Doped Emitting Cesium Silver Halides as X-Ray Scintillator with Fast Response Time, High Absorption Coefficient, and Light Yield

Radioluminescence materials (scintillators) are widely investigated because of their potential application in many fields, such as medical imaging, security-related techniques, and nondestructive inspection. However, the fabrication of scintillator materials with simultaneously fast response time, high absorption coefficient, and high light yield, as well as low toxicity is still a challenge. Herein, the synthesis of Cu(I)-doped Cs2AgI3 single crystals (SCs) with a 1D crystal structure is presented. A bright blue-green photoluminescence (PL) is observed after incorporating Cu+ into the Cs2AgI3 SCs under UV irradiation at room temperature. The PL quantum yield of the doped samples can reach up to 73% at a Cu+ concentration of 0.66%. Experimental and theoretical studies show that the blue-green emission may originate from self-trapped excitons, which is further verified by photophysical results from control experiments on pure Cs2AgI3 SCs. Upon X-ray excitation, Cu-doped SCs exhibit fast scintillation decay time (288 ns), high light yield (27 000 photons per MeV), and high absorption coefficient compared with the commercial product (CsI: Tl). These results suggest that Cu-doped Cs2AgI3 is an ideal scintillator, which will be a promising candidate for potential application in dynamic real-time imaging and radiation detection.

Automated summary

The study successfully synthesized Cu(I)-doped Cs2AgI3 single crystals, which exhibit bright blue-green photoluminescence under UV irradiation with high PL quantum yield. Cu-doped SCs demonstrate fast scintillation decay time and high light yield compared to the commercial product CsI:Tl, showing promising potential for applications in dynamic real-time imaging and radiation detection.