光探测
光电二极管
光电子学
材料科学
量子效率
异质结
光电探测器
范德瓦尔斯力
吸收(声学)
宽带
光子
比探测率
光学
量子
串联
载流子
能量转换效率
量子阱
光子学
吸收率
工作(物理)
物理
作者
Xi Zhang,Ruizhi Li,Shuzhou Qu,Zhexing Duan,Fang Yang,Ting Zheng,Qi Zhang,Jialin Zhang,Zhenhua Ni,Junpeng Lu
摘要
ABSTRACT The development of self‐powered photodetectors that simultaneously achieve high quantum efficiency and fast response remains a fundamental challenge in optoelectronics, primarily due to the intrinsic trade‐off between photon absorption depth and carrier transit distance. Here, we present a vertical van der Waals photodiode architecture that overcomes this limitation through a synergistic photon recycling and vertical extraction mechanism. By integrating a WSe 2 /MoS 2 heterojunction directly on a metal‐mirror electrode, we concurrently enhance optical absorption while establishing a nanoscale vertical transport channel that minimizes carrier transit time. This dual‐function design enables a record external quantum efficiency of 84% at zero bias, a fast response time of ∼200 ns, a specific detectivity of 1.6 × 10 11 cm Hz 1/2 W −1 , and a power conversion efficiency of 11.2%. Benefitting from the type‐II band alignment heterostructure, the vertical vdW photodiode achieves broadband detection from visible (633 nm) to the near‐infrared region (1550 nm). This work provides a generalizable device strategy for developing next‐generation, high‐performance, and low‐power optoelectronic systems.
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