Self‐Collimation and Slow Light‐Based Refractive Index Sensor with a Large Detection Range

Barough, Ali Samadian; Noori, Mina; Abbasiyan, Amin

doi:10.1002/andp.202100052

Cited by 3 publications

(1 citation statement)

References 44 publications

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“…Optical sensors benefit from the fast response time among other types due to the high speed of light. So far, diverse optical sensors have been introduced based on photonic crystals (PCs), optical fibers, and plasmonic phenomena [3][4][5]. Optical sensors are divided into two main categories of labeled and label-free sensors [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

Analyte detection based on SPR in 12-fold quasi-periodic PCF

Abbasiyan¹,

Noori²,

Vakili³

et al. 2021

Phys. Scr.

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In this article, an SPR sensor based on 12-fold quasi-periodic PCF composed of Ge-doped silica is introduced for analyte detection. The outer surface of the cladding is covered by a 40 nm gold layer serving as the plasmonic layer for the proposed sensor. The birefringence induced due to the inherent characteristic of the 12-fold pattern in the cross-section provides discrepancy for the operation of the structure regarding x- and y-polarizations. The wavelength sensitivity, amplitude sensitivity, and resolution of 12150 nm.RIU−1, 678 RIU−1, and 8.23 × 10–6 RIU, respectively are obtained for the proposed sensor. The FEM method has been implemented to investigate the performance of the proposed sensor for biosensing application in a detection range of 1.33–1.41.

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Section: Introductionmentioning

confidence: 99%

Analyte detection based on SPR in 12-fold quasi-periodic PCF

Abbasiyan¹,

Noori²,

Vakili³

et al. 2021

Phys. Scr.

Self Cite

View full text Add to dashboard Cite

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RETRACTED ARTICLE: Exploring surface plasmon resonance ring resonator structure for high sensitivity and ultra-high-Q optical filter with FDTD method

Krishnamoorthy¹,

Soubache²,

Farmani

2022

Opt Quant Electron

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Origin of the frequency-sensitive super-collimation phenomenon from the geometry of band dispersion surface for two-dimensional photonic crystals

2022

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Frequency-sensitive super-collimation (FSSC) is a novel dispersion phenomenon of photonic crystals (PhCs) that can realize the beam collimating propagation with very high frequency sensitivity. In order to deeply investigate the origin and the stability of FSSC phenomenon in a wide parameter space, we study the geometry of dispersion surface in detail. Four features for the special geometry of dispersion surface with FSSC are found for rectangular PhCs. The special geometry supports the stability of FSSC in a wide range of parameter space. Two-parameter modulation (TPM) method, in which the aspect ratio β and the dielectric constant of rods ɛ r of rectangular lattice are chosen as the key parameters, is used to analyze the geometry of dispersion surface from the frequency changes at the high-symmetry points. Step by step, the origin of such geometry is revealed and the evolving process can be explained by the field distribution changes of Bloch modes at the high-symmetry points. Furthermore, we show that the geometry not only can be used to explain the origin and the stability of FSSC, but also can help us to find other FSSC phenomenons. Theoretically, we believe the geometry of dispersion surface and the TPM can be widely used on the studies of complex dispersion properties of PhCs. The FSSCs found in this work with higher sensitivity or higher stability can help us to design new on-chip PhC devices.

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Self‐Collimation and Slow Light‐Based Refractive Index Sensor with a Large Detection Range

Cited by 3 publications

References 44 publications

Analyte detection based on SPR in 12-fold quasi-periodic PCF

Analyte detection based on SPR in 12-fold quasi-periodic PCF

RETRACTED ARTICLE: Exploring surface plasmon resonance ring resonator structure for high sensitivity and ultra-high-Q optical filter with FDTD method

Origin of the frequency-sensitive super-collimation phenomenon from the geometry of band dispersion surface for two-dimensional photonic crystals

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