Coherent Four-Fold Super-Resolution Imaging with Composite Photonic–Plasmonic Structured Illumination. Fernández-Domínguez, A. I., Liu, Z., & Pendry, J. B. ACS Photonics, 2(3):341--348, March, 2015. Paper doi abstract bibtex We present a far-field super-resolution imaging scheme based on coherent scattering under a composite photonic?plasmonic structured illumination. The super-resolved image retrieval method, which involves the combination of 13 different diffraction-limited images of the specimen, is first developed within a Fourier optics framework. A feasible implementation of this optical microscopy technique working at 465 nm is proposed and its point spread function is investigated using full electromagnetics calculations. The 4-fold super-resolution power of the scheme, able to resolve 60 nm feature sizes at the operating wavelength, is demonstrated against both Abbe?s (imaging a single object) and Rayleigh?s (imaging two closely spaced objects) criteria.
@article{fernandez-dominguez_coherent_2015,
title = {Coherent {Four}-{Fold} {Super}-{Resolution} {Imaging} with {Composite} {Photonic}–{Plasmonic} {Structured} {Illumination}},
volume = {2},
url = {http://dx.doi.org/10.1021/ph500342g},
doi = {10.1021/ph500342g},
abstract = {We present a far-field super-resolution imaging scheme based on coherent scattering under a composite photonic?plasmonic structured illumination. The super-resolved image retrieval method, which involves the combination of 13 different diffraction-limited images of the specimen, is first developed within a Fourier optics framework. A feasible implementation of this optical microscopy technique working at 465 nm is proposed and its point spread function is investigated using full electromagnetics calculations. The 4-fold super-resolution power of the scheme, able to resolve 60 nm feature sizes at the operating wavelength, is demonstrated against both Abbe?s (imaging a single object) and Rayleigh?s (imaging two closely spaced objects) criteria.},
number = {3},
urldate = {2016-03-07TZ},
journal = {ACS Photonics},
author = {Fernández-Domínguez, Antonio I. and Liu, Zhaowei and Pendry, John B.},
month = mar,
year = {2015},
pages = {341--348}
}
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