Conference paper
Review of the results of the COST MP0702 exercise on the sensitivity of metal-dielectric layered flat lens to fabrication inaccuracies
University of Warsaw1
National Polytechnic University of Armenia2
National Institute of Telecommunications – the State Research Institute3
Metamaterials, Department of Photonics Engineering, Technical University of Denmark4
Department of Photonics Engineering, Technical University of Denmark5
Vrije Universiteit Brussel6
We summarise the results of the COST MP0702 exercise on the sensitivity of metal-dielectric layered superlens to fabrication inaccuracies. The major results of this joint task have been already published in Ref. 1, Opto- Electronics Review, vol. 18(4), pp. 446-457, 2010. The numerical analysis of the superlens is based on the transfer matrix method, the finite-difference time-domain technique, and the method of single expression, and is compared with a simplified effective medium approach.
The lens is designed for imaging with subwavelength resolution at wavelength of 441 nm. Its operation may be attributed to self-collimation with a secondary role of Fabry-Perot resonant transmission. We have estimated the resolution, transmission efficiency and sensitivity with respect to fabrication inaccuracies of this superlens.
The tolerance analysis indicates that the resolution and transmission efficiency are highly sensitive to even small changes of layer thicknesses.
Language: | English |
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Publisher: | IEEE |
Year: | 2011 |
Pages: | 1-4 |
Proceedings: | 13th International Conference on Transparent Optical Networks (ICTON) |
Series: | International Conference on Transparent Optical Networks |
ISBN: | 1457708809 , 1457708817 , 1457708825 , 9781457708800 , 9781457708817 and 9781457708824 |
ISSN: | 21612064 , 21612056 and 21627339 |
Types: | Conference paper |
DOI: | 10.1109/ICTON.2011.5970809 |
ORCIDs: | Lavrinenko, Andrei |
Effective medium theory Finite-difference time-domain method Multilayers Nanolenses Nanophotonics Plasmonics Single expression method Superresolution Transfer matrix method
COST MP0702 exercise Fabry-Perot resonant transmission Finite difference methods Image resolution Imaging Nonhomogeneous media Optimized production technology Sensitivity Time domain analysis effective medium theory fabrication inaccuracies finite difference time-domain analysis finite-difference time-domain method finite-difference time-domain technique lenses metal-dielectric layered flat lens metal-dielectric layered superlens multilayers nanolenses nanophotonics numerical analysis optical collimators optical design techniques optical fabrication self-collimation single expression method superresolution transfer matrix method wavelength 441 nm