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Layer-by-Layer Assembly of Bifunctional Nanofilms: Surface-Functionalized Maghemite Hosted in Polyaniline

This study reports on the pioneering use of the layer-by-layer (LbL) technique to produce multilayered (1 to 50 bilayers) bifunctional nanocomposite films consisting of negatively charged citrate-coated maghemite nanoparticle (cit-MAG) hosted in positively charged conducting polyaniline (doped-PANI)...

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Bibliographic Details
Published in:Journal of physical chemistry. C 2009-04, Vol.113 (13), p.5087-5095
Main Authors: Paterno, Leonardo G, Soler, Maria A. G, Fonseca, Fernando J, Sinnecker, João P, Sinnecker, Elis H. C. P, Lima, Emilia C. D, Novak, Miguel A, Morais, Paulo C
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Language:English
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Summary:This study reports on the pioneering use of the layer-by-layer (LbL) technique to produce multilayered (1 to 50 bilayers) bifunctional nanocomposite films consisting of negatively charged citrate-coated maghemite nanoparticle (cit-MAG) hosted in positively charged conducting polyaniline (doped-PANI). The aim is to use the LbL assembly to fabricate thin nanocomposite films displaying superparamagnetic and conductivity properties and with fine control of the end properties as a function of the preparation condition. Multilayered cit-MAG/PANI bifunctional nanocomposite films were systematically investigated in order to access information regarding the nanofilm structure, electrical conductivity, and magnetic properties. Using the isothermal adsorption of each individual electrolyte (cit-MAG dispersion and doped-PANI solution) onto solid substrates (silicon and glass) the average time for deposition of a single layer (cit-MAG or doped-PANI) was fixed in 3 min. Independent evaluation using UV−vis spectroscopy and atomic force microscopy indicated a linear correlation between the nominal number of adsorbed cit-MAG/PANI bilayers and the material content (film thickness), even for the smallest number of adsorbed bilayers. Values of electrical conductivity (film thickness) found for the 10-bilayered cit-MAG/PANI nanocomposite films were in the range of 10−2−10−4 Scm−1 (25−63 nm) for γ-Fe2O3 concentration within the employed magnetic fluid suspension in the range of 10−4−10−3 g L−1. Values of the blocking temperature obtained from ZFC/FC curves recorded for the nanofilm produced using the highest γ-Fe2O3 concentrated suspension (2 × 10−3 g L−1) monotonically increase from 30 to 40 K as the number of cit-MAG/PANI bilayers increases from 5 to 50 bilayers. Therefore, we found that the end properties can be easily and precisely modulated by varying the concentration of the magnetic fluid used for film deposition and/or controlling the nominal number of cit-MAG/PANI bilayers in the nanocomposite.
ISSN:1932-7447
1932-7455
DOI:10.1021/jp8092463