Abstract
Abstract Using coupled electromagnetic and hydrodynamic calculations, we elucidate theoretically the topographic transition from a random metallic surface to a periodic sub-wavelength grating by ultrashort laser ablation. The origin of this transition lies in the successive selection of hybrid surface waves scattered by random nanoholes. Contrary to the common belief that surface plasmon polaritons play the dominant role in the process and define the grating periodicity, we show that both quasi-cylindrical and surface plasmon waves are involved, whereas the diversity in the resulting spacings λ/2–λ (λ is the laser wavelength) is the manifestation of a broad frequency overlap of these waves, controlled by their relative phase shifts with respect to the plasmonic counterparts. The topography evolution imposes the dominant contribution to the surface sub-wavelength pattern by selecting the appropriate wave character from plasmonic modes to evanescent cylindrical waves. With the radiation dose, the grating periodicity exhibits a pronounced blue shift due to reinforced dipole–dipole coupling between the nanoholes and surface curvatures in the laser-processed area. This allows the creation of regular patterns with tunable periodicity.
Highlights
In spite of the striking differences between the physical concepts, scenarios based on surface plasmon polariton (SPP) excitation were proposed to explain each of the above phenomena
cylindrical wave (CW) were shown to play a significant role in the extraordinary optical transmission through periodic and random nanohole arrays and to contribute to the interaction of light with all-nanostructured metallic surfaces [3, 4, 22, 23]
We show that the electromagnetic origin of laser-induced periodic surface structure (LIPSS) with periodicity λ/2–λ is a process of multipulse selection of hybrid standing waves produced by the interference of the incident light with surface wave scattered by nanoholes with comparable contributions of SPP and CW
Summary
The interaction of light with nanostructures on metal surfaces is at the origin of a large variety of amazing phenomena including extraordinary optical transmission through hole arrays [1,2,3,4], abnormal optical absorption and Wood’s anomalies by diffraction gratings and grooves [5,6,7], enhanced resonant coupling between nanoholes and nanoparticles [8,9,10,11], Anderson localization of light [12, 13], and the self-organization of matter by multipulse laser irradiation [14,15,16,17]. Abstract: Using coupled electromagnetic and hydrodynamic calculations, we elucidate theoretically the topographic transition from a random metallic surface to a periodic sub-wavelength grating by ultrashort laser ablation.
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