Abstract
We present a comprehensive experimental study on laser-induced hierarchic nano-micro periodic surface structures on brass that influences wetting behavior. Using ultra short laser pulses with a wavelength of 1030 nm, large scaled areas completely covered by laser-induced periodic surface structures (LIPSS) are generated with these areas being superimposed by ablation trenches and u-ripples. The influence of the incident laser fluence and pulse overlap on the apparent contact angle for coverage of the surface with distilled water with a surface tension of 74 mN/m are examined with its temporal evolution being observed over a period of two weeks. Our results show an initial drop in the apparent contact angle below the angle of an unstructured surface. Using atomic force microscopy, the roughness factor described by the Wenzel model is determined and compared to the roughness factor given by the apparent contact angle measurement. The ascertained difference in roughness cannot be entirely attributed to the topography of the laser-structured surface. We suggest that changes in the surface chemistry additionally alter the wetting behavior as confirmed by X-ray photoelectron spectroscopy (XPS) measurements. On a time scale of days after laser irradiation, the apparent contact angle increases into the hydrophobic range. Both the absolute apparent contact angle and this temporal change reveal a pronounced dependence on the applied laser fluence and pulse overlap. In particular, increasing both, the fluence and the pulse overlap leads to smaller apparent contact angles directly after the irradiation and to higher apparent contact angles after an observation period of two weeks.
Highlights
Over the last decade, the increased commercial availability of industrial grade ultra short pulsed laser systems has fostered many applications of this innovative laser source
Our results imply that the change in wetting behavior cannot entirely be attributed to the laser-induced changes in the topography, and we suggest that changes in the surface element concentration alter the wetting behavior, namely, by an increase in the oxygen concentration and a change in the concentration ratio between carbon and tin/copper, as confirmed by X-ray photoelectron spectroscopy (XPS) measurements of unstructured reference samples and laser-structured specimens
Using infrared femtosecond laser pulses, large scaled areas completely covered by highly uniformed laser-induced periodic surface structures (LIPSS) were generated on brass, with these nanostructures being superimposed by microscopic laser ablation trenches and u-ripples
Summary
The increased commercial availability of industrial grade ultra short pulsed laser systems has fostered many applications of this innovative laser source. Whereas the apparent contact angle initially reveals a pronounced drop as compared to unstructured brass, it increases into the hydrophobic regime and saturates over several days This temporal evolution has already been shown for several metallic surfaces after femtosecond-based laser structuring [17,25,26,27,28] and is mainly described by a highly chemical reactive surface direct after laser treatment and a growing passive hydrophobic layer rich on carbon from the composition of CO2 [29]. Both the initial drop and the subsequent increase reveal a strong dependence on pulse overlap and laser fluence. The results can help to implement hierarchic nano and micro structures into surface engineering approaches
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