Growth and Luminescence Properties of Sm2+-Ce3+ Co-Doped CLLB Scintillation Crystals

doi:10.16553/j.cnki.issn1000-985x.2025.0192

Abstract

Abstract: Due to the better matched with the spectral response of silicon-based photodetectors，offering a promising route toward compact，highly sensitive radiation detection，the near infrared scintillators have attracted much interest. The Sm²⁺ activated halide scintillators with emission wavelength of 700 nm to 900 nm have been developed. However，the strategy of single Sm²⁺ doping have some disadvantage of low light out and worse energy resolution. Usually，the co-doping is an effect method to improve the scintillation properties by adjusting the energy transfer efficiency，defect structure and quantity.In this work，the Cs₂LiLaBr₆∶Ce³⁺ with excellent scintillation properties is chosen as a host，and the Sm²⁺ is introduced as a near infrared emitting center to construct an energy transfer route from Ce³⁺ to Sm²⁺. Cs₂LiLaBr₆∶Ce³⁺，Sm²⁺ single crystals with varied Sm²⁺ concentrations were successfully grown by the vertical Bridgman method. The axial distribution and segregation behavior of Sm²⁺ were quantitatively evaluated using ICP-MS，yielding an effective segregation coefficient of about 2.0，which indicates a pronounced tendency of Sm enrichment during crystal growth. Optical properties and energy transfer were investigated by steady state photoluminescence，time resolved decay measurements，and photoluminescence quantum yield. In addition，X-ray excited luminescence and thermoluminescence were employed to probe defect related trapping and radiative processes.The co-doped crystals exhibit three characteristic emission bands centered at approximately 390，420 and 770 nm. The two visible bands originate from Ce³⁺ 5d to 4f transitions，while the near infrared band is assigned to Sm²⁺ 5d-4f emission，demonstrating successful introduction of near infrared luminescence for the Cs₂LiLaBr₆ matrix. The spectral overlap between Ce³⁺ emission and Sm²⁺ excitation is observed，together with the evolution of decay dynamics，provide strong evidence for energy transfer from Ce³⁺ to Sm²⁺. Notably，a number of energies are loss during the energy transfer pathway of Ce-Sm，implying the presence of competing nonradiative channels and trap assisted dissipation. The photoluminescence quantum yield increased firstly and then decreased as Sm²⁺ concentration raised. It reaches a maximum value of about 98.5% when the Sm²⁺ concentration is 3%. The concentration quenching is happened for the higher doping concentration. Thermoluminescence and X-ray excited luminescence further reveal that the Sm²⁺ co-doping reconstructs the defect energy of the host，altering the trap depth and recombination pathways.Overall，this study establishes a systematic design and characterization framework for Ce³⁺ sensitized Sm²⁺ near infrared emission in the Cs₂LiLaBr₆ host，provides quantitative insight into dopant segregation，and clarifies the coupled roles of energy transfer losses and defect evolution. These findings offer practical guidance for optimizing near infrared halide scintillators intended for silicon-based readout and advanced radiation detection applications.

Key words: Sm²⁺ doping; Cs₂LiLaBr₆∶Ce³⁺; Sm²⁺; vertical Bridgman method; energy transfer; scintillation crystal; luminescence property

CLC Number:

O782

WANG Haohan, WEI Qinhua, SHU Chang, YIN Hang, TANG Gao, ZHANG Suyin, QIN Laishun. Growth and Luminescence Properties of Sm²⁺-Ce³⁺ Co-Doped CLLB Scintillation Crystals[J]. Journal of Synthetic Crystals, 2026, 55(2): 201-210.

Figures/Tables 9

Fig.1 Crystal diagram of CLLB∶2%Ce3+，x%Sm2+ （a） and its XRD patterns （b）

Fig.2 （a） Survey XPS of CLLB∶2%Ce3+，x%Sm2+ crystal；（b） high-resolution XPS of Cs+，La3+，and Br- in CLLB∶2%Ce3+，3%Sm2+；（c） high-resolution XPS of Sm2+ in CLLB∶2%Ce3+，x%Sm2+ crystal；（d） high-resolution XPS of Ce3+ in CLLB∶2%Ce3+，x%Sm2+ crystal

Fig.3 （a） Crystal image and selected sampling positions；（b） segregation of Sm2+ in crystal

Table 1 Concentrations of Sm2+ at different positions in crystal

Sample ID/cm	Sm²⁺ concentration in crystal/%	Relative solidification position （Z/L）
1 （0.00）	4.00	0
2 （0.08）	2.49	0.016
3 （0.33）	2.06	0.066
4 （0.50）	1.83	0.100
5 （0.67）	1.49	0.134
6 （1.17）	1.32	0.234
7 （1.67）	1.23	0.334
8 （2.17）	1.16	0.434
9 （2.67）	0.86	0.534
10 （3.67）	0.48	0.734

Fig.4 （a） Emission spectra of crystals with different Sm2+ concentrations （λ??=360 nm）；（b） excitation spectra of crystals，monitored at wavelengths of 390，420，and 770 nm respectively；（c） excitation spectrum （λ?? = 770 nm） and emission spectrum （λ?? = 360 nm） of CLLB∶2%Ce3+，3%Sm2+ crystal；（d） emission spectra of crystal （λ??=420，390 nm）

Fig.5 Fluorescence decay curves of CLLB∶2%Ce3+，x%Sm2+ crystals

Fig.6 PLQY results of CLLB∶2%Ce3+，x%Sm2+ crystals

Fig.7 XEL results of CLLB∶2%Ce3+，x%Sm2+ crystals，insets is proportion of integrated intensity of Ce3+ and Sm2+ related emission peaks

Fig.8 （a） TL spectra of CLLB∶2%Ce3+，CLLB∶2%Ce3+，1%Sm2+，and CLLB∶2%Ce3+，3%Sm2+ in temperature range from 100 K to 400 K；（b） luminescence mechanism diagram of CLLB∶Ce3+，Sm2+

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Growth and Luminescence Properties of Sm²⁺-Ce³⁺ Co-Doped CLLB Scintillation Crystals

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