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Molecular template approach for evolution of conducting polymer nanostructures: Tracing the role of morphology on conductivity and solid state ordering

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dc.contributor.author Jinish Antony, M
dc.contributor.author Jayakannan, M
dc.date.accessioned 2013-11-22T08:53:49Z
dc.date.available 2013-11-22T08:53:49Z
dc.date.issued 2011
dc.identifier.citation Journal of Physical Chemistry B: 114(3):1314-1324;28 Jan 2010 en_US
dc.identifier.issn 1520-6106
dc.identifier.uri http://ir.niist.res.in:8080/jspui/handle/123456789/820
dc.description.abstract Here, we report a unique molecular template approach, for the first time, to Study the evolution of the different types of nanomaterial morphologies Such as nanofiber, nanorod, nanosphere, and nanotube in a single system without changing their chemical composition or polymerization route. A renewable resource surfactant was self-organized with aniline (95%) and pyrrole (5%) in water to produce white emulsion consisting of long-range cylindrical micellar aggregates. The dilution of the emulsion with water resulted in file transformation of cylindrical to vesicular aggregates Without any, phase separation. The size and shape of the cylindrical and vesicular template aggregates were confirmed by dynamic light scattering and electron microscopic analysis. The chemical oxidation of file cylindrical templates produced nanofibers and nanorods, whereas hollow spheres and 11, nanotubes were produced by vesicular templates. The nanofibers were found as long as 4-5 mu m length with 200 nm widths, whereas the nanorods were shorter in length (0.5-0.7 mu m) with 80-120 nm diameters. The hollow spheres were obtained in I mu m diameter with wall thickness of similar to 80 nm. The length of the nanotubes was found to vary from 1.2 to 1.8 mu m. The average wall thickness and inner pore diameter of the nanotubes were found as similar to 30 nm and similar to 60 nm, respectively. The size and shape of the template aggregates match very well with that of the synthesized nanomaterials and provide direct evidence for the template-assisted evolution of the nanostructure morphology. NMR, FT-IR and UV-visible spectroscopies were utilized to confirm the structure and electronic properties of the nanomaterials. Wide angle X-ray diffraction and transmission electron microscopy-electron diffraction analysis revealed that the nanotubes possessed three-dimensional lamellar-type solid states ordering with high percent crystallinity up to 60%. Variable temperature four-probe conductivity measurements of all samples showed typical I-V plots. The conductivity of the nanofibers was found one order higher than that of nanorod, hollow sphere, and nanotubes at all temperatures. The present investigation enabled LIS to establish the role of various types of nanomorphologies on properties of nanomaterials such as conductivity and solid state ordering without change in their chemical composition. en_US
dc.language.iso en en_US
dc.publisher American Chemical Society en_US
dc.subject Polypyrrole en_US
dc.subject X-Ray en_US
dc.subject Pyrrole copolymer en_US
dc.subject Chemical-Synthesis en_US
dc.subject Sulfonic-Acid en_US
dc.subject Facile synthesis en_US
dc.subject Electrical-Conductivity en_US
dc.subject Polyaniline nanofibers en_US
dc.subject High-yield synthesis en_US
dc.subject Self-assembly method en_US
dc.title Molecular template approach for evolution of conducting polymer nanostructures: Tracing the role of morphology on conductivity and solid state ordering en_US
dc.type Article en_US


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