Abstract
The combination of graphene with semiconductor materials in heterostructure photodetectors enables amplified detection of femtowatt light signals using micrometer-scale electronic devices. Presently, long-lived charge traps limit the speed of such detectors, and impractical strategies, e.g., the use of large gate-voltage pulses, have been employed to achieve bandwidths suitable for applications such as video-frame-rate imaging. Here, atomically thin graphene-WS2 heterostructure photodetectors encapsulated in an ionic polymer are reported, which are uniquely able to operate at bandwidths up to 1.5 kHz whilst maintaining internal gain as large as 106 . Highly mobile ions and the nanometer-scale Debye length of the ionic polymer are used to screen charge traps and tune the Fermi level of the graphene over an unprecedented range at the interface with WS2 . Responsivity R = 106 A W-1 and detectivity D* = 3.8 × 1011 Jones are observed, approaching that of single-photon counters. The combination of both high responsivity and fast response times makes these photodetectors suitable for video-frame-rate imaging applications.
Highlights
We report the first study of WS2-graphene heterostructure photodetectors with an ionic polymer gate
Hybrid WS2-graphene photodetectors have been fabricated onto p-Si/SiO2 (300 nm) substrates, where the doped Si serves as a global back gate
The WS2-graphene devices were covered by a transparent ionic polymer, lithium perchlorate/poly(ethylene oxide) (LiClO4/PEO, 8:1 in methanol), which serves as a top gate, see Figure 1a
Summary
We report the first study of WS2-graphene heterostructure photodetectors with an ionic polymer gate.
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