Simple Photografting Method to Chemically Modify and Micropattern the Surface of SU-8 Photoresist

Wang, Yuli; Bachman, Mark; Sims, Christopher E.; Li, G. P.; Allbritton, Nancy L.

doi:10.1021/la053188e

Cited by 66 publications

(78 citation statements)

References 38 publications

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“…In particular, for applications such as microsensing, or DNA array technology, the specificity can be enhanced by functional chemical groups, [29] by means of silanization after wet chemical modification, [2,30,31] by direct covalent attachment, [32] or by UVactivated linking. [6,33] The surface chemistry of SU-8 can also be modified by a two-step process employing CAN and polyacrylic acid to enhance cell attachment. [34] Protein resistance is a surface functionality that is often required in biomicrofluidic devices.…”

Section: Introductionmentioning

confidence: 99%

Surface hydrophilization of SU‐8 by plasma and wet chemical processes

Walther

Drobek

Gigler

et al. 2010

Surface & Interface Analysis

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Wetting properties and surface roughness of SU-8 can be modified by wet chemical and plasma processes. These processes result in an enhanced wettability that can be attributed to an increase of C O and COO groups at the surface. Wet chemical etching with ceric ammonium nitrate (CAN) rendered the SU-8 surface hydrophilic. However, it also led to the accumulation of cerium species on the surface, which may interfere with biochemical reactions in the device. Surface activation could also be achieved with a low-temperature atmospheric argon plasma, which left a smooth surface. Treatment of SU-8 with oxygen plasma led to a stable hydrophilization and an increased surface roughness. Owing to oxygen plasma processing, antimony species were accumulated which could be removed with a cleaning step. In order to maintain the hydrophilization after oxygen plasma treatment for storage, or over several wetting cycles, the surface can be coated with a protein-resistant graft copolymer (PLL-g-PEG).

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Section: Introductionmentioning

confidence: 99%

Surface hydrophilization of SU‐8 by plasma and wet chemical processes

Walther

Drobek

Gigler

et al. 2010

Surface & Interface Analysis

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“…It has been demonstrated that trace amounts of triarylsulfonium hexafluoroantimonate (initiator) which remains within cured SU8 acts as a source of free radicals, initiating UV-mediated grafting of PAA onto the surface of the SU8. [39] Figure 3 illustrates the surface modification, infiltration of the monomer and subsequent polymerization of the acrylic acid in the pores of the SU8 structure. The slow evaporation of the water from inside of open cylindrical micropores causes the swollen PAA network grafted to the pore walls to shrink significantly, resulting in high compressive stresses.…”

Section: Pattern Transformation As a Results Of Mechanical Instabilitiesmentioning

confidence: 99%

Bifurcated Mechanical Behavior of Deformed Periodic Porous Solids

Singamaneni

Bertoldi

Chang

et al. 2009

Adv Funct Materials

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The transformation of periodic microporous structures fabricated by interference lithography followed by their freezing below glass transition is described. Periodic porous microstructures subjected to internal compressive stresses can undergo sudden structural transformation at a critical strain. The pattern transformation of collapsed pores is caused by the stresses originated during the polymerization of acrylic acid (rubbery component) inside of cylindrical pores and the subsequent solvent evaporation in the organized microporous structure. By confining the polymerization of acrylic acid to localized porous areas complex microscopic periodic structures can be obtained. The control over the mechanical instabilities in periodic porous solids at a sub‐micron scale demonstrated here suggests the potential mechanical tunability of photonic, transport, adhesive, and phononic properties of such periodic porous solids.

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“…Water-soluble monomers and other polymers like poly(acrylic acid) have been covalently grafted to SU-8 using UV-mediated grafting and also, chemically micro-patterned [13]. Under controlled conditions, the remainder photo acid generator triarylsulfonium hexafluoroantimonate works as a photo initiator and generates free radicals such as C-OO, C-O, -COOH [13].…”

Section: Boundary Layer Lubricationmentioning

confidence: 99%

SU-8 Composite Based “Lube-tape” for a Wide Range of Tribological Applications

2014

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Abstract:In a previous work, we have developed a perflouropolyether (PFPE) lubricant droplet-filled SU-8 composite which promotes bonding between the molecules of SU-8 and PFPE and provides excellent boundary lubrication. The SU-8 + PFPE composite has enhanced the wear durability of SU-8 by more than four orders of magnitude. In this work, the same SU-8 + PFPE composite was used to fabricate a stand-alone laminate film called "Lube-tape". It has integrated two layers of approximately 90 microns thickness each; the top layer is made of SU-8 + PFPE composite and the bottom layer of pristine SU-8. Thus, a single tape can have drastically contrasting high friction and low friction properties on its two surfaces. The composite side has the initial coefficient of friction ~7 times lower and the wear life more than four orders of magnitude than those of the pristine SU-8 side. This lube tape can be used on any load bearing surface to improve the tribological performance by simply pasting the pristine SU-8 side onto the substrate.

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Simple Photografting Method to Chemically Modify and Micropattern the Surface of SU-8 Photoresist

Cited by 66 publications

References 38 publications

Surface hydrophilization of SU‐8 by plasma and wet chemical processes

Surface hydrophilization of SU‐8 by plasma and wet chemical processes

Bifurcated Mechanical Behavior of Deformed Periodic Porous Solids

SU-8 Composite Based “Lube-tape” for a Wide Range of Tribological Applications

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