AI Article Synopsis
- Self-powered solar-blind UV photodetectors using nontoxic copper halide CsCuI were developed using a unique vapor co-deposition method, showcasing their potential in various applications.
- By optimizing annealing conditions, the resulting CsCuI films achieved high quality with improved morphology and carrier lifetimes, leading to effective performance in photodetection.
- The device exhibited excellent characteristics like low dark current, high solar-blind rejection ratios, stability after prolonged use, and promising potential for solar-blind UV applications.
Article Abstract
Self-powered solar-blind ultraviolet (UV) photodetectors have drawn worldwide attention in recent years because of their important applications in military and civilian areas. In this study, a dual-source vapor codeposition technique was employed, for the first time, to prepare a nontoxic copper halide CsCuI, which was integrated with the β-GaO wafer to construct a type-II heterojunction for photodetection applications. By optimizing the annealing conditions, high-quality CsCuI films with dense morphology, high crystallinity, and a long carrier lifetime of 1.02 μs were acquired. Because of the high material integrity of CsCuI films and effective interfacial carrier transfer from CsCuI to β-GaO, a heterojunction device demonstrates a good solar-blind UV response property and operates at zero bias. Typically, the photodetector presents a low dark current (∼1.2 pA), a high solar-blind/UVA rejection ratio (∼1.0 × 10), a relatively fast photoresponse speed (37/45 ms), and a high photo-to-dark current ratio (∼5.1 × 10) at zero bias. Moreover, even after 12-h continuous working and 2-month storage without encapsulation in ambient air, the photodetection ability of the device can almost be maintained, demonstrating outstanding air stability. Our results suggest that nontoxic CsCuI is able to serve as a prospective candidate for stable solar-blind UV photodetection.
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| http://dx.doi.org/10.1021/acsami.1c00387 | DOI Listing |
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