Flexible, High Scintillation Yield Cs3Cu2I5 Film Made of Ball‐Milled Powder for High Spatial Resolution X‐Ray Imaging

Adv. Optical Mater. 2022, 10, 2102232 DOI: 10.1002/adom.202102232 Through an unfortunate oversight, the element symbol Cs in the chemical formula Cs3Cu2I5 was mistyped in the article title (1×) and in the abstract (5×) of the original publication Adv. Opt. Mater. 2022, 10, 2102232. The wrong “Cu3Cu2I5” is hereby corrected to “Cs3Cu2I5” such that the proper article title reads as shown in the Correction title above. The authors and the publisher are very sorry for the inconvenience. The corrected abstract reads: “Cu halide materials with low electronic dimension show great scintillation properties with high photoluminescence quantum yield (PLQY) and large Stokes shift, which can result in reabsorption-free scintillators. However, there is still a need for a large-scalable method to fabricate large amount of scintillation powder and large-size scintillation films. In this regard, a high scintillation yield Cs3Cu2I5−PDMS flexible film utilizing ball-milled Cs3Cu2I5 powder is developed. The ball-milled Cs3Cu2I5 powder shows a high PLQY of 74.5%, narrow emission peak of 80 nm and good ambient stability, demonstrating the potential of ball-milling method for large-scale scintillator production. Furthermore, the Cs3Cu2I5−PDMS film shows even high PLQY exceeding 90%, which may be ascribed to the passivation effect of PDMS resulting in a little longer carrier lifetime. The flexible Cs3Cu2I5−PDMS film can further deliver high spatial resolution of 6.8 lp mm−1@0.2 MTF in X-ray imaging and good stability under steady X-ray illumination. This work demonstrates that the ball-milling method could be an effective approach for large-scale fabrication of low electronic dimensional scintillation materials.”