Stimuli-responsive nanostructured surfaces

The coupling of stimuli-responsive macromolecules to nanostructured surfaces opens the perspective for the fabrication and integration of "smart" micro- and nano-electro-mechanical systems (MEMS&NEMS) in which the smallest motile unit is the polymeric chain. The goal of this work was to develop thermoresponsive, durable nanoporous surfaces as a first step toward the fabrication of functional nanocontainers and nanovalves. The proposed strategy involves in a first step the design and implementation of a clean-room compatible, reproducible and up-scalable method for defining organized nanoporous arrays in MEMS compatible surfaces, such as silicon, silicon oxide and silicon nitride. The main objective of the second step was the covalent immobilization of responsive macromolecules on the obtained structures, as to provide the later with a "smart" behavior. The nanostructuring step was realized by block-copolymer assisted lithography. This newly developed technique enables the definition of nanoscale features on semiconductor substrates over large surface areas and in a cost effective manner. A novel method for patterning thin metal films by a lift-off approach, using spin coated block-copolymer micelles monolayers as a template, was investigated. The obtained nanoporous mask was used as resist for the structuring of hard substrates in plasma-assisted processes and structures with aspect ratios as high as 1:10 were be obtained. By using different block-copolymer micelles and spin-coating conditions, the proposed approach enables the variation of the nanopores' diameter from 40 to 80 nm and a surface coverage between 11.7% and 25.5 % in an independent manner. This technique was successfully integrated in a standard microfabrication process for the batch production of thin nanoporous silicon nitride membranes. The 100 nm thick membranes span over thousands of square micrometers and present porosities higher than 109 pores/cm2. They are thus competitive in terms of porosity with the commercially available polymeric membranes. In addition they are two orders of magnitude thinner than polymeric membranes, this making them extremely interesting for applications where permeation rate or response time is important. The rapid flow of water soluble small molecular species through the nanopores was demonstrated in a qualitative manner in this work. Another series of investigations targeted the functionalization of the available nanoporous surfaces with responsive molecules. Poly(N-isopropyl acrylamide) (PNIPAAM) was chosen as a model system. Its coupling to silicon surfaces by a "grafting-to" approach from melt, using an epoxy-functionalized silane as anchoring layer was studied. The analysis of the yielded grafting density showed results superior to those obtained by classic grafting-to approaches. The relation between the polymer's weight and its responsiveness was investigated in liquid media by atomic force microscopy and by dynamic force spectroscopy. Polym