Self‐assembly of plasmonic nanoparticles on optical fiber end face

Kularia, Muskan; Aftenieva, Olha; Sarkar, Swagato; Steiner, Anja M.; Gupta, Vaibhav; Fery, Andreas; Joseph, Joby; Schmidt, Markus A.; König, Tobias A. F.

doi:10.1002/pol.20230024

Cited by 2 publications

(1 citation statement)

References 49 publications

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“…[48,140] Note that a plasmonic array does not necessarily guarantee ultrasharp modes. [156,157] Nanostructures with smaller dimensions (d) compared to their periodicity (Λ), i.e., arrays with lower fillfactor (F = d/Λ), mainly result in sharper features [46,158] compared to structures with higher fill-factor. [159] Depending on the NPs' geometric properties and their coupled diffraction mode order, the ultra-narrow resonances can possess either dipolar [139,160] or quadrupolar [161,162] characteristics.…”

Section: Surface Lattice Resonancementioning

confidence: 99%

Engineering Plasmonic Hybridization toward Advanced Optical Sensors

Sarkar,

König

2023

Advanced Sensor Research

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The requirements for an optical sensor are high: the sensor should be reliable, quick, and simple, and all these features must be provided at ultralow fabrication costs. The requirements go even further, as the sensor may operate without an energy source, and nowadays, the sensor components should be recyclable. Today existing plasmonic concepts and advances in nanofabrication can meet these requirements. This review article describes the available nanoscale components and discusses their reasonable layout to obtain the sensing requirements. It is shown that combining photonic and plasmonic properties helps to get high sensitivity at low losses, where these hybrid modes with simple optical concepts are introduced. The current state of the art in developing lithographic nanostructuring and directed self‐assembly to pave the way for future refractive index sensors is also used. By providing a guideline for advanced sensors, how the individual optical components can be used to create hybrid properties that can be realized cost‐effectively are shown. The review article ends with a discussion on the perspectivs for plasmonic hybridization sensors.

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Section: Surface Lattice Resonancementioning

confidence: 99%

Engineering Plasmonic Hybridization toward Advanced Optical Sensors

Sarkar,

König

2023

Advanced Sensor Research

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Advances in scalable plasmonic nanostructures: towards phase-engineered interference lithography for complex 2D lattices

Sarkar,

Aftenieva,

König

2024

Colloid Polym Sci

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Scalable plasmonic nanostructures are reliably created by controlled drying of a colloidal suspension on prefabricated templates. More complex structures such as hexagonal, Lieb, honeycomb, or Kagome lattices are required to develop specific band structures. Laser inference lithography (LIL) combined with template-assisted self-assembly (TASA) offers fabricating nanostructures reliably with high precision over large areas. Less well-known is that more complex 2D lattice geometries are possible with phase-engineered interference lithography (PEIL). Using optical design and electromagnetic simulations, we numerically propose the potential of PEIL towards realizing complex structures of various periodicities. We present the advantages of these structures using dispersion diagrams showing Dirac cones for honeycomb lattices, which are known from the electronic band structure of graphene or an optical band gap for Kagome lattices at an oblique angle. Further, based on our simulated optical characterization of the proposed 2D plasmonic gratings supporting surface lattice resonances (SLR), it is possible to achieve an exceptionally small linewidth of 1 nm for hexagonal and honeycomb gratings. Consequently, we discuss the benefits of refractive index sensors, where we found a ten times higher sensitivity for such complex plasmonic lattices. Overall, we propose and estimate the potential of PEIL for colloidal plasmonics to be realized using the conventional TASA method. Graphical Abstract The König research group describes the innovative process of producing complex 2D plasmonic lattices by phase-engineered interference lithography (PEIL). The proposed PEIL approach provides the foundation for implementing future template-assisted self-assembly (TASA) using this method. The optical properties of these gratings, such as narrow line widths and a high figure of merit (FOM), are emphasized, which are crucial to advancing the colloidal plasmonics and nanostructuring field.

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Self‐assembly of plasmonic nanoparticles on optical fiber end face

Cited by 2 publications

References 49 publications

Engineering Plasmonic Hybridization toward Advanced Optical Sensors

Engineering Plasmonic Hybridization toward Advanced Optical Sensors

Advances in scalable plasmonic nanostructures: towards phase-engineered interference lithography for complex 2D lattices

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