Add to ORKGThis dissertation provides a comprehensive study of non-Hermitian systems and applications. The coupling phenomena occur in three-dimensional plasmonic nanostructure lead to a peculiar spectral response. Modification of near-field coupling in nanorod pairs enables to invert plasmon hybridization scheme, which offers engineering resonance. The first half of this dissertation investigates the optical properties of the plasmon hybridization system based on the multilayered structure. The proposed hybridized sensing platforms can improve sensing capabilities than a standard single plasmonic resonance system. In the second half of this dissertation, we propose a novel approach to exceptional points (EPs) where eigenvalues and eigenvectors coales...
The field of nanophotonics has realized rapid growth over the past several decades, as novel nanosca...
Plasmon hybridization between closely spaced nanoparticles yields new hybrid modes not found in indi...
Here, we examine the electromagnetic (EM) energy coupling and hybridization of plasmon resonances be...
This dissertation provides a comprehensive study of non-Hermitian systems and applications. The coup...
We investigate theoretically and experimentally the structure of plasmonic modes in individual asymm...
The interaction between light and matter (an atom or a molecule) is generally weak, while the abilit...
Plasmonics can bind light to their surface while increasing its intensity. The confinement and enhan...
The strong coupling between planar arrays of gold and silver nanoparticles mediated by a near-field ...
Controlling the hybridization is a very powerful tool to manipulate the modes in a single nanostruct...
The following dissertation focuses on a new class of devices based on singularities of non-Hermitian...
Surface plasmons are elementary excitations of the collective and coherent oscillations of conductiv...
Localized surface plasmons are collective electron oscillations in metallic nanostructures at optica...
Metallic nanostructures support resonant oscillations of their conduction band electrons called loca...
Electromagnetic interactions in nanoscale systems are a driving force of research in the field of na...
Controllable manipulation of light propagation on nanostructured plasmonic materials paves the way t...
The field of nanophotonics has realized rapid growth over the past several decades, as novel nanosca...
Plasmon hybridization between closely spaced nanoparticles yields new hybrid modes not found in indi...
Here, we examine the electromagnetic (EM) energy coupling and hybridization of plasmon resonances be...
This dissertation provides a comprehensive study of non-Hermitian systems and applications. The coup...
We investigate theoretically and experimentally the structure of plasmonic modes in individual asymm...
The interaction between light and matter (an atom or a molecule) is generally weak, while the abilit...
Plasmonics can bind light to their surface while increasing its intensity. The confinement and enhan...
The strong coupling between planar arrays of gold and silver nanoparticles mediated by a near-field ...
Controlling the hybridization is a very powerful tool to manipulate the modes in a single nanostruct...
The following dissertation focuses on a new class of devices based on singularities of non-Hermitian...
Surface plasmons are elementary excitations of the collective and coherent oscillations of conductiv...
Localized surface plasmons are collective electron oscillations in metallic nanostructures at optica...
Metallic nanostructures support resonant oscillations of their conduction band electrons called loca...
Electromagnetic interactions in nanoscale systems are a driving force of research in the field of na...
Controllable manipulation of light propagation on nanostructured plasmonic materials paves the way t...
The field of nanophotonics has realized rapid growth over the past several decades, as novel nanosca...
Plasmon hybridization between closely spaced nanoparticles yields new hybrid modes not found in indi...
Here, we examine the electromagnetic (EM) energy coupling and hybridization of plasmon resonances be...