Abstract
Hierarchical surface structures were fabricated on fused silica by using a fs-laser with a pulse duration τ = 300 fs and a wavelength λ = 512 nm. The resulting surface structures were characterized by scanning electron microscopy, atomic force microscopy and white light interference microscopy. The optical properties were analyzed by transmittance measurements using an integrating sphere and the wettability was evaluated by measuring the water contact angle θ. The silanization of structured fused silica surfaces with trichloro(1H,1H,2H,2H-perfluorooctyl)silane allows to switch the wettability from superhydrophilic (θ = 0°) to superhydrophobic behavior with θ exceeding 150°. It was shown that the structured silica surfaces are a suitable master for negative replica casting and that the hierarchical structures can be transferred to polystyrene. The transmittance of structured fused silica surfaces decreases only slightly when compared to unstructured surfaces, which results in high transparency of the structured samples. Our findings facilitate the fabrication of transparent glass samples with tailored wettability. This might be of particular interest for applications in the fields of optics, microfluidics, and biomaterials.
Highlights
Multifunctional surfaces consisting of hierarchical micro- and nanostructures are provided and optimized by nature for a wide range of requirements [1]
The topography of the laser structured fused silica surfaces remained intact even with repeated replica casting and allows multiple usage. These findings demonstrate the ability to transfer the specific hierarchical surface structures fabricated by fs-laser processing on fused silica to polystyrene, which allows engineering polymer surfaces with this kind of tailored surface structures
The results reveal that the wettability of silica surfaces can be tailored in the full range of superhydrophilic and superhydrophobic behavior by adjusting their surface roughness and chemistry
Summary
Multifunctional surfaces consisting of hierarchical micro- and nanostructures are provided and optimized by nature for a wide range of requirements [1]. Biological systems stimulated intense research aiming on the transfer of nature’s functional principles to technical applications For this purpose, different techniques like replica casting of natural surfaces [6], nanolithography [7,8,9], chemical etching [10], deposition of nanoparticles on surfaces [11,12], and ultra-short pulsed laser processing [1,13,14] have been investigated. Fs-lasers allow the generation of so-called laser-induced periodic surface structures (LIPSS) Since their first observation by Birnbaum in 1965 [18], LIPSS were intensively investigated in order to unveil their formation process as well as the dependence of influencing parameters [1,15,16,17,19,20,21,22,23,24,25,26]. The first ones that arise below the ablation threshold, have a period much smaller than
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