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Research Papers

Three-Dimensional Compatible Sacrificial Nanoimprint Lithography for Tuning the Wettability of Thermoplastic Materials

[+] Author and Article Information
Molla Hasan, Imrhankhan Shahjahan

Department of Mechanical and
Aerospace Engineering,
Rutgers University,
Piscataway, NJ 08854

Manesh Gopinadhan

Department of Chemical and Environmental
Engineering,
Yale University,
New Haven, CT 06520

Jittisa Ketkaew, Jan Schroers

Department of Mechanical Engineering and
Materials Science,
Yale University,
New Haven, CT 06520

Aaron Anesgart, Chloe Cho, Saransh Chopra, Michael Higgins, Saira Reyes

New Jersey Governor's School of Engineering
and Technology,
Rutgers University,
Piscataway, NJ 08854

Chinedum O. Osuji

Department of Chemical and Environmental
Engineering,
Yale University,
New Haven, CT 06520;
Department of Chemical and Environmental
Engineering,
University of Pennsylvania,
Philadelphia, PA 19104

Jonathan P. Singer

Department of Mechanical and
Aerospace Engineering,
Rutgers University,
98 Brett Road,
Piscataway, NJ 08854
e-mail: jonathan.singer@rutgers.edu

1Corresponding author.

Contributed by the Manufacturing Engineering Division of ASME for publication in the JOURNAL OF MICRO-AND NANO-MANUFACTURING. Manuscript received August 6, 2018; final manuscript received September 16, 2018; published online October 16, 2018. Editor: Nicholas Fang.

J. Micro Nano-Manuf 6(4), 041003 (Oct 16, 2018) (8 pages) Paper No: JMNM-18-1027; doi: 10.1115/1.4041532 History: Received August 06, 2018; Revised September 16, 2018

We report the tuning of surface wetting through sacrificial nanoimprint lithography (SNIL). In this process, grown ZnO nanomaterials are transferred by imprint into a metallic glass (MG) and an elastomeric material, and then etched to impart controlled surface roughness. This process increases the hydrophilicity and hydrophobicity of both surfaces, the Pt57.5Cu14.7Ni5.3P22.5 MG and thermoplastic elastomer (TPE), respectively. The growth conditions of the ZnO change the characteristic length scale of the roughness, which in turn alters the properties of the patterned surface. The novelty of this approach includes reusability of templates and that it is able to create superhydrophilic and superhydrophobic surfaces in a manner compatible with the fabrication of macroscopic three-dimensional (3D) parts. Because the wettability is achieved by only modifying topography, without using any chemical surface modifiers, the prepared surfaces are relatively more durable.

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Figures

Grahic Jump Location
Fig. 1

Synthesis of ZnO nanostructures on aluminum template. (a) Schematic illustration of hydrothermal synthesis steps. The vial containing growth solution and aluminum template (attached with glass slide) was held at 90 °C. (b) SEM images of the aluminum template: (i) bare surface (scale bar 50 μm), (ii) after growing the ZnO nanostructures (scale bars 50 μm and 2 μm), (iii) after etching away the nanostructures (scale bar 100 μm, inset scale bar 5 μm), and (iv) after regrowing the ZnO nanostructures (scale bars 10 μm and 2 μm).

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Fig. 2

Modifying the topography of TPE. (a) Schematic illustration of nanoimprinting. To imprint, both the template and the TPE were heated at 120 °C (which is 10 °C above the Tg of TPE) and pressed. ZnO nanostructures embedded in the TPE broke during demolding at room temperature. The broken nanostructures were removed through etching. (b) SEM images of TPE (Kraton) (i) of a bare surface, (ii) after embossing, and (ii) after etching. (c) SEM images of Pt-MG (i) of flat surface, (ii) after embossing, and (iii) after etching.

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Fig. 3

Water CA alteration by sacrificial templating with different characteristic scales for both pore-like (i) and (ii) and pillar-like (iii) and (iv) geometries. Scale bars in (i) and (iii) are 500 nm and scale bars in (ii) and (iv) are 2 μm.

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Fig. 4

Tuning the surface wettability of TPE. (a) SEM image of aluminum templates with ZnO nanostructures. The growth and density of the nanostructures are varied with the immersion time. (b) SEM images of flat and nanoimprinted TPEs and corresponding CA measurements. Scale bar is 2 μm. (c) Effect of pretreatment of aluminum template on the wettability of TPE. The CAs measurement error is ±5 deg.

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Fig. 5

Superhydrophobic 3D TPE. (a) The aluminum mold for 3D imprinting. (b) Photographs of water droplets on the different faces of the superhydrophobic 3D part. ((c)–(g)) Water droplets on different faces of TPE. (h) Table of CAs of different faces. ((i)–(j)) water droplets rest on vertical and flipped TPE surfaces. ((k)–(m)) Optical images of water droplets on a patterned TPE substrate in flat, bent, and twisted conformations. CA measurement error is ±5 deg.

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