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Livakas N, Skoulas E, Stratakis E. Omnidirectional iridescence via cylindrically-polarized femtosecond laser processing. Opto-Electron Adv 3, 190035 (2020). doi: 10.29026/oea.2020.190035
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Original Article Open Access
Omnidirectional iridescence via cylindrically-polarized femtosecond laser processing
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Abstract
We report the femtosecond (fs) laser fabrication of biomimetic omnidirectional iridescent metallic surfaces exhibiting efficient diffraction for practically any angle of light incidence. Such diffractive behavior is realized by means of multi-directional low-spatial-frequency, laser-induced periodic surface structures (LSFL) formed upon exploiting the cylindrical symmetry of a cylindrical vector (CV) fs field. We particularly demonstrate that the multi-directional gratings formed on stainless steel surface by a radially polarized fs beam, could mimic the omnidirectional structural coloration properties found in some natural species. Accordingly, the fabricated grating structures can spatially disperse the incident light into individual wavelength with high efficiency, exhibiting structural iridescence at all viewing angles. Analytical calculations using the grating equation reproduced the characteristic variation of the vivid colors observed as a function of incident angle. We envisage that our results will significantly contribute to the development of new photonic and light sensing devices.-
Keywords:
- laser processing /
- structural colors /
- radial polarisation
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References
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Livakas N, Skoulas E, Stratakis E. Omnidirectional iridescence via cylindrically-polarized femtosecond laser processing. Opto-Electron Adv 3, 190035 (2020). doi: 10.29026/oea.2020.190035
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Figure 1.
The experimental setup used for surface structuring.
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Figure 4.
(a) Experimental setup and geometry used for the evaluation of surface diffraction properties. (b) Typical intensity plot of the white light spectrum. (c) Schematic illustration of the structural color monitoring system. (d) The respective coordination parameters.
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Figure 2.
LSFL periodicity dependence on the laser fluence (a), and the effective number of pulses (b), for linearly (squares) and radially (circles) polarized fs beams. Top-view SEM images of areas produced upon irradiation using linearly (c, d) and radially (e, f) polarized fs beams.
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Figure 3.
Top-view SEM images of areas produced upon irradiation using linearly (a–c) and radially (d–f) polarized fs beams.
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Figure 5.
Schematic illustration of the structural colors observed the S1 (a) and the S2 (b) sample series respectively; 2D-FFT patterns corresponding to the S1 (c) and the S2 (e) sample series respectively. The corresponding intensity plots of the 2D-FFT patterns in four different directions (denoted as '1' to '4') are depicted in (d) and (f) respectively.
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Figure 6.
(a) Diffracted colors of S1 surfaces obtained upon irradiation with linearly polarized fs beam. (b) Diffracted colors of S2 surfaces obtained upon irradiation with radially polarized fs beam. Each color is characterized by the coordinates (ω, φ+θ, β), as defined by the optical system used for their monitoring.
