Directional launching of surface plasmon polaritons by electrically driven aperiodic groove array reflectors

Lin, Yuanhai; Hoang, Thanh Xuan; Chu, Hong‒Son; Nijhuis, Christian A.

doi:10.1515/nanoph-2020-0558

Cited by 15 publications

(16 citation statements)

References 57 publications

(70 reference statements)

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“…The right outermost arc in Figure 2 is due to both the scattering and leakage radiation of the right-propagating Cu-glass SPPs. [23] The third feature appearing along the inner circle (k/k 0 ≈ 1) represents the Cu-air SPP that approaches the Cu waveguide end. This waveguide end scatters the Cu-air SPPs to photons.…”

Section: Electrical and Optical Characterization Of Tunnel Junctionsmentioning

confidence: 99%

“…[3][4][5] Most plasmonic components, however, are optically driven by off-chip light sources [6,7] and limited to to control the direction of SPP excitation and propagation from tunnel junctions by integration of edge-to-edge nanorods, [20] Yagi-Uda antennas, [21,22] or aperiodic gratings. [23] Furthermore, tunneling junctions are arguably the smallest possible plasmon sources that can be scaled down to the nanometer scale. For instance, plasmonic tunnel junctions are routinely made with tips of scanning tunneling microscopes.…”

Section: Introductionmentioning

confidence: 99%

“…[46] Although impressive progress has been made toward improving the properties of plasmonic components, integration of different plasmonic components in electronic-plasmonic transducers is rare. For example, ultrafast temporal modulation (>1 GHz) of light emission, [15] directional plasmon excitation, [23,47] or highly efficient plasmon excitation [48] has been demonstrated for tunnel junctions equipped resonant structures. To utilize SPPs as information carriers, it is desirable to write and read out plasmonic signals via electrical means.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

CMOS‐Compatible Electronic–Plasmonic Transducers Based on Plasmonic Tunnel Junctions and Schottky Diodes

Wang

Liu

Hoang

et al. 2021

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plasmonic metals, such as Au and Ag, that are not CMOS compatible. [8] Here, we report an all-electrical, CMOS-compatible electronic-plasmonic transducer based on an Al-AlO X -Cu tunnel junction as the plasmon source, a Si-Cu Schottky diode as the plasmon detector, both connected by a Cu plasmonic strip waveguide. These electronic-plasmonic transducers do not require bulky off-chip components and are useful for future on-chip applications where it is vital to interface plasmonics with microelectronics. [1,9] Often, SPPs are excited by optical means, which requires momentummatching elements such as gratings or prisms. [10] One approach to realize on-chip excitation of SPPs is to miniaturize the light sources where first an electrical signal is converted to photons which then couple to SPPs. [3,11,12] In this context of miniaturization, metalinsulator-metal tunnel junctions (MIM-TJs) are interesting because they can be used as electrically driven plasmon sources where SPPs are directly excited via inelastic tunneling of electrons. [13][14][15] The potential of such plasmonic tunnel junctions has been explored in terms of two-photon emission, [16] above threshold emission (where the emitted photons have higher energy than the applied bias), [17,18] and nonlinear effects [19] have been demonstrated. It is also possible To develop methods to generate, manipulate, and detect plasmonic signals by electrical means with complementary metal-oxide-semiconductor (CMOS)-compatible materials is essential to realize on-chip electronicplasmonic transduction. Here, electrically driven, CMOS-compatible electronic-plasmonic transducers with Al-AlO X -Cu tunnel junctions as the excitation source of surface plasmon polaritons (SPPs) and Si-Cu Schottky diodes as the detector of SPPs, connected via plasmonic strip waveguides of Cu, are demonstrated. Remarkably, the electronic-plasmonic transducers exhibit overall transduction efficiency of 1.85 ± 0.03%, five times higher than previously reported transducers with two tunnel junctions (metal-insulatormetal (MIM)-MIM transducers) where SPPs are detected based on optical rectification. The result establishes a new platform to convert electronic signals to plasmonic signals via electrical means, paving the way toward CMOS-compatible plasmonic components.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/smll.202105684.

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Section: Electrical and Optical Characterization Of Tunnel Junctionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

CMOS‐Compatible Electronic–Plasmonic Transducers Based on Plasmonic Tunnel Junctions and Schottky Diodes

Wang

Liu

Hoang

et al. 2021

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“…[4,[10][11][12] Inelastic tunneling can also be utilized to excite SPP modes propagating along plasmonic waveguides. [13][14][15] Directional control over SPPs and light emission has also been demonstrated via the integration of optical elements, such as gratings, [16] nanoantennas, [17] nanoparticles, [18] Yagi-Uda antennas, [19] and tilted self-assembled monolayers. [20] This paper describes a new method to manipulate the location of SPP/photon excitation within large-area junctions by tuning the tunneling current density via engineering of the tunnel oxide thickness.…”

Section: Introductionmentioning

confidence: 99%

Spatial Control over Stable Light‐Emission from AC‐Driven CMOS‐Compatible Quantum Mechanical Tunnel Junctions

Wang

Hoang

Chu

et al. 2022

Laser & Photonics Reviews

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The potential application of quantum mechanical tunnel junctions as subdiffraction light or surface plasmon sources has been explored for decades, but it has been challenging to create devices with subwavelength spatial control over the light or plasmon excitation. This paper describes spatial control over the electrical excitation of surface‐plasmon polaritons (SPPs) and photons in large‐area junctions of the form of Al–AlOX–Cu complementary metal‐oxide‐semiconductor (CMOS)‐compatible tunnel junctions. Nanoscale spatial control (smallest feature sizes of 150 nm) is achieved by locally fine‐tuning the thickness of the AlOX tunneling barrier resulting in large local tunneling currents and associated SPP excitation rates. Mostly, plasmonic tunnel junctions are studied under DC operation with a relatively large bias (and associated currents) to observe light emission at optical frequencies. Large voltages risk device failure and reduce device lifetimes. Here it is demonstrated that the operational lifetime of AC‐driven plasmonic tunnel junctions is improved by a factor of three. Under DC conditions, slow processes that lead to device failure (e.g., undesirable electromigration leading to shorts) readily occur, thus limiting the device decay time to 9.2 h; but under AC operation, such processes are slow with respect to the voltage changes prolonging the decay time beyond 18.0 h.

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“…Compared to optical excitation schemes, where the position of the plasmonic waveguide within the laser waist beam has to be precisely controlled in order to excite SPPs close to the edges of the waveguide, 30,35,42−44 in MIM-TJs connected to plasmonic waveguides, SPPs can easily be excited across the entire width of the waveguides and the edge diffraction can easily be obtained as previously observed. 38,39,41,45 Additionally, the edge diffraction clearly separates the metal−air leaky SPP contributions from those of the metal−glass SPPs, which can only be detected via scattering at the end of the waveguide due to the bound nature of the modes. 38,46 Hence, an integrated structure where the MIM-TJ is in-plane with a plasmonic stripe waveguide offers an efficient platform for investigating the SPP edge diffraction.…”

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confidence: 99%

Geometric Control Over the Edge Diffraction of Electrically Excited Surface Plasmon Polaritons by Tunnel Junctions

2021

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Plasmonic metal–insulator–metal tunnel junctions (MIM-TJs) readily excite surface plasmon polaritons (SPPs) by inelastic electron tunneling, well below the diffraction limit, eliminating the need for bulky optical elements. The highly confined MIM cavity mode (MIM-SPP) excited by the tunneling electrons dominantly outcouples to photons and single-interface SPPs which further outcouple as photons and give characteristic features in the Fourier plane of observation. Here, we employ SPP waveguides, directly integrated with MIM-TJs, to explore the diffraction of single-interface SPPs at the edges of the metal stripe waveguides. In addition to the leakage of the SPP modes through the metal electrodes, SPP edge diffraction presents as an additional channel for SPP outcoupling, not limited by the thickness of the waveguide. Edge diffraction manifests as a straight-line feature in the Fourier plane of the far-field and by systematically varying the width of the waveguides, we show that the in-plane momentum of the SPPs can be controlled, which in turn leads to control over the edge diffraction. We fabricated MIM-TJs with integrated plasmonic stripe waveguides of different widths, and the propagation and confinement of the SPP modes along the edges of the SPP waveguides are directly identified by the experimental back focal plane imaging, which are further corroborated by numerical simulations. Our findings can be exploited for applications ranging from sensing to nonlinear plasmonics, where focusing and localization of SPP fields are necessary.

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Directional launching of surface plasmon polaritons by electrically driven aperiodic groove array reflectors

Cited by 15 publications

References 57 publications

CMOS‐Compatible Electronic–Plasmonic Transducers Based on Plasmonic Tunnel Junctions and Schottky Diodes

CMOS‐Compatible Electronic–Plasmonic Transducers Based on Plasmonic Tunnel Junctions and Schottky Diodes

Spatial Control over Stable Light‐Emission from AC‐Driven CMOS‐Compatible Quantum Mechanical Tunnel Junctions

Geometric Control Over the Edge Diffraction of Electrically Excited Surface Plasmon Polaritons by Tunnel Junctions

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