Conducting nanocomposites

Grossiord, N., Loos, J., Regev, O., and Koning, C. E. Toolbox for dispersing carbon nanotubes into polymers to get conductive nanocomposites, Chem. Mater. (2006), 18, 1089-1099. [Pg.291]

Benoit et al. (41) obtained electrically conductive nanocomposites by dispersing SWCNT and PMMA in toluene, followed by drop casting the mixture on substrates. Thin films of SWCNT-PMMA composites for different CNT concentration were produced by spin casting by Chapelle et al. (54) and Stephan et al. (55). They characterized these nanocomposites by Raman spectroscopy to study interactions between nanotubes and PMMA and found that PMMA tends to intercalate between the CNTs thereby increasing the distance between the nanotubes in the film. [Pg.183]

The application of a 11-ferrocenylundecyl-ammonium bromide/hexa-decylammonium bromide surfactant mixture as structure-directing agent resulted in a lamellar mesostructured silica film, which showed electronic conductivity due to electron transport in the ferrocenyl chains. Lyotropic lithium triflate-silicate liquid crystals have been utilized as supramolecular templates in the synthesis of ionically conducting nanocomposite films. ... [Pg.456]

Antibacterial Importance of a Biodegradable Polypyrrole/ Dextrin Conductive Nanocomposite... [Pg.122]

Natural biodegradable polymers with tailor-made properties offer excellent opportunities for advanced functional materials, e.g., biodegradable conductive nanocomposites based on polypyrrole (Ppy)/dextrin or PANI/dextrin provide enhanced conductive and antibacterial activities. [Pg.280]

FEL 11] Feller J.F., Castro M., Kumar B., Tolymer CNT conductive nanocomposite for sensing . Polymer Carbon Nanotube Composites Preparation, Properties and Applications, McNally T. (ed.). Chapter 25, Woodhead Pubhshing, Cambridge, p. 848,2011. [Pg.241]

N. Ballav and M. Biswas, A conducting nanocomposite via intercalative polymerisation of thiophene in montmoriUonite clay, Synth. Metals., 142, 309-315 (2004). [Pg.371]

R. Gangopadhyay, A. De, and S. Das, Transport properties of polypyrrole-ferric oxide conducting nanocomposites, J. Appl. Phys., 87, 2363 (2000). [Pg.524]

A. Maity and M. Biswas. Alumina-based water-dispersible conducting nanocomposites of polypyrrole and polypyrrole with poly(A-vinylcarbaz-... [Pg.55]

The new nanocomposites might find interesting uses in chemical sensors or paint formulations for antistatic applications, as well as in the development of electrically conductive nanocomposites with better mechanical properties due to the high mechanical strength of the T-CNs. [Pg.486]

Cho, E.-C., Li, C.-R, Huang, J.-H., Lee, K.-C., Huang, J.-H., 2015. Three-dimensional conductive nanocomposites based on multiwaUed carbon nanotube networks and PEDOT PSS as a flexible transparent electrode for optoelectronics. ACS Appl. Mater. Interfaces 7,11668-11676. [Pg.142]

PEDOT with and without the dopant PSS has been the most commonly used conductive polymer for SWNT composites. De et al prepared composite films by vacuum filtration from aqueous dispersions with PEDOT PSS as the matrix and both arc and HiPCO SWNTs as the filler. The optimal performance was observed for a 80 nm thick film containing 60 wt /o arc SWNTs, with a sheet resistance of 80 Q sq at 75 /o transmittance. Electromechanical testing showed these films to be stable under flexing and cycling. Later, a modified PEDOT copolymer with enhanced solubility, perchlorate-doped poly(3,4-ethylenedioxythiophene)-Z /ock-poly(ethyleneox-ide) (P-PEDOT-b-PEO) was used to disperse SWNTs and then to fabricate conductive nanocomposites via vacuum filtration method.The sheet resistance of the composite film was approximately 600 Q sq with 80 /o transmittance. [Pg.195]

S. Kumar, S.K. Pal, P.S. Kumar, V. Lakshminarayanan, Novel conducting nanocomposites synthesis of triphenylene-covered gold nanoparticles and their insertion into a columnar matrix. Soft Matter 3, 896-900 (2007)... [Pg.131]

Zou, J., Chen, H., Chunder, A., Yu, Y., Huo, Q., Zhai, L. Preparation of a superhydrophobic and conductive nanocomposite coating from a carbon-nanotube-conjugated block copolymCT dispersion. Adv. Mater. 20, 3337 (2008)... [Pg.254]

De M. F. Riccardis, V. Marti, Hybrid Conducting Nanocomposites Coatings for Corrosion Protection. In Developments in Corrosion Protection M. Allofkhazraei, Ed. InTech, 2014. [Pg.90]

Keywords Electromagnetic interference (EMI) shielding, microwave absorption, electrical conductivity, nanocomposites, intrinsically conducting polymers (ICPs), polyaniline, carbon nanotubes, graphene, shielding effectiveness, reflection loss, absorption loss, complex permittivity and permeabdity... [Pg.451]

Machida, K., K. Furuuchi, M. Min, and K. Naoi. 2004. Mixed proton-electron conducting nanocomposite based on hydrous Ru02 and polyaniline derivatives for supercapacitors. Electrochemistry 72 (6) 402-404. [Pg.255]

Petrov PD, Georgiev GL (2011) Ice-mediated coating of macroporous cryogels by carbon nanotubes a concept towards electrically conducting nanocomposites. Chem Commun 47 5768-5770... [Pg.222]

Formation of conducting nanocomposite films using coiiagen-chitosan blends and nanocarbons... [Pg.63]

Formation of conducting nanocomposite fiims from coiiagen and carbon nanotubes... [Pg.67]

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