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Auteurs principaux: He, Chenjia, Sun, Xiaqing, Zhong, Hao, Meng, Qingfeng, Zhou, Xuetong, Liu, Sihang, Zheng, Li, Kong, Xiangyang, Chen, Shengfu, Tao, Shengce, Yang, Tian
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2410.15100
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author He, Chenjia
Sun, Xiaqing
Zhong, Hao
Meng, Qingfeng
Zhou, Xuetong
Liu, Sihang
Zheng, Li
Kong, Xiangyang
Chen, Shengfu
Tao, Shengce
Yang, Tian
author_facet He, Chenjia
Sun, Xiaqing
Zhong, Hao
Meng, Qingfeng
Zhou, Xuetong
Liu, Sihang
Zheng, Li
Kong, Xiangyang
Chen, Shengfu
Tao, Shengce
Yang, Tian
contents We found that the specific dispersion of metal-insulator-metal (MIM) waveguide allows the hybridization of surface plasmon polaritons (SPPs) and the waveguide, which is not possible with dielectric waveguides. The SPP-MIM hybridization structure forms such a meta-film that integrates the previously incompatible respective merits of SPR and LSPR, including flat interfaces, high sensitivities, short evanescent fields and easy coupling with confined light. On the other hand, to achieve stable and reproducible performance is one of the greatest unresolved challenges for the development of nanophotonic biosensors. We point out that the key is to obtain well-controlled biomolecular behaviors using simple physical interfaces, for which the SPP-MIM meta-film provides a capable solution. We embed the SPP-MIM meta-film with a plasmonic crystal cavity and integrate it on a single-mode fiber's end-facet to detect biomolecular interactions. This device demonstrates highly reproducible sensorgrams and convincing detection of biotinylated proteins at down to 30 fM, with the sensorgrams following the Langmuir model. By unprecedentedly having both high sensitivity and high reproducibility, our device proposal provides a comprehensive solution for optical fiber-tip plasmonic devices to turn into a useful industrial biosensing technology.
format Preprint
id arxiv_https___arxiv_org_abs_2410_15100
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Flat Plasmonic Biosensing Interface on Optical Fiber End-Facet via SPP-MIM Hybridization
He, Chenjia
Sun, Xiaqing
Zhong, Hao
Meng, Qingfeng
Zhou, Xuetong
Liu, Sihang
Zheng, Li
Kong, Xiangyang
Chen, Shengfu
Tao, Shengce
Yang, Tian
Optics
We found that the specific dispersion of metal-insulator-metal (MIM) waveguide allows the hybridization of surface plasmon polaritons (SPPs) and the waveguide, which is not possible with dielectric waveguides. The SPP-MIM hybridization structure forms such a meta-film that integrates the previously incompatible respective merits of SPR and LSPR, including flat interfaces, high sensitivities, short evanescent fields and easy coupling with confined light. On the other hand, to achieve stable and reproducible performance is one of the greatest unresolved challenges for the development of nanophotonic biosensors. We point out that the key is to obtain well-controlled biomolecular behaviors using simple physical interfaces, for which the SPP-MIM meta-film provides a capable solution. We embed the SPP-MIM meta-film with a plasmonic crystal cavity and integrate it on a single-mode fiber's end-facet to detect biomolecular interactions. This device demonstrates highly reproducible sensorgrams and convincing detection of biotinylated proteins at down to 30 fM, with the sensorgrams following the Langmuir model. By unprecedentedly having both high sensitivity and high reproducibility, our device proposal provides a comprehensive solution for optical fiber-tip plasmonic devices to turn into a useful industrial biosensing technology.
title A Flat Plasmonic Biosensing Interface on Optical Fiber End-Facet via SPP-MIM Hybridization
topic Optics
url https://arxiv.org/abs/2410.15100