Soft lithography
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In technology, soft lithography refers to a set of methods for fabricating or replicating structures using "elastomeric stamps, molds, and conformable photomasks" (in the words of Rogers and Nuzzo, p. 50, as cited in "References"). It is called "soft" because it uses elastomeric materials most notably PDMS. Soft lithography is generally used to construct features measured on the nanometer scale. According to Rogers and Nuzzo (2005), development of soft lithography expanded rapidly during the period 1995 to 2005.
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[edit] Procedure
Soft lithography includes the technologies of Micro Contact Printing (µCP), replica molding (REM), microtransfer molding (µTM), micromolding in capillaries (MIMIC) and solvent-assisted micromolding (SAMIM) (From Xia et al.) Patterning by etching at the nanoscale (PENs) One of the soft lithography procedures, Micro contact printing as discussed by Xia and Whitesides, is as follows:
- The steps of any of your favorite micro- or nano- scale lithography procedures (photolithography, EBL, etc.) are followed to etch a desired pattern onto a substrate (usually silicon)
- Next, the stamp is created by pouring a degassed resin overtop of the etched wafer. Common resins include PDMS and Fluorosilicone.
- Removing the cured resin from the substrate, a stamp contoured to your pattern is acquired.
- The stamp is then "inked" by placing it, pattern-up, in a bath of inking solution (for example, ODT in ethanol) for a short period of time(Figure 1). The ink molecules will fall and adhere to the surface of the stamp (Figure 2) creating a single-molecule layer of the ink on the stamp.
- The inked stamp is then pressed on the substrate and removed, leaving the desired single-molecule thick pattern on the substrate (Figure 3)
- Steps 4 and 5 are repeated for each substrate on which the pattern is desired
[edit] Advantages
Soft lithography has some unique advantages over other forms of lithography (such as photolithography and electron beam lithography). They include the following:
- Lower cost than traditional photolithography in mass production
- Well-suited for applications in biotechnology
- Well-suited for applications in plastic electronics
- Well-suited for applications involving large or nonplanar (nonflat) surfaces
- More pattern-transferring methods than traditional lithography techniques (more "ink" options)
- Does not need a photo-reactive surface to create a nanostructure
- Smaller details than photolithography in laboratory settings (~30nm vs ~100nm). The resolution depends on the mask used and can reach 6 nm[1].
[edit] See also
[edit] References
- Xia, Y. and Whitesides, G. M., (1998) Soft Lithography. In Angew. Chem. Int. Ed. Engl. 37, 551-575.[1]
- Xia, Y. and Whitesides, G. M., (1998) Soft Lithography. In Annu. Rev. Mater. Sci. 28, 153-184.
- Quake, S. R. & Scherer, A. (2000, November 24). From micro- to nanofabrication with soft materials. In Issues in nanotechnology. In Science, 290, 1536 – 1540.
- Rogers, J. A. & Nuzzo, R. G. (2005, February). Recent progress in soft lithography. In Materials today, 8, 50 – 56.
- ^ Waldner, Jean-Baptiste (2008). Nanocomputers and Swarm Intelligence. ISTE John Wiley & Sons, P93. ISBN 1847040020.
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