Predicting the Performance of Surface Plasmon Resonance Sensors Based on Anisotropic Substrates

Eloise P. Rodrigues; Arthur A. Melo; Antonio M.N. Lima

doi:10.1007/s11468-020-01257-w

Predicting the Performance of Surface Plasmon Resonance Sensors Based on Anisotropic Substrates

Eloise P. Rodrigues, Arthur A. Melo, Antonio M.N. Lima

Universidade Federal de Campina Grande

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

The aim is to investigate how the sensing features of a surface plasmon resonance sensor based on the Kretschmann configuration are affected when the optical substrate is an anisotropic medium. The investigation considers the use of two different uniaxial anisotropic crystals, one made of barium titanate and another made of lithium niobate, as the optical substrate. It also considered that the sensor operates in the angular interrogation mode at the gold–water interface. The Fresnel equations and the finite element method were employed to determine the sensing features. The present study revealed that both formulations provide almost identical results for the resonance angle (difference less than 1%). On the other hand, the two formulations provide results with significant differences for additional features like the sensitivity and the full width at half maximum.

Original language	English
Pages (from-to)	403-412
Number of pages	10
Journal	Plasmonics
Volume	16
Issue number	2
DOIs	https://doi.org/10.1007/s11468-020-01257-w
State	Published - Apr 2021
Externally published	Yes

Keywords

Angular interrogation mode
Anisotropic medium
Kretschmann configuration
Surface plasmon resonance

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10.1007/s11468-020-01257-w

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title = "Predicting the Performance of Surface Plasmon Resonance Sensors Based on Anisotropic Substrates",

abstract = "The aim is to investigate how the sensing features of a surface plasmon resonance sensor based on the Kretschmann configuration are affected when the optical substrate is an anisotropic medium. The investigation considers the use of two different uniaxial anisotropic crystals, one made of barium titanate and another made of lithium niobate, as the optical substrate. It also considered that the sensor operates in the angular interrogation mode at the gold–water interface. The Fresnel equations and the finite element method were employed to determine the sensing features. The present study revealed that both formulations provide almost identical results for the resonance angle (difference less than 1%). On the other hand, the two formulations provide results with significant differences for additional features like the sensitivity and the full width at half maximum.",

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AU - Lima, Antonio M.N.

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N2 - The aim is to investigate how the sensing features of a surface plasmon resonance sensor based on the Kretschmann configuration are affected when the optical substrate is an anisotropic medium. The investigation considers the use of two different uniaxial anisotropic crystals, one made of barium titanate and another made of lithium niobate, as the optical substrate. It also considered that the sensor operates in the angular interrogation mode at the gold–water interface. The Fresnel equations and the finite element method were employed to determine the sensing features. The present study revealed that both formulations provide almost identical results for the resonance angle (difference less than 1%). On the other hand, the two formulations provide results with significant differences for additional features like the sensitivity and the full width at half maximum.

AB - The aim is to investigate how the sensing features of a surface plasmon resonance sensor based on the Kretschmann configuration are affected when the optical substrate is an anisotropic medium. The investigation considers the use of two different uniaxial anisotropic crystals, one made of barium titanate and another made of lithium niobate, as the optical substrate. It also considered that the sensor operates in the angular interrogation mode at the gold–water interface. The Fresnel equations and the finite element method were employed to determine the sensing features. The present study revealed that both formulations provide almost identical results for the resonance angle (difference less than 1%). On the other hand, the two formulations provide results with significant differences for additional features like the sensitivity and the full width at half maximum.

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Predicting the Performance of Surface Plasmon Resonance Sensors Based on Anisotropic Substrates

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Keywords

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