Coherent Detection of Terahertz Radiation with Graphene

Despite that significant efforts have been made in the development of time-integrated graphene-based detectors operating in vis/IR/THz ranges, little is known about coherent detection of THz pulses with graphene. To date only a few time-resolved studies with on-chip detection schemes, which signific...

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Bibliographic Details
Published in:ACS photonics 2019-07, Vol.6 (7), p.1780-1788
Main Authors: Obraztsov, Petr A, Chizhov, Pavel A, Kaplas, Tommi, Bukin, Vladimir V, Silvennoinen, Martti, Hsieh, Cho-Fan, Konishi, Kuniaki, Nemoto, Natsuki, Kuwata-Gonokami, Makoto
Format: Article
Language:English
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Summary:Despite that significant efforts have been made in the development of time-integrated graphene-based detectors operating in vis/IR/THz ranges, little is known about coherent detection of THz pulses with graphene. To date only a few time-resolved studies with on-chip detection schemes, which significantly limit the spectral range naturally provided by the gapless band structure of graphene, are known. Here we demonstrate free-space room-temperature detection of THz radiation in a wide spectral range with optically gated graphene. The detection principle is based on registration of the time-domain waveform of the THz field by measuring the hot-carrier photocurrent under THz pulse exposure in optically excited graphene using a pump–probe scheme. The applied method is simple and robust, while the sensitivity and working range of the developed graphene-based detector are comparable and in some aspects outperform materials conventionally used for terahertz time-domain spectroscopy based on electro-optic sampling and photoconductive antennas. In addition, we demonstrate that efficient coherent detection of terahertz radiation in a wide range to above 2 THz does not require highly crystalline, single-layer graphene but can be also realized with ultrathin graphite film, which is synthesized directly on an arbitrary dielectric substrate. Employment of such a material for fabrication of ultrafast terahertz detectors creates a versatile platform for the scalable production of wide-aperture photoconductive detectors applicable in spatially resolved time-domain terahertz spectrometers and visualizers.
ISSN:2330-4022
2330-4022
DOI:10.1021/acsphotonics.9b00536