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Physics and advanced simulations of photonic and plasmonic structures
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SYSNO ASEP 0436814 Document Type C - Proceedings Paper (int. conf.) R&D Document Type Conference Paper Title Physics and advanced simulations of photonic and plasmonic structures Author(s) Richter, I. (CZ)
Kwiecien, P. (CZ)
Fiala, J. (CZ)
Petráček, J. (CZ)
Eksioglu, Y. (CZ)
Kuzmiak, Vladimír (URE-Y) RID
Čtyroký, Jiří (URE-Y) RIDNumber of authors 7 Source Title Transparent Optical Networks (ICTON), 2014, 16th International Conference on. - Waršava : IEEE, 2014 / Jaworski Marek ; Marciniak Marian - ISSN 2162-7339 - ISBN 978-1-4799-5600-5 Pages s. 6876460 Number of pages 9 s. Publication form Print - P Action 16th International Conference on Transparent Optical Networks, ICTON 2014 Event date 06.07.2014-10.07.2014 VEvent location Graz Country AT - Austria Event type WRD Language eng - English Country PL - Poland Keywords Finite-difference method ; Fourier modal method ; Magnetooptic effect Subject RIV JA - Electronics ; Optoelectronics, Electrical Engineering Institutional support URE-Y - RVO:67985882 EID SCOPUS 84906762038 DOI 10.1109/ICTON.2014.6876460 Annotation In this contribution, we present the main results of our joint scientific theoretical project with the Czech Science Foundation (2010-2013) Physics and advanced simulations of photonic and plasmonic structures, arisen from the cooperation of three laboratories of Czech Technical University in Prague, Institute of Photonics and Electronics of the Academy of Sciences of the Czech Republic, and Brno University of Technology. First, we present the basics of our in-house methods and numerical tools for the analysis of such structures, developed independently within the scope of the project, together with their mutual comparison. Three linear frequency-domain modal three-dimensional (3D) numerical methods developed and adapted for modelling photonic / plasmonic guiding and resonant subwavelength (SW) structures, will be mentioned, namely, aperiodic rigorous coupled-wave analysis (aRCWA) method, bi-directional mode expansion propagation method (BEP) based on the Fourier series (BEX), as well as the finite difference (FD) / finite element (FE)-BEP technique, connecting the eigensolvers with advanced BEP-based scattering matrix algorithm. Subsequently, a special original method suitable for treating nonlinear structures with Kerr nonlinearities, based on the eigenmode expansion (EME), has been developed (NL-EME) and applied, too. These methods, together with several approximate methods, have formed a solid portfolio for subsequent analysis of various photonic and plasmonic subwavelength structures of interest. Workplace Institute of Radio Engineering and Electronics Contact Petr Vacek, vacek@ufe.cz, Tel.: 266 773 413, 266 773 438, 266 773 488 Year of Publishing 2015
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