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Issue 4, 2010
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“Smart” polymeric microfluidics fabricated by plasma processing: controlled wetting, capillary filling and hydrophobic valving

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Abstract

We demonstrate a mass-production-amenable technology for fabrication, surface modification and multifunction integration in polymeric microfluidic devices, namely direct lithography on the polymeric substrate followed by polymer plasma etching, and selective plasma deposition. We apply the plasma processing technology to fabricate polymeric microfluidics in poly(methyl methacrylate) (PMMA) and poly(ether ether ketone) (PEEK). First, deep anisotropic O2 plasma etching is utilized to pattern the polymer via an in situ, highly etch-resistant, thin, Si-containing photoresist, or via a thick organic photoresist. Absolute control of surface roughness (from smooth to very rough), and the production of stable-in-time (slowly ageing) superhydrophilic microchannels are demonstrated. Second, we demonstrate the spontaneous capillary pumping through such rough, superhydrophilic plasma-etched microchannels in contrast to smooth ones, even 5 weeks after fabrication. Third, by using C4F8 fluorocarbon plasma deposition through a stencil mask, we produce superhydrophobic patches inside the microchannels, and use them as passive valves. Our approach proposes “smart” multifunctional microfluidics fabricated by a plasma technology toolbox.

Graphical abstract: “Smart” polymeric microfluidics fabricated by plasma processing: controlled wetting, capillary filling and hydrophobic valving

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Publication details

The article was received on 11 Aug 2009, accepted on 28 Oct 2009 and first published on 30 Nov 2009


Article type: Paper
DOI: 10.1039/B916566E
Citation: Lab Chip, 2010,10, 462-469
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    “Smart” polymeric microfluidics fabricated by plasma processing: controlled wetting, capillary filling and hydrophobic valving

    K. Tsougeni, D. Papageorgiou, A. Tserepi and E. Gogolides, Lab Chip, 2010, 10, 462
    DOI: 10.1039/B916566E

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