Polarization-sensitive infrared photodetectors based on van der Waals heterojunction with the unilateral depletion region

In recent years, polarization infrared detection technology has made great progress and has been successfully applied in various fields such as national defense, astronomy, and civil applications. However, so far, the integration of micro polarizers and infrared photodetectors is still a big challenge since metal microstructures are severely limited in their size. As anisotropic two-dimensional (2D) materials rapidly appear, this distinctive polarization characteristic regardless of the size provides new freedom to polarization infrared photodetectors. In this paper, a van der Walls heterojunction with the unilateral depletion region was constructed to obtain polarization-sensitive infrared photodetection, in which black phosphorus (BP) serves as a natural polarizer. BP/PtS2 infrared photodetectors possess a fast response speed (the rise time is 56 mu s and the fall time is 64 mu s). At the same time, these photovoltaic detectors achieve a high detectivity of 4.47 x 10(10) cm Hz(1/2) W-1 at 830 nm. Using the anisotropic structure of BP, the photovoltaic polarization detector was realized, and its polarization extinction ratio at 830 nm was 2.66 (3.18 @ 1310 nm and 2.63 @ 1550 nm). This work discovers the potential value of anisotropic 2D materials in infrared polarization-sensitive photodetection and provides a possibility for a new infrared polarization detection system.

Automated summary

In recent years, the polarization infrared detection technology has advanced and been applied in various fields. However, integrating micro polarizers with infrared photodetectors remains a challenge. In this study, a van der Walls heterojunction was used to achieve polarization-sensitive infrared photodetection, utilizing black phosphorus as a natural polarizer. The results demonstrated fast response speed and high detectivity, providing potential for a new infrared polarization detection system.