Reconfigurable optoelectronic functionality implemented in a Ta2NiSe5/WS2 heterostructure toward multifunctional applications
Abstract
With the advancement of artificial intelligence, an increasing array of application scenarios is imposing diverse demands on optoelectronic devices. Consequently, the pursuit of multi-functional optoelectronic devices has become highly desirable to streamline system design and minimize costs. However, the fabrication of optoelectronic devices that concurrently facilitate both photodetection and neuromorphic visual simulation poses a significant challenge due to conflicting structural requirements. Herein, we present a Ta2NiSe5/WS2 heterostructure that exhibits dual-modal functionality, integrating photodetection and neuromorphic visual simulation within a single device. Specifically, the device operates in photovoltaic mode under self-powered and reverse bias conditions, transitioning to photoconductive mode under forward bias conditions. In the photovoltaic mode, it demonstrates a high responsivity of 6.58 A W−1, an exceptional detectivity of 1.56 × 1012 Jones, and rapid rise/fall times of 46.9/48.9 μs, enabling effective photodetection. Furthermore, in the photoconductive mode, the device achieves basic synaptic functions for neuromorphic visual sensing, including short-term plasticity (STP), long-term plasticity (LTP), and the ability to “learn–forget–relearn” through photocarrier trapping/de-trapping processes, with a paired pulse facilitation (PPF) of 31.34%. This research introduces a novel strategy for the development of future multifunctional, integrated, intelligent, and compact optoelectronic devices.