"3"^^ . "Numerical modeling of photonic nanojet behind dielectric microcylinder"@en . . . . . "Numerical modeling of photonic nanojet behind dielectric microcylinder" . "We studied the influence of the refractive index contrast, the incident plane wave wavelength and the microcylinder diameter on the position of the maximum of photonic nanojet electric field for microscopy and spectroscopy biomedical applications. The photonic nanojet is a propagative optical feature originating behind micro-sized dielectric sphere or cylinder when it is illuminated by a plane wave. This pheno-menon can potentially break the diffraction limit of microscop-ic methods. Broad range of scientific area could profit from photonic nanojets, especially material sciences, analytical chemistry and biomedical sciences. We can summarize that the distance increases nearly linear-ly with decreasing refractive index and increasing diameter of the cylinder and increases with the wavelength of the illumina-tion. The results can potentially be used for the design of pho-tonic nanojet experiments." . . "Mad\u011Br\u00E1nkov\u00E1, D." . "RIV/68081715:_____/09:00354494!RIV11-GA0-68081715" . . . "VDE Conference Services" . "330225" . "Numerical modeling of photonic nanojet behind dielectric microcylinder"@en . "P(GA203/08/1680), P(GD102/09/H083), Z(AV0Z40310501), Z(MSM0021630513)" . . . . "4"^^ . . . "Klep\u00E1rn\u00EDk, Karel" . . "Provazn\u00EDk, I." . "2009-09-07+02:00"^^ . . "RIV/68081715:_____/09:00354494" . . "[2465385E7D5B]" . "Mnichov" . "Mnichov" . "Numerical modeling of photonic nanojet behind dielectric microcylinder" . "1"^^ . . . "Medical Physics and Biomedical Engineering, World Congress 2009" . . "photonic nanojet; FDTD method"@en . . "We studied the influence of the refractive index contrast, the incident plane wave wavelength and the microcylinder diameter on the position of the maximum of photonic nanojet electric field for microscopy and spectroscopy biomedical applications. The photonic nanojet is a propagative optical feature originating behind micro-sized dielectric sphere or cylinder when it is illuminated by a plane wave. This pheno-menon can potentially break the diffraction limit of microscop-ic methods. Broad range of scientific area could profit from photonic nanojets, especially material sciences, analytical chemistry and biomedical sciences. We can summarize that the distance increases nearly linear-ly with decreasing refractive index and increasing diameter of the cylinder and increases with the wavelength of the illumina-tion. The results can potentially be used for the design of pho-tonic nanojet experiments."@en . "978-3-642-03881-5" .