Resonance modes of tall plasmonic nanostructures and their applications for biosensing
The collective oscillation of plasmons in metallic nanostructures generates localized surface plasmons (LSP), which are responsive to their surrounding dielectric environment and can be used for low-cost, label-free sensing platforms. However, the inherently short evanescent decay field saturates th...
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sg-ntu-dr.10356-1544582021-12-23T01:27:48Z Resonance modes of tall plasmonic nanostructures and their applications for biosensing Soehartono, Alana M. Tobing, Landobasa Y. M. Mueller, Aaron D. Yong, Ken-Tye Zhang, Dao Hua School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Plasmonics Electrodeposition The collective oscillation of plasmons in metallic nanostructures generates localized surface plasmons (LSP), which are responsive to their surrounding dielectric environment and can be used for low-cost, label-free sensing platforms. However, the inherently short evanescent decay field saturates the optical response within 10-30 nm of the metal surface, hindering multi-layered functionalization strategies typically used for specific binding due to its limited surface proximity. In this work, we propose the use of tall nanostructures to engineer the plasmonic response for biosensing applications. The resonance mode characteristics are investigated, where the emergence of hybrid modes is found to arise from the decoupling of localized plasmon modes at increasing antenna height. Using high aspect ratio plasmonic nanostructures, we demonstrate its viability with up to 4.3 × higher sensitivity and 18.4 × higher figure of merit within the visible range. Coupled with a cost-effective fabrication method, the height provides an additional degree of freedom for tailoring the optical spectrum. Agency for Science, Technology and Research (A*STAR) This work was supported in part by the NRF-ANR Joint Call 2017 Project through the program under M4197007.640, and in part by the A∗Star under Grant SERC A1883C0002 and Grant SERC 1720700038. 2021-12-23T01:27:47Z 2021-12-23T01:27:47Z 2020 Journal Article Soehartono, A. M., Tobing, L. Y. M., Mueller, A. D., Yong, K. & Zhang, D. H. (2020). Resonance modes of tall plasmonic nanostructures and their applications for biosensing. IEEE Journal of Quantum Electronics, 56(2), 1-7. https://dx.doi.org/10.1109/JQE.2019.2958362 0018-9197 https://hdl.handle.net/10356/154458 10.1109/JQE.2019.2958362 2-s2.0-85076298565 2 56 1 7 en SERC A1883C0002 SERC 1720700038 IEEE Journal of Quantum Electronics © 2019 IEEE. Personal use is permitted, but republication/redistribution requires IEEE permission. |
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Engineering::Electrical and electronic engineering Plasmonics Electrodeposition Soehartono, Alana M. Tobing, Landobasa Y. M. Mueller, Aaron D. Yong, Ken-Tye Zhang, Dao Hua Resonance modes of tall plasmonic nanostructures and their applications for biosensing |
| description |
The collective oscillation of plasmons in metallic nanostructures generates localized surface plasmons (LSP), which are responsive to their surrounding dielectric environment and can be used for low-cost, label-free sensing platforms. However, the inherently short evanescent decay field saturates the optical response within 10-30 nm of the metal surface, hindering multi-layered functionalization strategies typically used for specific binding due to its limited surface proximity. In this work, we propose the use of tall nanostructures to engineer the plasmonic response for biosensing applications. The resonance mode characteristics are investigated, where the emergence of hybrid modes is found to arise from the decoupling of localized plasmon modes at increasing antenna height. Using high aspect ratio plasmonic nanostructures, we demonstrate its viability with up to 4.3 × higher sensitivity and 18.4 × higher figure of merit within the visible range. Coupled with a cost-effective fabrication method, the height provides an additional degree of freedom for tailoring the optical spectrum. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Soehartono, Alana M. Tobing, Landobasa Y. M. Mueller, Aaron D. Yong, Ken-Tye Zhang, Dao Hua |
| format |
Article |
| author |
Soehartono, Alana M. Tobing, Landobasa Y. M. Mueller, Aaron D. Yong, Ken-Tye Zhang, Dao Hua |
| author_sort |
Soehartono, Alana M. |
| title |
Resonance modes of tall plasmonic nanostructures and their applications for biosensing |
| title_short |
Resonance modes of tall plasmonic nanostructures and their applications for biosensing |
| title_full |
Resonance modes of tall plasmonic nanostructures and their applications for biosensing |
| title_fullStr |
Resonance modes of tall plasmonic nanostructures and their applications for biosensing |
| title_full_unstemmed |
Resonance modes of tall plasmonic nanostructures and their applications for biosensing |
| title_sort |
resonance modes of tall plasmonic nanostructures and their applications for biosensing |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/154458 |
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1720447204273946624 |