PATTERN TRANSFER - SELF-ASSEMBLED MONOLAYERS AS ULTRATHIN RESISTS

This review includes three sections: (i) preparation, structure, and p roperties of self-assembled monolayers (SAMs); (ii) techniques for pat terning SAMs, including microcontact printing (mu CP), UV-photolithogr aphy, and e-beam writing; and (iii) use of patterned SAMs as ultrathin resists (2-3 nm thick) in processes for pattern transfer based on sel ective chemical etching and selective deposition. Microcontact printin g is a non-lithographic technique for forming patterned features with dimensions greater than or equal to 100 nm; the initial product of pat terning is organized monolayers of alkanethiolates on Au, Ag, Cu and G aAs, and of alkylsiloxanes on Si/SiO2 and glass. In this technique, an elastomeric stamp having a surface patterned with a relief structure is used to generate patterned SAMs on the surfaces of solid materials. These patterned SAMs are resists that protect the underlying substrat es from dissolution in selective etchants(for example, for evaporated thin films of Au and Ag, aqueous solutions of K2S2O3, K3Fe(CN)(6) and K4Fe(CN)(6)). Patterned structures of gold or silver that are produced by the combination of mu CP and selective etching can be used as the secondary masks for subsequent processes such as isotropic etching of SiO2, isotropic or anisotropic etching of Si, anisotropic etching of G aAs, and reactive ion etching (RIE) of Si. Patterned SAMs can also be used as templates for selective deposition of metals by chemical vapor deposition (CVD), electroplating, or electroless deposition.