Loading...
Lotus-leaf inspired surfaces: hydrophobicity evolution of replicas due to mechanical cleaning and mold wear
Romano, J.-M. Garcia-Giron, A. Penchev, P. Gülçür, Mert, Whiteside, Benjamin R. Dimov, S.
Romano, J.-M.
Garcia-Giron, A.
Penchev, P.
Gülçür, Mert,
Whiteside, Benjamin R.
Dimov, S.
Publication Date
2020-03
End of Embargo
Supervisor
Rights
© 2020 ASME. Reproduced in accordance with the publisher's self-archiving policy. This manuscript version is made available under the CC-BY distribution license.
Peer-Reviewed
Yes
Open Access status
openAccess
Accepted for publication
2020
Institution
Department
Awarded
Embargo end date
Additional title
Abstract
Inspired from the low wetting properties of Lotus leaves, the fabrication of dual micro/nano-scale topographies is of interest to many applications. In this research, superhydrophobic surfaces are fabricated by a process chain combining ultrashort pulsed laser texturing of steel inserts and injection moulding to produce textured polypropylene parts. This manufacturing route is very promising and could be economically viable for mass production of polymeric parts with superhydrophobic properties. However, surface damages, such as wear and abrasion phenomena, can be detrimental to the attractive wetting properties of replicated textured surfaces. Therefore, the final product lifespan is investigated by employing mechanical cleaning of textured polypropylene surfaces with multipurpose cloths following the ASTM D3450 standard. Secondly, the surface damage of replication masters after 350 injection moulding cycles with glass-fiber reinforced polypropylene, especially to intensify mould wear, was investigated. In both cases, the degradation of the dual-scale surface textures had a clear impact on surface topography of the replicas and thus on their wetting properties, too.
Version
Accepted manuscript
Citation
Romano J-M, Garcia-Giron A, Penchev P et al (2020) Lotus-leaf inspired surfaces: hydrophobicity evolution of replicas due to mechanical cleaning and mold wear. Journal of Micro and Nano-Manufacturing. 8(1): 010913.
Link to publisher’s version
Link to published version
Link to Version of Record
Type
Article