Nanoantenna Effect
at the Center of the Bull’s
Eye Pattern by Controlling the Refractive Indices and Layer Thicknesses
of Dielectric Media on a Silver Surface
Posted on 2024-02-13 - 08:29
The light that is illuminated on
a silver-film-coating substrate
with a periodic structure, i.e., a plasmonic chip, can couple to plasmon
polaritons and enhance the electric field on the surface of the chip.
Fluorescent molecules fixed to the plasmonic periodic pattern are
excited by an enhanced electric field, enhancing their fluorescence.
Particularly, a bright fluorescence point appears at the center of
a concentric circle pattern called a Bull’s eye pattern. This
nanoantenna effect has been studied in various types of concentric
circles and has been comprehended by a constructive wave superposed
with diffraction light on the grooves of a plasmonic pattern. Here,
the antenna effect of fluorescent nanoparticles immobilized on the
chip surface was studied based on the controlling factors of the surface
plasmon resonance wavelengths, such as the pitch of a pattern, the
refractive index, and the layer thickness of the dielectric media
on the silver film, and it was improved by their factors. The pitches
of the plasmonic patterns were set at 400 and 480 nm, and the nanoantenna
rate (Ap) of the 480 nm pitch was higher than that of the
400 nm pitch when a 20 nm thick SiO2 layer was used. By
changing the refractive index of the dielectric media on the silver
film from 1.45 (silica layer) to 2.10 (zinc oxide layer), Ap increased at a 400 nm pitch. These results were well explained by
a constructive wave that was formed by the superposition of the diffraction
waves on the grooves at the center of the pattern. The most enhanced
antenna effect was found to be obtained by controlling the pitch of
a plasmonic chip as the resonance wavelength is adjusted to the excitation
wavelength. Conversely, the distance from the silver surface was controlled
using silica layer thicknesses of 20 and 80 nm, and Ap increased
remarkably at 480 nm pitch for the 80 nm thick silica layer. This
result was supported by the electric field intensities at the center
and edge calculated by discrete-dipole approximation, revealing that
the distance factor can contribute to the electric field intensities
of propagated waves. The nanoantenna effect could be enhanced by the
pitch and dielectric media prepared on the silver film.
CITE THIS COLLECTION
DataCiteDataCite
3 Biotech3 Biotech
3D Printing in Medicine3D Printing in Medicine
3D Research3D Research
3D-Printed Materials and Systems3D-Printed Materials and Systems
4OR4OR
AAPG BulletinAAPG Bulletin
AAPS OpenAAPS Open
AAPS PharmSciTechAAPS PharmSciTech
Abhandlungen aus dem Mathematischen Seminar der Universität HamburgAbhandlungen aus dem Mathematischen Seminar der Universität Hamburg
ABI Technik (German)ABI Technik (German)
Academic MedicineAcademic Medicine
Academic PediatricsAcademic Pediatrics
Academic PsychiatryAcademic Psychiatry
Academic QuestionsAcademic Questions
Academy of Management DiscoveriesAcademy of Management Discoveries
Academy of Management JournalAcademy of Management Journal
Academy of Management Learning and EducationAcademy of Management Learning and Education
Academy of Management PerspectivesAcademy of Management Perspectives
Academy of Management ProceedingsAcademy of Management Proceedings
Academy of Management ReviewAcademy of Management Review
Tawa, Keiko; Shinohara, Takeha; Nawa, Yasunori; Hasegawa, Seiju; Imura, Kohei (1753). Nanoantenna Effect
at the Center of the Bull’s
Eye Pattern by Controlling the Refractive Indices and Layer Thicknesses
of Dielectric Media on a Silver Surface. ACS Publications. Collection. https://doi.org/10.1021/acs.jpcc.3c07171