Se; [8] Park and co-workers reported sensitivities of CH 3 NH 3 PbI 3 X-ray detectors as high as 11 000 µC Gy air −1 cm −2 . [9] On the other hand, inorganic lead halide perovskites have demonstrated high carrier mobilities, good stability, and low ionic migrations compared to organic-inorganic hybrid perovskite [11] and, therefore, provide higher detection sensitivity toward X-rays; however, they have rarely been studied as X-ray detectors.Another challenge is the fabrication of a thick perovskite film with controlled orientations. A thickness of hundreds of micrometers to millimeters is the prerequisite for complete X-ray attenuation. The uniform orientation of perovskite films is beneficial for charge transport and collection along the electric field direction, thereby requiring a quasi-monocrystalline film. Here, we define a quasi-monocrystalline as the crystal with the same orientation and without grain boundaries along the vertical direction. Current perovskite film-based X-ray detectors face the issue of random orientation and, thus, inefficient charge collection. [9] A new method to fabricate thick quasimonocrystalline perovskite films for X-ray detection is urgently needed.For the first time, here, we employ a hot-pressing method to fabricate thick quasi-monocrystalline inorganic perovskite CsPbBr 3 films. The thickness of the film reaches hundreds of micrometers, which guarantees complete X-ray attenuation. The good orientation of the films is tuned to promote carrier transport close to that of the single-crystal samples. Most importantly, as-fabricated CsPbBr 3 X-ray detectors demonstrate a high sensitivity of 55 684 µC Gy air −1 cm −2 as a result of high carrier mobility, large µτ product, and photoconductive gain effect. Additionally, CsPbBr 3 detectors also exhibit relatively fast response speed, negligible baseline drift, and good stability, which together make the CsPbBr 3 X-ray detector extremely competitive in high-contrast X-ray detection and imaging applications.Currently, the synthesis of high-quality millimeter-thick perovskite films is still a great challenge, because the typical solution-based process often results in many pinholes when the solvent is evaporated out of the film. [9] Here, we propose and demonstrate a hot-pressing method to obtain thick perovskite films. The hot-pressing method avoids the use of any solvent, An X-ray detector with high sensitivity would be able to increase the generated signal and reduce the dose rate; thus, this type of detector is beneficial for applications such as medical imaging and product inspection. The inorganic lead halide perovskite CsPbBr 3 possesses relatively larger density and a higher atomic number in contrast to its hybrid counterpart. Therefore, it is expected to provide high detection sensitivity for X-rays; however, it has rarely been studied as a direct X-ray detector. Here, a hot-pressing method is employed to fabricate thick quasi-monocrystalline CsPbBr 3 films, and a record sensitivity of 55 684 µC Gy air −1 cm −2 is achieved, surpas...
