGG-0.3N	GAGG∶1%Ce	0.3	No polishing

Fig.2 Optical and scintillation performance test results. （a） X-ray excited luminescence spectra；（b） transmission spectra；（c） pulse height spectra；（d） scintillation decay curves

Table 2 Performance parameters of scintillation screens

Sample ID	XEL peak/nm	Transmission@ 530 nm/%	Full energy peak	FWHM	Energy resolution/%	Scintillation decay/ns
GAGG-1D	532	87	461	35.1	7.6	113
GAGG-1DMg	537	83	372	36.0	9.7	63
GAGG-1DYb	532	82	345	29.1	8.4	65

Fig.3 Geant4 simulation results

Fig.4 X-ray imaging photographs of scintillation screens. （a），（c） GAGG-0.3D；（e），（g） GAGG-1D；（b），（d），（f），（h） the local magnifications and grayscale values of the corresponding photographs

Fig.5 X-ray imaging photographs of scintillation screens. （a） GAGG-0.3S；（b） GAGG-0.3N， the unit is lp/mm

Fig.6 X-ray imaging photographs of scrntillation screens. （a），（c） GAGG-1DMg；（d），（f） GAGG-1DYb；（b），（e） the local magnifications and grayscale values of the corresponding photographs

Fig.7 Object X-ray imaging photographs. （a） Photograph of object；（b），（c） X-ray imaging photographs of chip；（d）~（f） X-ray imaging photographs of fish

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X-Ray Imaging Performance of Gd₃(Al,Ga)₅O₁₂∶Ce Scintillation Screens under Synchrotron Radiation

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