In recent years, Pb-free CsSnI3 perovskite materials with excellent photoelectric properties as well as low toxicity are attracting much attention in photoelectric devices. However, deep level defects in CsSnI3, such as high density of tin vacancies, structural deformation of SnI6− octahedra and oxidation of Sn2+ states, are the major challenge to achieve high-performance CsSnI3-based photoelectric devices with good stability. In this work, defect passivation method is adopted to solve the above issues, and the ultra-stable and high-performance CsSnI3 nanowires (NWs) photodetectors (PDs) are fabricated via incorporating 1-butyl-2,3-dimethylimidazolium chloride salt (BMIMCl) into perovskites. Through materials analysis and theoretical calculations, BMIM+ ions can effectively passivate the Sn-related defects and reduce the dark current of CsSnI3 NW PDs. To further reduce the dark current of the devices, the polymethyl methacrylate is introduced, and finally, the dual passivated CsSnI3 NWPDs show ultra-high performance with an ultra-low dark current of 2 × 10–11 A, a responsivity of up to 0.237 A W−1, a high detectivity of 1.18 × 1012 Jones and a linear dynamic range of 180 dB. Furthermore, the unpackaged devices exhibit ultra-high stability in device performance after 60 days of storage in air (25 °C, 50% humidity), with the device performance remaining above 90%.
Formamidinium lead iodide (FAPbI3) perovskites are promising emitters for near-infrared light-emitting diodes. However, their performance is still limited by defect-assisted nonradiative recombination and band offset-induced carrier aggregation at the interface. Herein, we introduce a couple of cadmium salts with acetate or halide anion into the FAPbI3 perovskite precursors to synergistically passivate the material defects and optimize the device band structure. Particularly, the perovskite analogs, containing zero-dimensional formamidinium cadmium iodide, one-dimensional δ-FAPbI3, two-dimensional FA2FAn-1PbnI3n+1, and three-dimensional α-FAPbI3, can be obtained in one pot and play a pivotal and positive role in energy transfer in the formamidinium iodide-rich lead-based perovskite films. As a result, the near-infrared FAPbI3-based devices deliver a maximum external quantum efficiency of 24.1% together with substantially improved operational stability. Combining our findings on defect passivation and energy transfer, we also achieve near-infrared light communication with device twins of light emitting and unprecedented self-driven detection.
Lead halide perovskite single crystals have attracted
wide interest
in the field of X-ray detection due to their excellent photophysical
properties. However, their inherent toxicity and high thickness restrict
their applications in flexible devices. In this paper, designing a
micronanometer-scale X-ray detector based on all-inorganic lead-free
CsAg2I3 (CAI) single crystal microbelts (MBs)
has addressed the above issues. These CAI single crystal MBs can be
synthesized on various substrates with high crystal quality and excellent
stability. Based on their excellent characteristics of the CAI MBs,
we fabricate single CAI MB devices with an Au/CAI/Au structure, which
shows not only good ultraviolet photoresponse characteristics, but
also excellent X-ray detection performance. The optimized CAI photodetectors
exhibit a responsivity of 23.59 mA/W, a high detectivity of 1010 Jones, and a fast response speed. For X-ray detection performance,
a sensitivity of up to 515.49 μC Gyair
–1 cm–2 and a detection limit of as low as 14.65
μGyair s–1 are achieved with outstanding
operation stability and excellent long-term stability. Furthermore,
our devices also showed excellent applicability for X-ray imaging,
which is promising for their use in X-ray detection and imaging. Finally,
flexible X-ray detectors are fabricated by using thin CAI single-crystal
MBs and demonstrate good flexibility under different bending radii
and bending cycles. Our work shows the potential for developing highly
sensitive flexible integrated micro/nano optoelectronic devices by
using lead-free perovskite analogue single crystals.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.