Phase-engineering compact and flexible CsPbBr 3 microcrystal films for robust X-ray detection.
Lotte ClinckemalieBapi PradhanRoel Vanden BrandeHeng ZhangJonathan VandenwijngaerdenRafikul Ali SahaGiacomo RomoliniLi SunDirk VandenbrouckeMischa BonnHai I WangElke DebroyePublished in: Journal of materials chemistry. C (2023)
All-inorganic CsPbBr 3 perovskites have gained significant attention due to their potential in direct X-ray detection. The fabrication of stable, pinhole-free thick films remains challenging, hindering their integration in durable, large-area high-resolution devices. In this study, we propose a facile strategy using a non-conductive polymer to create a flexible, compact thick film under ambient conditions. Furthermore, we investigate the effect of introducing the 2D CsPb 2 Br 5 phase into CsPbBr 3 perovskite crystals on their photophysical properties and charge transport. Upon X-ray exposure, the devices consisting of the dual phase exhibit improved stability and more effective operation at higher voltages. Rietveld refinement shows that, due to the presence of the second phase, local distortions and Pb-vacancies are introduced within the CsPbBr 3 lattice. This in turn presumably increases the ion migration energy barrier, resulting in a very low dark current and hence, enhanced stability. This feature might benefit local charge extraction and, ultimately, the X-ray image resolution. These findings also suggest that introducing a second phase in the perovskite structure can be advantageous for efficient photon-to-charge carrier conversion, as applied in medical imaging.