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Nature of Photoconductivity in Self-Powered Single-Atomic-Layered Nb-Doped WSe<sub>2</sub> Phototransistors

Jihyang Park, Seunggyu Kim, Mino Yang, Hideo Hosono, K. Park, Jeechan Yoon, Jina Bak, Bolim You, Sang‐Won Park, Myung Gwan Hahm, Moonsang Lee

2023ACS Photonics19 citationsDOI

Abstract

Although single-atomic-layered alloys are regarded as promising components for improving the performance of broadband photodetectors, the origin of their enhanced photoresponsivity due to the introduction of dopants in the crystal lattice has not yet been investigated in depth. Herein, we comprehensively analyze the nature of the photoconductivity of a photodetector based on a niobium (Nb)-doped WSe 2 monolayer. The Nb-doped WSe 2 photodetector exhibited superior responsivity and specific detectivity compared with those of the undoped WSe 2 photodetectors. Experimental and density functional theory analyses revealed that the introduction of Nb not only modified the Fermi level of WSe 2 but also generated multiple electron-trapping sites, thereby increasing both the photovoltaic and photogating effects to improve the photocurrent of the device. We believe that this research presents a sophisticated approach to achieve photodetectors based on single-atomic-layered alloys, which are both highly sensitive and energy-efficient.

Topics & Concepts

PhotodetectorResponsivityPhotoconductivityMaterials sciencePhotocurrentDopingOptoelectronicsPhotodiodeDopant2D Materials and ApplicationsMXene and MAX Phase MaterialsAdvanced Thermoelectric Materials and Devices