Patterning Inorganic (CaCO3) Thin Films via a Polymer-Induced

The initial pH of the solution was adjusted to between 8 and 8.7 with 0.1 M NaOH. ... used was based on the process first developed by Aizenberg,53 wh...
0 downloads 0 Views 15MB Size
4862

Langmuir 2007, 23, 4862-4870

Patterning Inorganic (CaCO3) Thin Films via a Polymer-Induced Liquid-Precursor Process Yi-Yeoun Kim, Elliot P. Douglas, and Laurie B. Gower* Department of Materials Science and Engineering, UniVersity of Florida, 210A Rhines Hall, P.O. Box 116400, GainesVille, Florida 32611-6400 ReceiVed July 7, 2006. In Final Form: January 18, 2007 The biomimetic synthesis of patterned mineral thin films, based on a combination of the microcontact printing technique and a novel crystallization process called the polymer-induced liquid-precursor (PILP) process, is demonstrated. The PILP process enables the deposition of smooth and continuous calcitic mineral films (up to 1500 nm in thickness) under low-temperature and aqueous-based processing conditions. The films are formed by deposition of colloidal droplets composed of a liquid-phase mineral precursor that is induced by a polymeric process-directing agent (polyaspartate or polyacrylate salts). The droplets can be preferentially deposited onto patterned substrates templated with selfassembled monolayers (SAMs) of alkanethiolate on gold. The droplets coalesce to form an amorphous mineral film, which then transforms (solidifies and crystallizes) while retaining the shape of the patterned template, providing a means for patterning the location and morphology of two-dimensional calcite crystals. A vertical substrate experiment supports the premise that the calcite films are created by adsorption of colloidal droplets from solution, rather than heterogeneous nucleation and growth of an amorphous phase on the SAMs. Large single-crystalline domains, on the order of 50-100 µm, can be “molded” into nonequilibrium morphologies by constraining the mineral precursor to a chemically defined “compartment”. Biominerals are well recognized for their elaborate nonequilibrium molded crystal morphologies, and increasing evidence suggests that many biominerals are formed from an amorphous precursor that is stabilized by polyanionic proteins. The biomimetic system examined here, which consists of a polyanionic process-directing agent in combination with a functionalized organic template, offers a practical tool for generating complex inorganic structures such as those found in biominerals.

Introduction The formation of patterned inorganic thin films under aqueous and ambient conditions may provide a significant advance in a variety of applications such as biosensors, bioMEMS, tissue engineering, and micro/nanocomposites. The successful production of inorganic thin films from aqueous solution at low temperatures (