Mesostructured materials for optical applications: from low-k dielectrics to sensors and lasers

Recent advances on the use of mesoporous and mesostructured materials for e lectronic and optical applications are reported. The focus is on materials which are processed by block-copolymer templating of silica under weakly ac idic conditions and by employing dip- and spin-coating as well as soft lith ographic methods to bring them into a well-defined macroscopic shape. Sever al chemical strategies allow the mesostructure architecture to be used for electronic/optical applications: Removal of the block-copolymers results in highly porous, mechanically and thermally robust materials which are promi sing candidates for low dielectric constant materials. Since the pores are easily accessible, these structures are also ideal hosts for optical sensor s, when suitable are incorporated during synthesis. For example, a fast res ponse optical pH sensor was implemented on this principle. As-synthesized m esostructured silica/block-copolymer composites, on the other hand, are exc ellently suited as host systems for laser dyes and photochromic molecules, Laser dyes like rhodamine 6G can be incorporated during synthesis in high c oncentrations with reduced dimerization. This leads to very-low-threshold l aser materials which also show a good photostability of the occluded dye. I n the case of photochromic molecules, the inorganic-organic nanoseparation enables a fast switching between the colorless and colored form of a spiroo xazine molecule, attributed to a partitioning of the dye between the block- copolymer chains. The spectroscopic properties of these dye-doped nanocompo site materials suggest a silica/block-copolymer/dye co-assembly process, wh ereby the block-copolymers help to highly disperse the organic dye molecule s. (C) 2001 Elsevier Science B.V. All rights reserved.