Journal
CHIMIA
Volume 56, Issue 10, Pages 527-542Publisher
SWISS CHEMICAL SOC
DOI: 10.2533/000942902777680207
Keywords
biopattern; elastomeric; electroless; flexography; high resolution; light stamp; microcontact print; microfluidic; mold; nanopattern; PDMS; soft lithography
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We are developing a high-resolution printing technique based on transferring a pattern from an elastomeric stamp to a solid substrate by conformal contact. This is an attempt to enhance the accuracy of classical printing to et precision comparable with optical lithography, creating a low-cost, large-area, high-resolution patterning process. First, we introduce the components of this technique, called soft lithography, and review its evolution. Topics described in detail are the stamp material, stamp architecture, pattern design rules, and printing tools. The accuracy of the prints made by thin patterned elastomeric layers supported on a stiff and flexible backplane is then assessed, and defects are characterized using a new electrical metrology approach. This is followed by a discussion of various printing processes used in our laboratory: (1) thiol printing for high-resolution patterns of noble metals that may also be used as sacrificial masks; (2) confined contact processing with liquids in cavities or channels to chemically convert a substrate or deposit layers of materials or biornolecules; (3) printing of catalysts to mediate patterned deposition of metals; and (4) structured, light-guiding stamps for transferring high-resolution patterns into photoresists. Finally, we compare classical and high-resolution printing approaches, and describe their potential for emerging micro- and nanoscale patterning technologies.
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