Ultra-high resolution filter and optical field modulator based on a surface plasmon polariton

Wu, Wenjun; Yang, Junbo; Zhang, Jingjing; Huang, Jie; Chen, Dingbo; Wang, Hongqing

doi:10.1364/ol.41.002310

Cited by 38 publications

(30 citation statements)

References 23 publications

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“…Examples of photonic devices created for plasmons are shown in Figure 4 and include "Y" junctions for combining or separating plasmons [68][69][70][71][72], "X" junctions [70], proximity couplers [73], directional couplers [74] [73, [75][76][77][78], Bragg grating filters [69,79], add-drop filters [80], and ring resonators [69,79,81] that transmit or reflect plasmon waves depending on frequency and switching using phase shifts [82]. A novel plasmon filter was created using two wires of different materials joined together that provided a large electric permittivity mismatch resulting in unidirectional propagation [83].…”

Section: Linear Devices For Optical Computingmentioning

confidence: 99%

Plasmonic circuits for manipulating optical information

2016

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Surface plasmons excited by light in metal structures provide a means for manipulating optical energy at the nanoscale. Plasmons are associated with the collective oscillations of conduction electrons in metals and play a role intermediate between photonics and electronics. As such, plasmonic devices have been created that mimic photonic waveguides as well as electrical circuits operating at optical frequencies. We review the plasmon technologies and circuits proposed, modeled, and demonstrated over the past decade that have potential applications in optical computing and optical information processing.

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Section: Linear Devices For Optical Computingmentioning

confidence: 99%

Plasmonic circuits for manipulating optical information

2016

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“…Surface plasmon polaritons (SPPs) have shown the considerable potential to control light at the subwavelength scale due to their ability of overcoming the diffraction limit [1]. Recently, huge kinds of highly integrated optical devices have been investigated or demonstrated assisted by plasmonic nanostructures, such as perfect absorbers [2,3], filters [4][5][6], all-optical switches [7][8][9], and nanofocusing structures [10][11][12]. Among these devices, plasmonic sensors for refractive index sensing have been explored by means of the classical analogue of electromagnetically induced transparency (EIT) [13][14][15] or perfect absorption resonance [16][17][18].…”

Section: Introductionmentioning

confidence: 99%

High sensitivity microsensor assisted by Fano resonance in InSb based terahertz plasmonic waveguide

Liu¹,

Zhong²,

Xu³

2019

Optica Applicata

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We propose a compact terahertz plasmonic structure comprising an InSb-dielectric-InSb waveguide side-coupled with two stub resonators. Due to the coherent interference of the splitting discrete and quasi-continuum modes, the reflection spectrum possesses a sharp asymmetric Fano resonance dip, which stems from the phase difference between the two stub resonators. Owing to the permittivity temperature dependent property of InSb, the Fano resonance dip can be actively controlled by tuning temperature. The physical features contribute to a highly efficient plasmonic sensor for both refractive index and temperature sensing. The microsensor yields a sensitivity of ~2.9 THz/RIU and 1.8 × 10-3 THz/°C. This multiparameter high sensitivity microsensor may find important applications in medical sensing, biosensing and on-chip sensing working in terahertz region.

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“…Surface plasmon polaritons (SPPs) are electromagnetic fields propagating along the interface of metal-insulator, and have been widely discussed for several decades due to the ability to modulate light in nanoscale as well as break the diffraction limit [1]. Recently, many kinds of plasmonic devices have been investigated such as filters [2], absorbers [3], splitters [4] and sensors [5]. Among these, plasmonic sensors have drawn more attention, because compared with traditional optical sensors such as fiber sensors and silicon-based sensors, plasmonic sensors have much smaller size with comparable sensing performance, which means they are more suitable for integrating [6].…”

Section: Introductionmentioning

confidence: 99%

Plasmonic Refractive Index Sensor with High Figure of Merit Based on Concentric-Rings Resonator

Zhang

Yang

et al. 2017

Preprint

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A plasmonic refractive index (RI) sensor based on metal-insulator-metal (MIM) waveguide coupled with concentric double rings resonator (CDRR) is proposed and investigated numerically. Utilizing the novel supermodes of the CDRR, the FWHM of the resonant wavelength can be modulated, and a sensitivity of 1060 nm/RIU with high figure of merit (FOM) 203.8 is realized in the near-infrared region. The unordinary modes as well as the influence of structure parameters on the sensing performance are also discussed. Such plasmonic sensor with simple framework and high optical resolution could be applied to on-chip sensing systems and integrated optical circuits. Besides, the special cases of bio- sensing and triple rings are also discussed.

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Ultra-high resolution filter and optical field modulator based on a surface plasmon polariton

Cited by 38 publications

References 23 publications

Plasmonic circuits for manipulating optical information

Plasmonic circuits for manipulating optical information

High sensitivity microsensor assisted by Fano resonance in InSb based terahertz plasmonic waveguide

Plasmonic Refractive Index Sensor with High Figure of Merit Based on Concentric-Rings Resonator

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