Litcius/Paper detail

Study of Micro- and Nanopatterned Aluminum Surfaces Using Different Microfabrication Processes for Water Management

Kirill Misiiuk, Sam Lowrey, Richard J. Blaikie, Josselin Juras, Andrew D. Sommers

2022Langmuir18 citationsDOI

Abstract

Superhydrophobic surfaces demonstrate extreme water-repellence, promoting drop-wise over film-wise condensation, increasing liquid mobility, and reducing thermal resistance for heat-exchanger applications. Introducing topographic structures can lead to modified surface free energy, as inspired by natural systems like the lotus leaf, potentially allowing coating-free ice- and frost-free surfaces under certain conditions. This work presents a study of coating-free aluminum micro/nanopatterns fabricated using micromilling or laser-etching techniques and the resultant wetting properties. Our review and experiments clarify the roles of line-edge-roughness and microstructural geometry from each microfabrication technique, which manifests in technique-specific nano- to midmicro-scale roughness, producing a hierarchical structure in both cases. For micromilling, line-edge-roughness consists of jagged burrs of 1-8 μm thickness with 10-25 μm periodicity along the microlines with constantly changing height on the order of 1-20 μm. These effects simultaneously raise the water contact angle from 52° (unprocessed aluminum) up to 136° but with strong edge pinning effects. On the other hand, laser-etched surfaces exhibit line-edge-roughness with a microstructure of 3-20 μm width and 5-10 μm in height superimposed with evenly spread spikes of 50-250 nm. This results in a high contact angle (>150°) coupled with a low contact angle hysteresis (<15°), promoting superhydrophobicity on a coating-free aluminum surface. It is also shown that for certain cases, line-edge-roughness is more important for the resultant wetting properties than the structure geometry.

Topics & Concepts

Materials scienceWettingContact angleSurface finishSurface roughnessComposite materialCoatingMicrofabricationMicrostructureLotus effectAluminiumNanotechnologyMedicinePathologyFabricationOrganic chemistryChemistryRaw materialAlternative medicineSurface Modification and SuperhydrophobicityAdhesion, Friction, and Surface InteractionsFluid Dynamics and Heat Transfer