Multilevel Hierarchical Topographies by Combined Photolithography and Nanoimprinting Processes To Create Surfaces with Controlled Wetting

Multilevel Hierarchical Topographies by Combined Photolithography and Nanoimprinting Processes To Create Surfaces with Controlled Wetting

This work presents a practical methodology to produce multilevel hierarchical structures with precise control of the structural geometry at every level by combining photo and nanoimprint lithography processes. The method involves sequential steps of nanoimprinting of a first deposited polymer layer...

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Bibliographic Details
Published in:ACS applied nano materials Vol. 2; no. 8; pp. 4727 - 4733
Main Authors: Alameda, María T, Osorio, Manuel R, Hernández, Jaime J, Rodríguez, Isabel
Format: Journal Article
Language:English
Published: American Chemical Society 23-08-2019
Subjects:
anisotropic wetting
fractal
bioinspired
hierarchical structure
nanoimprinting lithography
nanofabrication
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Summary:This work presents a practical methodology to produce multilevel hierarchical structures with precise control of the structural geometry at every level by combining photo and nanoimprint lithography processes. The method involves sequential steps of nanoimprinting of a first deposited polymer layer followed by nanoimprinting of a second deposited layer of a photoresin and, afterward, performing on this layer optical lithography by means of a maskless laser writer to pattern micrometer-size features. A hierarchical topography is consequently obtained comprising nanopatterns and micropatterns at different levels designed independently with very high feature control. The process can be repeated sequentially employing hierarchical working molds produced on a previous fabrication cycle to produce multilevel self-similar hierarchical topographies in a sort of fractal growing manner. The patterning method has broad applicability, as exemplary demonstration, superhydrophobicity, and anisotropic wetting behavior are revealed.
ISSN:2574-0970
2574-0970
DOI:10.1021/acsanm.9b00338