Article ID Journal Published Year Pages File Type
1441841 Synthetic Metals 2012 6 Pages PDF
Abstract

By simply changing the concentration of aniline ([An]) and the molar ratio of dichloroacetic acid (DCA) to aniline ([DCA]/[An]), the polyaniline (PANI) nanostructures with different morphologies including 1D-nanotubes, 2D-nanoflakes, 3D-nanofiber networks and microspheres were obtained through a self-assembly process, respectively. It was found that morphological changes were closely related to DCA used as reaction media and [DCA]/[An], and also affected by the pH and temperature of reaction system. The strong hydrogen bonding effect of the two chlorine groups and one carboxyl group of DCA with the amine/imine groups of aniline/polyaniline might be a driving force for the self-assembling nanostructures. Spectral study indicated that phenazine-like units could be obtained in the early reaction state under different [DCA]/[An] ratios, which could be responsible for the formation of nanofiber networks and microspheres at an acidic medium of pH < 1.

Graphical abstractPolyaniline nanostructures with different morphologies including 1D-nanotubes, 2D-nanoflakes, 3D-nanofiber networks and microspheres through a self-assembly process only using dichloroacetic acid.Figure optionsDownload full-size imageDownload as PowerPoint slideHighlights► We obtained four different polyaniline nanostructures through a self-assembly process only using dichloroacetic acid. ► Morphologies of polyaniline changed from 1D-nanotubes, to 2D-nanoflakes, to 3D-nanofiber networks and microspheres. ► In the strong acidic condition of pH < 1, we obtained the junctional nanofiber networks and the microspheres of polyaniline. ► The formation of these morphologies was considered to be the result of forming strong hydrogen bonding effect. ► Phenazine-like units could be responsible for the formation of nanofiber networks and microspheres.

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Physical Sciences and Engineering Materials Science Biomaterials
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