Publication detail
Simulations of high-Q optical nanocavities with a gradual 1D bandgap
MAES, B. PETRÁČEK, J. BURGER, S. KWIECIEN, P. LUKSCH, J. RICHTER, I.
English title
Simulations of high-Q optical nanocavities with a gradual 1D bandgap
Type
Peer-reviewed article not indexed in WoS or Scopus
Language
en
Original abstract
High-quality cavities in hybrid material systems have various interesting applications. We perform a comprehensive modeling comparison on such a design, where confinement in the III-V material is provided by gradual photonic crystal tuning, a recently proposed method offering strong resonances. The III-V cavity couples to an underlying silicon waveguide. We report on the device properties using four simulation methods: finite-difference time-domain (FDTD), finite-element method (FEM), bidirectional eigenmode propagation (BEP) and aperiodic rigorous coupled wave analysis (aRCWA). We explain the major confinement and coupling effects, consistent with the simulation results. E.g. for strong waveguide coupling, we find quantitative discrepancies between the methods, which establishes the proposed high-index-contrast, lossy, 3D structure as a challenging modeling benchmark.
Keywords in English
Resonators, Photonic integrated circuits, Photonic crystals, Computational electromagnetic methods
Released
2013-03-11
ISSN
1094-4087
Journal
OPTICS EXPRESS
Volume
21
Number
6
Pages from–to
6794–6806
Pages count
13
BIBTEX
@article{BUT98881,
author="Bjorn {Maes} and Jiří {Petráček} and Sven {Burger} and Pavel {Kwiecien} and Jaroslav {Luksch} and Ivan {Richter}",
title="Simulations of high-Q optical nanocavities with a gradual 1D bandgap",
journal="OPTICS EXPRESS",
year="2013",
volume="21",
number="6",
pages="6794--6806",
issn="1094-4087"
}