CsPbI3 nanorods as the interfacial layer for high-performance, all-solution-processed self-powered photodetectors

Heterojunction is regarded as a crucial step toward realizing high-performance devices, particularly, forming gradient energy band between heterojunctions benefits self-powered photodetectors. Therefore, in this paper, the synthesis of CsPbI3 nanorods (NRs) and its application as the interfacial layer in high-performance, all-solution-processed self-powered photodetectors are presented. For the bilayer photodetector ITO/ZnO(100 nm)/PbS-TBAI(150 nm)/Au, a responsivity of 3.6 A/W with a specific detectivity of 9.8 x 10(12) Jones was obtained under 0.1 mW/cm(2) white light illumination at zero bias (i.e. in self-powered mode). Meanwhile, the photocurrent was enhanced to an On/Off current ratio of 10(5) at zero bias with an open circuit voltage of 0.53 V for trilayer photodetector ITO/ZnO(100 nm)/PbS-TBAI(150 nm)/CsPbI3(250 nm)/Au, in which the CsPbI3 NRs layer works as the interfacial layer. As a result, a specific detectivity of 4.5 x 10(13) Jones with a responsivity of 11.12 A/W was obtained under 0.1 mW/cm(2) white light illumination, as well as the rising/decaying time of 0.57 s/0.41 s with excellent stability and reproducibility upto four weeks in air. The enhanced-performance is ascribed to the mismatch bandgap between PbS-TBAI/CsPbI3 interface, which can suppress the carrier recombination and provide efficient transport passages for charge carriers. Thus, it provides a feasible and efficient method for high-performance photodetectors. (C) 2021 Published by Elsevier Ltd on behalf of The editorial office of Journal of Materials Science & Technology.