Simulation methods for multiperiodic and aperiodic nanostructured dielectric waveguides

Autor: Moritz Paulsen, Sabrina Jahns, Martina Gerken, Jost Adam, Lars Thorben Neustock
Rok vydání: 2016
Předmět:
multiperiodic
Fabrication
Materials science
Fibonacci number
ddc:621.3
Technische Fakultät
Binary number
Physics::Optics
02 engineering and technology
simulation methods
01 natural sciences
Spectral line
Article
010309 optics
Deterministic aperiodic nanostructures
Optics
waveguide gratings
0103 physical sciences
ddc:6
finite elements method
Electrical and Electronic Engineering
simulation methods
finite elements method
rigorous coupled wave analysis
waveguide gratings
aperiodic
multiperiodic
business.industry
Faculty of Engineering
Finite-difference time-domain method
article
021001 nanoscience & nanotechnology
aperiodic
Finite element method
Atomic and Molecular Physics
and Optics
Electronic
Optical and Magnetic Materials
Transmission (telecommunications)
Aperiodic graph
rigorous coupled wave analysis
Optoelectronics
0210 nano-technology
business
Waveoptic simulations
Waveguide gratings
Zdroj: Optical and Quantum Electronics.-New York City : Springer US; 2017.-S.1-14.
University of Southern Denmark
Optical and Quantum Electronics
Paulsen, M, Neustock, L T, Jahns, S, Adam, J & Gerken, M 2016, ' Simulation Methods for Multiperiodic and Aperiodic Nanostructured Dielectric Waveguides ', 24th International Workshop on Optical Wave and Waveguide Theory and Numerical Modelling, Warsaw, Poland, 20/05/2016-21/05/2016 .
Paulsen, M, Neustock, L T, Jahns, S, Adam, J & Gerken, M 2017, ' Simulation methods for multiperiodic and aperiodic nanostructured dielectric waveguides ', Optical and Quantum Electronics, vol. 49, no. 107 . https://doi.org/10.1007/s11082-017-0918-6
ISSN: 0306-8919
DOI: 10.1007/s11082-017-0918-6
Popis: Nanostructured dielectric waveguides are of high interest for biosensing applications, light emitting devices as well as solar cells. Multiperiodic and aperiodic nanostructures allow for custom-designed spectral properties as well as near-field characteristics with localized modes [1-4]. Here, a comparison of experimental results and simulation results obtained with different simulation methods is presented. We fabricated and characterized multiperiodic nanostructured dielectric waveguides with two, three, and four compound grating periods as well as aperiodic nanostructured waveguides based on Rudin-Shapiro, Fibonacci, and Thue-Morse binary sequences. The near-field and far-field properties are calculated employing the finite-element method (FEM), the finite- difference time-domain (FDTD) method as well as a rigorous coupled wave algorithm (RCWA). References[1] S. V. Boriskina, A. Gopinath, L. Dal Negro, Optical gap formation and localization properties of optical modes in deterministic aperiodic photonic structures, Opt. Express 16, 18813, 2008[2] E. Maciá, Exploiting aperiodic designs in nanophotonic devices, Rep Prog Phys 75, 036502,2012[3] C. Kluge, J. Adam, N. Barié, P. J. Jakobs, M. Guttmann, M. Gerken, Multiperiodic nanostructuresfor photon control, Opt. Express 22, A1363-A1371, 2014[4] L. T. Neustock, S. Jahns, J. Adam, M. Gerken, Optical waveguides with compound grating nanostructures for refractive index sensing, J. of Sensors, 6174527, 2016
Databáze: OpenAIRE
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