Atomically thin Schottky junction with a gap-mode plasmon for enhanced photoresponsivity in MoS2-based photodetectors

Two-dimensional (2D) materials present various extraordinary properties that are advantageous in optoelectronic devices with atomically thin nature. Despite their excellent light-matter interaction, a low optical absorption that is proportional to thickness is considered to be a major limitation. In...

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Veröffentlicht in:Journal of physics. D, Applied physics Applied physics, 2021-04, Vol.54 (14)
Hauptverfasser: Jin, Hyeok Jun, Lee, Khang June, Park, Cheol Min, Shin, Gwang Hyuk, Hong, Woonggi, Oh, Dongsik, Choi, Sung-Yool
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Sprache:eng
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Zusammenfassung:Two-dimensional (2D) materials present various extraordinary properties that are advantageous in optoelectronic devices with atomically thin nature. Despite their excellent light-matter interaction, a low optical absorption that is proportional to thickness is considered to be a major limitation. In this study, a gap-mode plasmon structure is applied to the Schottky junction of Au-MoS2 to compensate for its low absorption. The magnitude of the gap-mode plasmon is generally known to be inversely proportional to the gap distance between two metal nanostructures; hence, an atomically thin 2D material can be considered to be a good candidate for a gap spacer. Owing to the gap-mode plasmon structure, the photoresponsivity of the proposed device is enhanced by approximately 11.6 times from 25 to 290 A W−1 under 1 nW of laser power, without photoresponse time degradation. Two operation modes, named the photovoltaic and the photoconductive mode, are also observed through different response times; these present different carrier transport mechanisms depending on the existence of bias voltage.
ISSN:0022-3727
1361-6463
DOI:10.1088/1361-6463/abd6ac