Wafer-Scale Growth of Vertical-Structured SnSe2 Nanosheets for Highly Sensitive, Fast-Response UV-Vis-NIR Broadband Photodetectors

Owing to the strong light-matter interactions, 2D semiconducting thin films have shown their great potential in the development of high-performance ultraviolet-visible-near infrared (UV-Vis-NIR) broadband photodetectors (PDs). However, the planar 2D semiconducting thin films via conventional growth method are often in the form of isolated flakes and/or suffering from low absorption efficiency of light, which hinders the UV-Vis-NIR optoelectronics from widespread applications. Herein are reported high-performance nonplanar UV-Vis-NIR broadband PD arrays, based on wafer-scale, vertical-structured SnSe2 nanosheet arrays (NSAs) via low-temperature molecular beam epitaxy method. The vertical-structured SnSe2 NSAs possess light absorption efficiency of >90% covering the wave range from 340 to 650 nm. Benefiting from the excellent light trapping ability and uniformity of waferscaled SnSe2 NSAs as well as relatively short channel, the broadband PD arrays exhibit superior comprehensive performance. They achieve a high responsivity of 31.94 A W-1, fast speed (approximate to 63 mu s), and high uniformity. In addition, the responsivity of the broadband PD arrays is further improved via Zn-doping technique.

Automated summary

High-performance nonplanar UV-Vis-NIR broadband photodetector arrays based on wafer-scale, vertical-structured SnSe2 nanosheet arrays have been developed via low-temperature molecular beam epitaxy method. These arrays exhibit a high light absorption efficiency of >90% and show superior performance in responsivity, speed, and uniformity. In addition, the responsivity of the arrays is further improved through Zn-doping technique.