Abstract

Performance of 2D photodetectors is often predominated by charge traps that offer an effective photogating effect. The device features an ultrahigh gain and responsivity, but at the cost of a retarded temporal response due to the nature of long-lived trap states. In this work, we devise a gain mechanism that originates from massive charge puddles formed in the type-II 2D lateral heterostructures. This concept is demonstrated using graphene-contacted WS₂ photodetectors embedded with WSe₂ nanodots. Upon light illumination, photoexcited carriers are separated by the built-in field at the WSe₂/WS₂ heterojunctions (HJs), with holes trapped in the WSe₂ nanodots. The resulting WSe₂ hole puddles provide a photoconductive gain, as electrons are recirculating during the lifetime of holes that remain trapped in the puddles. The WSe₂/WS₂ HJ photodetectors exhibit a responsivity of 3 × 10² A/W with a gain of 7 × 10² electrons per photon. Meanwhile, the zero-gate response time is reduced by 5 orders of magnitude as compared to the prior reports for the graphene-contacted pristine WS₂ monolayer and WS₂/MoS₂ heterobilayer photodetectors due to the ultrafast intralayer excitonic dynamics in the WSe₂/WS₂ HJs.