Multilayer MoS2 photodetector with broad spectral range and multiband response

In recent years, wideband photodetectors have played an important role in various fields such as optical communication, imaging, transmission, sensing, environmental safety, and monitoring. As a typical two-dimensional material, molybdenum disulfide (MoS₂), a transition metal dichalcogenide, has attracted significant attention due to its excellent electrical and optical properties, as well as its ease of processing. However, the bandgap of MoS₂ limits the detection range of its photodetectors. To broaden the response range of MoS₂ photodetectors, various chemical treatment methods have been reported. Additionally, integration of MoS₂ detectors with photonic nanostructures enables enhanced and broadened light response. Nevertheless, mechanically exfoliated MoS₂ photodetectors prepared without the need for chemical treatment possess irreplaceable advantages. Achieving sub-bandgap photodetection in transition metal dichalcogenides through mechanical exfoliation has become a focus of current research. Furthermore, the performance of two-dimensional material photodetectors is closely related to device structures and fabrication methods. In this study, a multilayer MoS₂ field-effect transistor (FET) photodetector was prepared using a mechanical exfoliation method, exhibiting a wide spectral detection range of up to 1550 nm. Experimental results demonstrate that the optimized MoS₂ FET exhibits lower resistance and more stable gate control characteristics. By mechanically exfoliating multilayer MoS₂ during the pre-transfer process, high responsivity and specific detectivity were achieved under 480 nm illumination. The device exhibits good output and transmission characteristics under incident light ranging from 410 to 800 nm, and it is photosensitive. The response bandwidth can be extended to 1550 nm, enabling wideband response across multiple spectral regions. Additionally, the carrier transport characteristics and time-dependent responses of the device at different wavelengths were analyzed. Visible light detection is based on the photoconductive and photogating effects, while infrared light detection beyond the bandgap primarily relies on the photothermal effect.

A research team from Southeast University explained the different electrical characteristics between pretransfer and posttransfer MoS₂ devices through the different contact modes between MoS₂ and Au. The surface potential difference (SPD) at the MoS₂-Au junction of a posttransfer MoS₂ device was observed using Kelvin probe force microscopy. Based on the measurement results of SPD and the difference in work function, it was found that the work function of MoS₂ is approximately 0.05 eV smaller than that of Au. The energy band diagram before and after contact revealed the presence of a Schottky barrier at the MoS₂-Au interface, which resulted in inferior electrical behavior. In the case of pretransfer devices, the MoS₂-Au interface was influenced by Fermi level pinning, leading to a reduction in the work function of Au below that of MoS₂. As a result, Ohmic contact was formed at the MoS₂-Au interface, reducing the contact resistance and increasing the current.

This study presents an optimized mechanically exfoliated multilayer MoS₂ back-gated detector with multi-band photodetection capabilities. Under the optimized pre-transfer fabrication process, the device exhibits improved charge transport performance. Without the need for chemical treatment, the MoS₂ detector achieves a wide spectral photodetection beyond the MoS₂ bandgap. The device demonstrates a maximum responsivity of 33.75 A W⁻¹ at visible light (480 nm), with a corresponding specific detectivity of 6.1×10¹¹ cm Hz^1/2 W⁻¹. The response mechanism under visible light is attributed to the photogating and photoconductive effects. Additionally, the device shows a response at 1550 nm infrared light, surpassing the bandgap limitation, which is attributed to the variation in carrier concentration caused by the photothermal effect. The wideband photodetection behavior of the device is attributed to the photoelectric effect in visible light and the photothermal effect in infrared light, providing insights for room-temperature wideband detection and demonstrating significant potential in various fields such as infrared stealth, machine vision, and environmental monitoring.