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High-Performance Dual-Band Self-Powered Photoelectrochemical Photodetector Based on Type-I In<sub>2</sub>Te<sub>3</sub>/Se Heterostructure for Encrypted Optical Communication

H. J. Song, Jinhong Liu, Yue Wu, Yanqing Ge, Nan Ma, T. H. Wang, Chunhui Lu, Yixuan Zhou, Xinlong Xu

2025Nano Letters11 citationsDOI

Abstract

Self-powered photoelectrochemical (PEC) photodetectors have emerged as promising candidates for optical communication systems owing to the natural compatibility with aqueous environments, simple fabrication processes, excellent detection sensitivity, and flexibly tunable photoresponse. However, existing PEC-based optical communication devices predominantly operate in a single-channel mode (either visible or ultraviolet spectrum), making them inherently vulnerable to signal interception and information leakage. This work presents the first experimental demonstration of secure dual-wavelength optical communication systems employing self-powered PEC photodetectors based on a type-I In 2 Te 3 /Se heterostructure. This self-powered photodetector shows strong visible-NIR photoresponse, excellent operational stability, fast response of hundreds of microseconds, and high photoresponsivity. Based on this, we developed a dual-wavelength optical communication architecture, comprising a 550/1030 nm free-space transmission system and a 450/550 nm underwater optical communication system to facilitate high-precision encrypted data transmission. These results demonstrate the feasibility of developing dual-band self-powered PEC photodetectors for multiscenario encrypted optical communication applications.

Topics & Concepts

PhotodetectorHeterojunctionDual (grammatical number)OptoelectronicsEncryptionMaterials scienceOptical communicationComputer scienceComputer networkArtLiteratureChalcogenide Semiconductor Thin Films2D Materials and ApplicationsQuantum Dots Synthesis And Properties
High-Performance Dual-Band Self-Powered Photoelectrochemical Photodetector Based on Type-I In<sub>2</sub>Te<sub>3</sub>/Se Heterostructure for Encrypted Optical Communication | Litcius