Wedge Surface Plasmon Polariton Waveguides Based on Wet-Bulk Micromachining

Hương, Nguyễn Thanh; Chính, Nguyễn Văn; Hoang, Chu Manh

doi:10.3390/photonics6010021

Cited by 12 publications

(5 citation statements)

References 29 publications

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“…4a). This is due to the fact that for a metal wedge embedded in a dielectric medium, the propagation length and propagation mode area decrease with the increment of the refractive index of operation medium [16]. For a 2 nm thin SiO 2 layer, LSPP of the proposed waveguide can be enhanced by a factor of 7.5 compared to that of the Au wedge embedded in air for the case t m = 250 nm (543 µm compared to 72 µm), Fig.…”

Section: Resultsmentioning

confidence: 93%

“…Figure 1 (a) shows the cross-section of conventional metal wedge plasmonic waveguide. The wedge plasmonic waveguide is formed by depositing a thin metal layer on a silicon waveguide (SW) which can be fabricated by using the anisotropic wet etching property of single crystal silicon in potassium solution [16,23]. Therefore, the apex angle of SW is 70o.…”

Section: The Background Of Studymentioning

confidence: 99%

“…SPP waveguides can be found in applications such as fundamental elements in integrated nanophotonic circuits including lightwave guiding at nanoscale, optical switches, optical modulators, and ©2022 Vietnam Academy of Science and Technology optical sensors [1][2][3][4][5][6][7][8][9][10][11][12]. Various types of SPP waveguide have been proposed for improving the propagation length while keeping the propagation mode area at subwavelength size such as metallic nanowires [13], metal strips [14], and wedge-shaped waveguides [15,16]. Among these waveguides, the wedge-shaped SPP waveguides show an excellent capability of the tight lightwave confinement around the apex of metallic wedge [3].…”

Section: Introductionmentioning

confidence: 99%

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Plasmon Wave Propagation Property of Metal Wedge Plasmonic Waveguides Covered by a Protective Oxide Layer

Thuy

Hoang

2022

Comm. in Phys.

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Guiding plasmon waves is based on dielectric/metal interfaces. The wedge-shaped interface shows an excellent capacity in the tight lightwave confinement at deep-subwavelength propagation mode size. Several types of metals have also been investigated for guiding plasmon waves. Among them, the Ag metal shows a plasmon wave guiding ability superior to other metals, however, it is sensitive to the operating medium and is easily oxidized. To overcome these drawbacks, the Ag wedge covered by a protective thin oxide layer is proposed. Numerically investigated results show that the propagation length of the Ag wedge covered by a protective thin silicon dioxide layer can be enhanced by a factor of 7.5 while its figure of merit is at least 1.7 times larger than that of the Au wedge waveguide. The advantage of the proposed interface is potential for developing plasmonic waveguide components.

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Section: Resultsmentioning

confidence: 93%

Section: The Background Of Studymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Plasmon Wave Propagation Property of Metal Wedge Plasmonic Waveguides Covered by a Protective Oxide Layer

Thuy

Hoang

2022

Comm. in Phys.

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“…Over the last few decades, several plasmonic waveguide structures have been modeled theoretically and demonstrated experimentally. The fundamental structures of plasmonic waveguides, including metal V-shape grooves [ 15 ], wedges [ 16 ], ring resonators [ 17 ], and nanowires [ 18 ], exhibit decent confinement but with tradeoffs of high propagation loss along the metal interface. Therefore, researchers have developed a hybrid plasmonic waveguide, which combines the properties of a silicon slab waveguide and surface plasmon, to improve the propagation length of up to several hundred micrometers.…”

Section: Introductionmentioning

confidence: 99%

Surface acoustic wave actuated plasmonic signal amplification in a plasmonic waveguide

Gupta,

Barman,

Lee

et al. 2024

Discover Nano

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Enhancement of nanoscale confinement in the subwavelength waveguide is a concern for advancing future photonic interconnects. Rigorous innovation of plasmonic waveguide-based structure is crucial in designing a reliable on-chip optical waveguide beyond the diffraction limit. Despite several structural modifications and architectural improvements, the plasmonic waveguide technology is far from reaching its maximum potential for mass-scale applications due to persistence issues such as insufficient confined energy and short propagation length. This work proposes a new method to amplify the propagating plasmons through an external on-chip surface acoustic signal. The gold–silicon dioxide (Au-SiO2) interface, over Lithium Niobate (LN) substrate, is used to excite propagating surface plasmons. The voltage-varying surface acoustic wave (SAW) can tune the plasmonic confinement to a desired signal energy level, enhancing and modulating the plasmonic intensity. From our experimental results, we can increase the plasmonic intensity gain of 1.08 dB by providing an external excitation in the form of SAW at a peak-to-peak potential swing of 3 V, utilizing a single chip.

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“…Different structures of lasers [25], waveguides [26], photodetectors [27][28][29], optical modulators [30,31], and optical switches [32,33] have been implemented in different material systems using plasmonic technology. It is worth mentioning here that conventional plasmonic waveguides based on metal/dielectric or metal-dielectric-metal structure are characterized by relatively high intrinsic loss [34,35]. To overcome this problem, hybrid plasmonic waveguide has been proposed, where a thin dielectric layer of low refractive index such as DLD164 (=1.83 at 1550 nm operating wavelength) is sandwiched between the dielectric substrate (silicon) and the metal cladding [36][37][38].…”

Section: Introductionmentioning

confidence: 99%

Design Investigation of 4 × 4 Nonblocking Hybrid Plasmonic Electrooptic Switch

2019

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This paper proposes a compact, plasmonic-based 4 × 4 nonblocking switch for optical networks. This device uses six 2 × 2 plasmonic Mach-Zehnder switch (MZS), whose arm waveguide is supported by a JRD1 polymer layer as a high electro-optic coefficient material. The 4 × 4 switch is designed in COMSOL environment for 1550 nm wavelength operation. The performance of the proposed switch outperforms those of conventional (nonplasmonic) counterparts. The designed switch yields a compact structure ( 500 × 70 µ m 2 ) having V π L = 12 V · µ m , 1.5 THz optical bandwidth, 7.7 dB insertion loss, and −26.5 dB crosstalk. The capability of the switch to route 8 × 40 Gbps WDM signal is demonstrated successfully.

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Wedge Surface Plasmon Polariton Waveguides Based on Wet-Bulk Micromachining

Cited by 12 publications

References 29 publications

Plasmon Wave Propagation Property of Metal Wedge Plasmonic Waveguides Covered by a Protective Oxide Layer

Plasmon Wave Propagation Property of Metal Wedge Plasmonic Waveguides Covered by a Protective Oxide Layer

Surface acoustic wave actuated plasmonic signal amplification in a plasmonic waveguide

Design Investigation of 4 × 4 Nonblocking Hybrid Plasmonic Electrooptic Switch

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