Resonant terahertz detection using graphene plasmons

Bandurin, Denis; Svintsov, Dmitry; Gayduchenko, Igor; Xu, Shuigang; Principi, Alessandro; Moskotin, M.; Tretyakov, I. V.; Yagodkin, Denis; Zhukov, Sergey S.; Taniguchi, Takashi; Watanabe, Kenji; Grigorieva, I. V.; Polini, Marco; Gol’tsman, G.; Geǐm, A. K.; Fedorov, G.

doi:10.1038/s41467-018-07848-w

Cited by 290 publications

(221 citation statements)

References 51 publications

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“…Graphene is known for its high carrier mobility, optical transparency and 0 eV bandgap that enables light absorption in a wide energy spectrum (VIS to THz) . However, it has a light absorptivity of only 2.3%, consequently leading to low photoresponses.…”

Section: Progress Of 2d Materials Flexible Photodetectors Architecturesmentioning

confidence: 99%

Flexible Photodetector Based on 2D Materials: Processing, Architectures, and Applications

Dong

Simões

Yang

2020

Adv Materials Inter

148

111

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Flexible photodetectors have emerged during the past few years for applications in healthcare, security, and environmental monitoring. Recently, 2D materials have started being implemented as functional layers in flexible photodetector due to their outstanding optoelectronic characteristics paired with high mechanical flexibility. In this work, the authors analyze the progress of 2D material‐based flexible photodetectors architectures, with a focus on graphene family, (Di)chalcogenides and van der Waals heterostructures. The optical and mechanical characteristics of 2D materials flexible photodetectors are systematically analyzed. Furthermore, the processing techniques compatible with flexible substrates and proof‐of‐concept sensors integrating 2D material flexible photodetectors are also reviewed. In the last section, the remaining challenges and future perspectives are discussed, envisioning to support future developments in the field.

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Section: Progress Of 2d Materials Flexible Photodetectors Architecturesmentioning

confidence: 99%

Flexible Photodetector Based on 2D Materials: Processing, Architectures, and Applications

Dong

Simões

Yang

2020

Adv Materials Inter

148

111

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“…Our experiment paves the way to active plasma resonance transistors working in the 0.1 1 THz  domain, above the natural cutoff ∼0.1 THz of conventional graphene field-effect transistors [21,22]. Building on this first demonstration performed at cryogenic temperatures, a room temperature variant can be envisioned by scaling down the sample size and the plasmon wave length by a factor 10 to accommodate the phononlimited mean free path of 0.7 μm at 300 K. During the reviewing process, we became aware of a related work [23] demonstrating the resonant detection of THz radiation using graphene plasmons. These achievements might in particular lead to the conception of novel detectors in the 600 GHz frequency domain, highly desirable for air-craft RADARs operating in the mm-range, with a resolution ultimately limited by hot electron effects [14,24,25].…”

Section: Introductionmentioning

confidence: 99%

Ultra-long wavelength Dirac plasmons in graphene capacitors

et al. 2018

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Graphene is a valuable 2D platform for plasmonics as illustrated in recent THz and mid-infrared optics experiments. These high-energy plasmons however, couple to the dielectric surface modes giving rise to hybrid plasmon-polariton excitations. Ultra-long wavelengths address the low energy end of the plasmon spectrum, in the GHz-THz electronic domain, where intrinsic graphene Dirac plasmons are essentially decoupled from their environment. However experiments are elusive due to the damping by ohmic losses at low frequencies. We demonstrate here a plasma resonance capacitor (PRC) using hexagonal boron-nitride (hBN) encapsulated graphene at cryogenic temperatures in the near-ballistic regime. We report on a 100 μm quarter-wave plasmon mode, at 40 GHz, with a quality factor Q;2. The accuracy of the resonant technique yields a precise determination of the electronic compressibility and kinetic inductance, allowing to assess residual deviations from intrinsic Dirac plasmonics. Our GHz frequency capacitor experiment constitutes a first step towards the demonstration of plasma resonance transistors for microwave detection in the sub-THz domain for wireless communication and sensing. It also paves the way to the realization of doping-modulated superlattices where plasmon propagation is controlled by Klein tunneling. Two-dimensional electron systems (2DES) sustain both single-particle and collective low-energy excitations, the latter being called plasmons. In graphene, their interplay is controlled by the electron density n which rules the kinetic energy, interactions and damping. Free 2DES plasmons are dispersive with q p

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“…The TeraFET applications already being commercialized include sub‐THz and THz detectors implemented in Si, GaAs, GaN, graphene (see ref. and references therein), and other materials systems (for a review see ref. ).…”

mentioning

confidence: 99%

“…In existing TeraFET applications (mainly using the “non‐resonant” regime of operation), this obstacle is partially overcome due to tunability of the intrinsic device response by the gate voltage. Very recently, there appeared an opportunity for a further revolutionary breakthrough in this direction which is based on experimental results obtained this year by different groups: A resonant tunable response with clearly distinguishable contributions of several plasmonic harmonics was obtained in a graphene TeraFET A possibility to integrate broadband THz antennas with a TeraFET was experimentally demonstrated .…”

mentioning

confidence: 99%

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Plasmonic Helicity‐Driven Detector of Terahertz Radiation

Gorbenko

Kachorovskii

Shur

2018

Physica Rapid Research Ltrs

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A theory of the helicity‐driven plasmonic dc response of a gated two‐dimensional electron gas to terahertz (THz) radiation is developed. A general diagram of a plasmonic detector operating in different regimes is found and analytical equations describing all these regimes are derived. It is demonstrated that the helicity‐sensitive part of the response dramatically increases in the vicinity of the plasmonic resonances and oscillates with the phase shift between the excitation signals on the source and drain. The resonance line shape is an asymmetric function of the frequency deviation from the resonance. In contrast, the helicity‐insensitive part of the response is symmetrical. These properties yield significant advantage for using plasmonic detectors as helicity‐sensitive THz and far infrared spectrometers and interferometers.

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Resonant terahertz detection using graphene plasmons

Cited by 290 publications

References 51 publications

Flexible Photodetector Based on 2D Materials: Processing, Architectures, and Applications

Flexible Photodetector Based on 2D Materials: Processing, Architectures, and Applications

Ultra-long wavelength Dirac plasmons in graphene capacitors

Plasmonic Helicity‐Driven Detector of Terahertz Radiation

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