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Dispersion carbon nanotubes

Dierking, 1., Scalia, G. and Morales, P. (2005) Liquid crystal-carbon nanotube dispersions. J. Appl. Phys., 97. 044309-1-044309-5. [Pg.276]

Alpatova, A.L. et al. (2010) Single-walled carbon nanotubes dispersed in aqueous media via noncovalent functionalization effect of dispersant on the stability, cytotoxicity, and epigenetic toxicity of nanotube suspensions. Water Research, 44 (2), 505-520. [Pg.210]

Ultrasonication has been used for the purification of CNTs. The low-molecular weight impurities are removed from carbon nanotube dispersion in methanol by filtration under a continuous sonication. The carbon nanotubes are... [Pg.5972]

Meyer F, Raquez JM, Dubios P et til (2010) Imidazolium end-functionalized poly(L-lactide) for efficient carbon nanotube dispersion. Chem Commun 46 5527-5529... [Pg.432]

Itoh E, Suzuki 1, Miyairi K (2005) Field emission from carbon-nanotube-dispersed conducting polymer thin film and its application to photovoltaic devices. Jpn J Appl Phys 44 636... [Pg.85]

Figure 13.17 compares inorganic nanoplatelets with single-wall carbon nanotubes, dispersed in a typical thermoplastic polymer melt at given and Af values, including the effects of shear rate and particle flexibility. The fact that the nanotube dispersion shows much higher viscosity than the nanoplatelet dispersion at low shear rates is a result of the superposition of two effects. Firstly, there is the effect of the difference between the geometrical characteristics of fibers and platelets, as was also shown in Figure 13.15. Secondly, there is the effect of the much greater stiffness of single-wall carbon nanotubes (E=5000 GPa [45]) compared to nanoplatelets (E-100 GPa), which results in the effects of particle flexibility becoming very small for the nanotubes. Figure 13.17 compares inorganic nanoplatelets with single-wall carbon nanotubes, dispersed in a typical thermoplastic polymer melt at given <J> and Af values, including the effects of shear rate and particle flexibility. The fact that the nanotube dispersion shows much higher viscosity than the nanoplatelet dispersion at low shear rates is a result of the superposition of two effects. Firstly, there is the effect of the difference between the geometrical characteristics of fibers and platelets, as was also shown in Figure 13.15. Secondly, there is the effect of the much greater stiffness of single-wall carbon nanotubes (E=5000 GPa [45]) compared to nanoplatelets (E-100 GPa), which results in the effects of particle flexibility becoming very small for the nanotubes.
Wisitsoraat, A.,Tuantranont, A.,Thanachayanont, C., Patthanasettakul, V. and Singjai, P. (2006) Electron beam evaporated carbon nanotube dispersed Sn02 thin film gas sensor , /. Electroceramics, 17,45-9. [Pg.405]

S.E. Moulton, M. Maugey, P. Poulin, G.G. Wallace, Liquid crystal behavior of single-walled carbon nanotubes dispersed in biological hyaluronic acid solutions. J. Am. Chem. Soc. 129, 9452-9457 (2007)... [Pg.96]

G. Ao, D. Nepal, M. Aono, V.A. Davis, Cholesteric and nematic liquid crystalline phase behavior of double-stranded DNA stabilized single-walled carbon nanotubes dispersions. ACS Nano 5, 1450-1458 (2011)... [Pg.97]

Ding et al. prepared functionalized graphene/carbon nanotube/PPy ternary nanocomposites by one-step electrochemical polymerization [143]. The functionalized graphene and carbon nanotube disperses homogeneously in the PANI matrix and the ternary nanocomposite is highly... [Pg.245]

Mallakpour S, Zadehnazari A. One-pot synthesis of glucose functionalized multi-walled carbon nanotubes dispersion in hydrox-ylated poly(amide-imide) composites and their thermo-mechanical properties. Polymer 2013 54(23) 6329-38. [Pg.338]

Shaffer, M. S. P. Windle, A. H. Analogies betwem polymer solutions and carbon nanotube dispersions. Macromolecules 32, 6864-6866 (1999). [Pg.596]

Songmin, S., Lu, G., Chrm-Wah, Y.M. Improvement of carbon nanotubes dispersion by chitosan salt and its application in silicone rubber. Compos. Sci. Technol. 86, 129-134 (2013)... [Pg.192]

M.L., Rodriguez, M.C., Ferreyra, N.F., Rubianes, M.D., Bollo, S., and Rivas, G.A. (2013) Comparative study of the electrochemical behavior and analytical applications of (bio)sensing platforms based on the use of multi-walled carbon nanotubes dispersed in different polymers. Anal Chim. Acta, 805, 19-35. [Pg.113]

Dalmasso, P., Pedano, M.L., and Rivas, GA. (2012) Electrochemical determination of ascorbic acid and paracetamol in pharmaceutical formulations using a glassy carbon electrode modified with multi-wall carbon nanotubes dispersed in polyhistidine. Sens. Actuators, B,... [Pg.115]

Dahl, K.N., and Islam, M.F. (2012) Not all protein-mediated single-wall carbon nanotube dispersions are equally bioactive. Nanoscale, 4, 7425. [Pg.115]

Bioelectrochemical sensing of promethazine with bamboo-type mul-tiwalled carbon nanotubes dispersed in calf-thymus double stranded DNA. Bioelectrochemistry, 99, 8-16. [Pg.115]

N.V., and Chien, N.D. (2012) Detection of pathogenic microorganisms using biosensor based on multi-walled carbon nanotubes dispersed in DNA solution. [Pg.115]

Kasaliwal, G. Villmow, T Pegel, S Potsehke, P. Influenee of material and proeessing parameters on carbon nanotube dispersion in polymer melts. In Polymer-carbon nanotube composites, preparation, properties and applications, MeNally, T. Potsehke, R, eds Woodhead Publishing Cambridge, UK, 2011 pp. 92-132. [Pg.137]

Lucas AA, Lambin PH, Smadey RE (1993) On the energetic of tubular fuderenes. J Phys Chem Sodds 54 587-593 Marsh DH, Ranee GA, Zaka MH, Whitby RJ, Khlobystov AN (2007) Comparison of the stabdity of multiwaded carbon nanotube dispersions in water. Phys Chem Chem Phys 9 5490-5496 Miyamoto Y, Berber S, Yoon M, Rubio A, Tomanek D (2002) Onset of nanotube decay under extreme thermal and electronic excitations. PhysicaB 323 78-85... [Pg.308]

Mathur R B, Singh B P, Dhami T L, Kalra Y, Lai N, Rao R and Rao A M (2010), Influence of carbon nanotube dispersion on the mechanical properties of phenolic resin composites , Polym Compos, 31, 321—327. [Pg.40]

Krause B, Petzold G, Pegel S and Potschke P (2008) Correlation of carbon nanotube dispersability in aqueous surfactant solutions and polymers. Carbon 47 602-612. [Pg.189]

Rastogi R, Kaushal R, Tripathi S K, Sharma A L, Kaur I and Bharadwaj L M (2008) Comparative study of carbon nanotube dispersion using surfactants, J Colloid Interface Sci 328 421-428. [Pg.220]

Kodgire P V, Bhattacharyya A R, Bose S, Gupta N, Kulkarni A R and Misra A (2006) Control of multiwall carbon nanotubes dispersion in polyamide 6 An assessment through electrical conductivity, Chem Phys Lett 432 480-485. [Pg.221]

Uchida T and Kumar S (2005) Single wall carbon nanotube dispersion and exfoliation in polymers, J Appl Polym Sci 98 985-989. [Pg.244]

Effect of surface treatment on carbon nanotube dispersion... [Pg.44]

See other pages where Dispersion carbon nanotubes is mentioned: [Pg.476]    [Pg.112]    [Pg.387]    [Pg.245]    [Pg.261]    [Pg.85]    [Pg.114]    [Pg.114]    [Pg.115]    [Pg.196]    [Pg.364]    [Pg.187]    [Pg.771]    [Pg.526]   
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See also in sourсe #XX -- [ Pg.158 , Pg.159 , Pg.160 , Pg.161 , Pg.162 ]

See also in sourсe #XX -- [ Pg.7 ]



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