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Among them, lead-halide-based perovskites have emerged as a compelling contender due to their remarkable luminescence efficiency, superior X-ray attenuation capabilities, and short fluorescence lifetimes. However, their application in the scintillation field is hindered by the toxicity of heavy metal lead (Pb), low photon yield caused by self-absorption effects, and poor X-ray irradiation stability.
Breaking barriers: Lead-free anti-perovskite nanocrystals
To overcome these challenges, researchers have sought solutions in lead-free zero-dimensional (0D) metal halides, such as copper-, silver-, zirconium-, and manganese-based halides. These intriguing alternatives have shown promise as effective scintillators for X-ray detection and imaging, boasting high photon yields, diverse composition and structure options, and a unique luminescence mechanism known as self-trapped excitons (STEs).
However, a major hurdle lies in the fabrication of these metal halides as thin films or wafers, resulting in subpar imaging resolution due to light scattering caused by large particles and crystal boundaries. Additionally, lead-free 0D metal halides face challenges related to poor stability, particularly in hot and humid environments.
In an astounding breakthrough reported in the journal Advanced Photonics, researchers from South China University of Technology have developed a pioneering approach that revolutionizes X-ray imaging. They have accomplished high-resolution and ultra-stable X-ray imaging even in demanding conditions of high temperature and humidity. The key to their success lies in lead-free Cs3MnBr5 anti-perovskite nanocrystals embedded within a glass matrix.
Unlike traditional perovskite materials, anti-perovskites possess a distinctive structure represented as [MX4]XA3 [A = alkali metal; M = transition metal; and X = chlorine (Cl), bromine (Br), and iodine (I)]. This unique configuration features a luminescence center, the [MX4]2- tetrahedron, nestled within a three-dimensional (3D) XA6 octahedral anti-perovskite skeleton. This structure significantly reduces the interaction of the luminescence center, fostering enhanced spatial confinement effects and ultimately yielding high quantum efficiency and luminescence stability.
Through the process of in-situ crystallization during annealing, Mn2+ ions are seamlessly integrated into the glass matrix, giving rise to tunable luminescence colors ranging from red to green, as dictated by the annealing schedule. Moreover, the Cs3MnBr5 nanocrystal-embedded glass exhibits unparalleled X-ray irradiation stability, thermal stability, and water resistance. Remarkably, it also boasts an exceptional X-ray detection limit of 767 nanograys per second, an impressive X-ray imaging spatial resolution of 19.1 line pairs per millimeter, and outstanding X-ray dose irradiation stability of 5.775 milligrays per second.
This groundbreaking work presents an intriguing new scheme that harnesses the potential of transparent glassy composites incorporating lead-free anti-perovskite halide nanocrystals for high-resolution and ultrastable X-ray imaging applications. The results of this research could serve as a catalyst, stimulating further exploration and development of novel metal halide anti-perovskite materials. Ultimately, this discovery paves the way for the future development of next-generation X-ray imaging devices, promising transformative advancements in the field of X-ray diagnostics and imaging.
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