Photogating-assisted tunneling boosts the responsivity and speed of heterogeneous WSe 2 /Ta 2 NiSe 5 photodetectors.
Mingxiu LiuJingxuan WeiLiujian QiJunru AnXingsi LiuYahui LiZhiming ShiDa-Bing LiKonstantin S NovoselovCheng-Wei QiuShaojuan LiPublished in: Nature communications (2024)
Photogating effect is the dominant mechanism of most high-responsivity two-dimensional (2D) material photodetectors. However, the ultrahigh responsivities in those devices are intrinsically at the cost of very slow response speed. In this work, we report a WSe 2 /Ta 2 NiSe 5 heterostructure detector whose photodetection gain and response speed can be enhanced simultaneously, overcoming the trade-off between responsivity and speed. We reveal that photogating-assisted tunneling synergistically allows photocarrier multiplication and carrier acceleration through tunneling under an electrical field. The photogating effect in our device features low-power consumption (in the order of nW) and shows a dependence on the polarization states of incident light, which can be further tuned by source-drain voltages, allowing for wavelength discrimination with just a two-electrode planar structure. Our findings offer more opportunities for the long-sought next-generation photodetectors with high responsivity, fast speed, polarization detection, and multi-color sensing, simultaneously.