Time-resolution addressable photoelectrochemical strategy based on hollow-channel paper analytical devices.

Abstract The construction of a photoelectrochemical (PEC) strategy for multi-component detection represents a great challenge in the field of sensing. To address these challenges, herein we presented a hollow-channel paper-based PEC analytical platform based on chemiluminescence (CL) addressable strategies excited PEC strategy for multiplexed sensing application. Sandwich-structured CdS quantum dots (QDs)/reduced graphene oxide (RGO)/ZnO nanorods arrays (NRAs) heterostructure where CdS serves as visible light sensitizers, RGO acts as an electron relay between ZnO NRAs and CdS QDs, were simply assembled on the gold nanoparticles modified paper working photoelectrode (Au-PWE). The PEC performance of the CdS/RGO/ZnO can be greatly improved benefiting from the formation of type II band alignment between CdS QDs and ZnO NR as well as the super charge collection and shuttling property of RGO. Multiplexed CL emission could be achieved through controlling the CL co-reagents transport. By the virtue of CL addressable technique and the excellent PEC activity of CdS/RGO/ZnO, a highly sensitive, and selective multiple microRNAs (miRNAs) quantification method was achieved. Such a tailored strategy would break the bottleneck of the current PEC detection techniques in multiplex tracing, as well as serve as a novel concept for designing multi-channel PEC sensing method. Highlights • A high-throughput photoelectrochemical device was constructed on hollow-channel paper based device. • Sandwich-structured CdS quantum dots/reduced graphene oxide /ZnO nanorods heterostructure was prepared. • Functionalized hollow-channel with different capillary forces was created to control the fluids flow rate. • Successive chemiluminescence emission can be realized to excite the photoactive materials based on the flow rate controlling. [ABSTRACT FROM AUTHOR]