Chiral Plasmonic Ellipsoids: An Extended Mie–Gans Model

Perera, Tharaka; Mallawaarachchi, Sudaraka; Premaratne, Malin

doi:10.1021/acs.jpclett.1c03144

Cited by 9 publications

(3 citation statements)

References 55 publications

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“…Modifying the conductor's structure, it is possible to customize the properties of plasmons, especially their interactions with light. This opens up exciting possibilities for creating novel photonic devices [20][21][22][23][24]. To advance next-generation communication channels in chip-scale environments, our primary focus should center on the research field of surface plasmon polaritons (SPPs), a key component of plasmonics.…”

Section: Introductionmentioning

confidence: 99%

Investigating the impact of polarization on surface plasmon polariton characteristics in plasmonic waveguides under periodic driving fields

Herath,

Gunapala,

Premaratne

2024

Phys. Scr.

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This study delves into the effects of polarization on surface plasmon polariton (SPP) modes within plasmonic waveguides when subjected to periodic driving fields. Addressing a significant knowledge gap in the existing literature, we present a comprehensive investigation employing Floquet engineering techniques, with a specific emphasis on elliptically polarized fields as the dressing field. Our analysis reveals that the use of generalized Floquet states allows us to derive Floquet states for specific polarized dressing fields, such as linear, left-handed circular, and right-handed circular polarization. Remarkably, we demonstrate that Floquet states depend on the chirality of the dressing field's polarization. Employing the Floquet-Fermi golden rule, we assess electron transport under various polarization types and find that the specific polarization type influence electron transport properties. However, we establish that the chirality of the polarization of the dressing field does not impact the transport properties. During our numerical analysis, we assess the alterations in SPP characteristics arising from two distinct types of polarization in dressing fields: linear polarization and circular polarization. Our results underscore the potential of employing a dressing field to effectively mitigate the propagation losses of SPPs in plasmonic metals, with the extent of improvement contingent on the specific polarization type. To quantify the performance enhancements of commonly used plasmonic metals under linearly and circularly polarized dressing fields, we employ a figure of merit (FoM). This study offers insights into the practical utilization of periodic driving fields as a powerful tool in advancing plasmonic communication within chip-scale environments.

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Section: Introductionmentioning

confidence: 99%

Investigating the impact of polarization on surface plasmon polariton characteristics in plasmonic waveguides under periodic driving fields

Herath,

Gunapala,

Premaratne

2024

Phys. Scr.

Self Cite

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“…As a result, research related to SPs have enabled many possibilities for modern nanoscale imaging and sensing applications. 1,3,[5][6][7] Since the collective oscillations of metal electrons, SPs always arise with trapped electromagnetic fields on the interface. Based on the field propagation manner, researchers have introduced two distinct modes of surface plasmons: Localized surface plasmons (LSPs) and surface plasmon polaritons (SPPs).…”

Section: Introductionmentioning

confidence: 99%

Polarization effect on dressed plasmonic waveguides

Herath¹,

Premaratne

2022

Emerging Imaging and Sensing Technologies for Security and Defence VII

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We present the polarization effect on surface plasmonic polariton (SPP) modes in plasmonic waveguides under high-intensity radiation via the Floquet engineering methods. First, we analyze the strong light coupling to the metallic system using a nonperturbative procedure. Then, we describe the behavior of dressed metal fermion system using the Floquet state solutions. Furthermore, we examine the impurity scattering effects on electron transport in disordered plasmonic metals using the generalized Floquet-Fermi golden rule. We also show that we can reduce the SPP propagation losses in plasmonic metals by applying a dressing field. We introduce a new figure of merit to compare the performance of popular plasmonic metals, assessing their performance enhancements under two different polarization types of dressing fields. Our study can be applied to accurately interpret the usage of strong external radiation as a tool in quantum plasmonic circuits and devices.

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“…Furthermore, in order to simplify the process difficulty, chiral meta-surfaces with single-layered or multilayered two-dimensional (2D) structures are gradually developed including split-rings, , gammadions, ,, L-shapes, twisted stacked crosses, and nanocylinders with anisotropic rectangular lattices . However, most chiral meta-surfaces are made of metal in previous studies − whose inherent Ohmic loss limits the optical efficiency . Hence, dielectric meta-surfaces have gradually become a new research hot topic because of the low absorption loss.…”

mentioning

confidence: 99%

Meta-Atom Coupling Induced Chiral Hotspot in Silicon Nitride Staggered Nanorods Meta-Surface

Gao

Shi

et al. 2023

J. Phys. Chem. Lett.

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Dielectric meta-surfaces have emerged as an effective way for fabricating chiral optical devices, and the chiral meta-surfaces are usually constituted by periodic chiral meta-atom structures. Here, we report a chiral meta-surface consisting of nonchiral silicon nitride rectangular nanorods. The chiral hotspots are generated between the staggered nanorods due to the coupling between the two nearest neighbor nanorod units. 14.6% macroscopic circular dichroism (CD) is achieved experimentally with larger area staggered nanorods. Meanwhile, we demonstrate that the wavelength tuning capability of this design from 696 to 820 nm by simply modulating the overlap length of nanorods. Our work highlights the mechanisms for CD hotspot generation without complex chiral units, which paves a novel way for future on-chip photon-spin selective devices.

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Chiral Plasmonic Ellipsoids: An Extended Mie–Gans Model

Cited by 9 publications

References 55 publications

Investigating the impact of polarization on surface plasmon polariton characteristics in plasmonic waveguides under periodic driving fields

Investigating the impact of polarization on surface plasmon polariton characteristics in plasmonic waveguides under periodic driving fields

Polarization effect on dressed plasmonic waveguides

Meta-Atom Coupling Induced Chiral Hotspot in Silicon Nitride Staggered Nanorods Meta-Surface

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