Optical Processes behind Plasmonic Applications

Babicheva, Viktoriia E.

doi:10.3390/nano13071270

Cited by 29 publications

(12 citation statements)

References 154 publications

(178 reference statements)

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“…Surface plasmons (SPs) are coherent oscillations of free electrons at the metal-dielectric interface. SPR describes the strong absorption phenomenon of transverse magnetic light caused by resonance, which occurs when the wave vector of the incident light matches that of the SPs [4,5]. SPR-based sensors are reported to be highly sensitive and enable real-time detection of heavy metals [6] and biomolecules [7].…”

Section: Introductionmentioning

confidence: 99%

Effects of thickness and roughness on plasmonic characteristics of gold thin films deposited on polished optical fiber

Sukma,

Hanif,

Masruroh

et al. 2024

Mater. Res. Express

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The thickness and roughness of metal layers substantially affect the performance of surface plasmon resonance (SPR)-based sensors. The deposition methods, control parameters, and substrate characteristics influence the layer thickness and roughness. This study investigates the SPR characteristics of a polished optical fiber surface coated with gold (Au) metal of different thicknesses. The Au layer is deposited via the thermal evaporation method, and its thickness is varied by controlling the deposition time (3–6 minutes). A proportionality relationship between thickness and deposition time is observed. Island-shaped structures in gold (Au) morphology are formed due to low adhesion to the substrate. The shape of this island creates gaps in the layer, causing scattering. In addition, the roughness on the gold surface triggers the Localized Surface Plasmon Resonance (LSPR) phenomenon. As a result, the measured dielectric characteristics differ from the reference. The SPR curve calculation simulation was carried out based on reference optical parameters and measurement results by an ellipsometer, which were then compared with experiments. The obtained results show that the substrate roughness, morphology, and thickness of the Au layer play an essential role in determining the characteristics of the SPR curve in a fiber optic plasmonic sensor. As a result, in basic experiments, the sample with an Au thickness of 27.37 nm (deposition time = 3 min) shows better characteristics (half-maximum full width, minimum transmittance, and resonance wavelength) compared with the sample with an Au thickness of 53.97 nm (deposition time = 4 min), Although 53.97 nm is the optimal thickness from the simulation using reference optical parameters (smooth substrate surface and smooth gold layer).

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Section: Introductionmentioning

confidence: 99%

Effects of thickness and roughness on plasmonic characteristics of gold thin films deposited on polished optical fiber

Sukma,

Hanif,

Masruroh

et al. 2024

Mater. Res. Express

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“…[13][14][15][16] These sensors leverage the collective oscillations of electrons on the surface of metals-plasmons-to detect changes in the local environment. 14,17,18 The interaction of these plasmonic waves with biological or chemical samples results in a change in the local refractive index near the sensor surface. This change is detectable as a shift in the resonance frequency of the sensor, which can be monitored through alterations in the amplitude and phase of the probing light.…”

Section: Introductionmentioning

confidence: 99%

Comparing amplitude-based and phase-based quantum plasmonic biosensing

Mpofu,

Mthunzi-Kufa

2024

Quantum Effects and Measurement Techniques in Biology and Biophotonics

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The utilization of quantum resources can enhance the sensitivity of conventional measurement techniques beyond the standard quantum limit (SQL). The objective of quantum metrology is to enable such quantum enhancements in practical devices. To achieve this objective, it is essential to have devices that are compatible with existing quantum resources operating within the SQL. Plasmonic sensors are promising candidates among these devices since they are extensively employed in biochemical sensing applications. Plasmonic sensors exhibit a response to slight variations in the local refractive index, which manifests as a shift in their resonance response. This shift, in turn, induces changes in the amplitude and phase of the probing light. By utilizing quantum states of light, such as NOON states, squeezed states, or Fock states, to probe these sensors, the measurement noise floor can be lowered, enabling the detection of signals below the SQL. In this study, we compare two configurations of quantum plasmonic sensing: phase-based and amplitude-based. By considering the Quantum Cramér Rao bound for both configurations, we demonstrate that the phase-based configuration can more effectively exploit the available quantum resources than the amplitude-based configuration. A limitation of this work is that it did not consider loss.

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“…36,38−41 Full-wave numerical simulations are essential for analyzing photonic nanostructures as they provide precise information regarding optical responses, including reflection, transmission, power loss (absorption), directional scattering, and field enhancement at specific points within the nanostructure. 10,42 These simulations offer essential insights into the behavior of light in complex nanoscale environments, aiding in the design and optimization of advanced photonic devices.…”

Section: Introductionmentioning

confidence: 99%

“…The electric and magnetic dipole and quadrupole moments of an antenna refer to the characteristics that describe the distribution and strength of its electric and magnetic fields, which play a significant role in determining the antenna’s radiation pattern and performance. Mie resonances are electromagnetic resonant responses that can occur in low-loss high-refractive-index or metallic nanoparticles and arise due to the interaction of light with the nanoparticle. − By incorporating metals and/or high-refractive-index materials into nanostructures, it is possible to achieve nanoscale light confinement and adaptable designs for controlling the optical field. ,− Plasmonic nanostructures take advantage of Mie resonances to efficiently manipulate light at the subwavelength scale.…”

Section: Introductionmentioning

confidence: 99%

“…Analytical models of multipole scattering, such as Mie theory and cross-sections, play a crucial role in understanding the interaction of electromagnetic waves with particles or nanostructures. − These models provide valuable insights into the scattering and absorption phenomena, enabling the characterization and design of various photonic and optoelectronic devices with enhanced functionalities . Additionally, the coupled dipole–quadrupole model for lattice structures offers a powerful framework to analyze the collective optical response of periodic arrangements of nanoparticles, facilitating the engineering of novel metasurfaces and metastructures with tailored optical properties. ,− Full-wave numerical simulations are essential for analyzing photonic nanostructures as they provide precise information regarding optical responses, including reflection, transmission, power loss (absorption), directional scattering, and field enhancement at specific points within the nanostructure. , These simulations offer essential insights into the behavior of light in complex nanoscale environments, aiding in the design and optimization of advanced photonic devices.…”

Section: Introductionmentioning

confidence: 99%

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Multipole Mie Resonances in MXene-Antenna Arrays

Karimi,

Babicheva

2023

J. Phys. Chem. C

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Our research focuses on studying the multipole Mie resonances that are excited within the antennas of transition-metal carbides and nitrides (MXenes), particularly focusing on Ti3C2T x MXene as an array component. Through analytical models, numerical simulations, and experimental characterizations, we explore how collective resonances of the lossy nanostructures, such as MXene or lossy metals, lead to absorption enhancement, reflection suppression, and 2π variations of phase for the transmitted signal. Analytical models provide insights into the nature of the optical resonances excited in the antenna array, allowing for the identification of the strongest multipole and designing the antenna array accordingly. This study presents experimental measurements of the near-infrared reflection from a titanium antenna array, highlighting the emergence of a generalized Kerker effect due to multipole scattering compensation. The well-pronounced and optically responsive collective multipole resonances in nanostructured MXene enable metasurfaces with broad bandwidth absorption, using its large permittivity and scattering enhancement to improve light conversion efficiency in large-scale energy-harvesting systems.

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Optical Processes behind Plasmonic Applications

Cited by 29 publications

References 154 publications

Effects of thickness and roughness on plasmonic characteristics of gold thin films deposited on polished optical fiber

Effects of thickness and roughness on plasmonic characteristics of gold thin films deposited on polished optical fiber

Comparing amplitude-based and phase-based quantum plasmonic biosensing

Multipole Mie Resonances in MXene-Antenna Arrays

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