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Abstract
With the increasing demand for optical data transmission and processing by modern communication systems, high-speed optoelectronics operating at telecom wavelengths are greatly desired. Two-dimensional (2D) materials with high carrier mobility and picosecond intrinsic response times exhibit large potential in this respect. However, most reported 2D material photodetectors for the telecom C-band either suffer from a slow response speed or rely on integrated silicon waveguides, which is a consequence of the inefficient utilization of hot carriers in these devices. Here, we report a high-performance and waveguide-free WS2/graphene photodetector operating at 1560 nm enabled by hot carrier injection and long-lived charge separation. The efficiently injected hot electrons from graphene to WS2 exhibit ultrafast cooling dynamics with 3 ps intrinsic response time. Simultaneous hole trapping in WS2 ensures a long circulation of injected electrons, enabling a high responsivity of 0.26 A/W. In continuation, we present a vertical WS2/graphene/WSe2 device with a built-in electric field and the same detection mechanism, for which a photocurrent on-off ratio of 3500 and an extrinsic response time of 1.71 ns are obtained. Our study highlights the benefits of combing 2D semiconductors and semimetals for high-speed photodetection.
Supplementary materials
Title
Supporting Information
Description
Methods
Supporting Section 1: Power density dependence of the photoresponse in WS2/graphene heterostructures with 636 nm (above WS2 bandgap) excitation
Supporting Section 2: I-V characteristics of a pure graphene photodetector
Supporting Section 3 : Exponential fitting of the slow dip component
Supporting Section 4: Power dependence of 2PC measurements in WS2/graphene
Supporting Section 5: Reproducibility of the intrinsic photoresponse signal
Supporting Section 6: Calculation of the photoresponsivity for WS2/graphene at 1560 nm laser
Supporting Section7: Comparison of the photocurrent intensity in devices with and without the slow component
Supporting Section 8: Fabrication procedure of WS2/graphene photodetector arrays
Supporting Section 9: 2PC measurements of WSe2/graphene/WS2 veritical heterostructures
Supporting Section 10: Supplementary results for the laser repetition-related extrinsic response time and the 3-dB bandwidth in WSe2/graphene/WS2 photodetectors
Supporting References
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