Polymer/carbon nanotube

Coleman, J. N., Khan, U., Blau, W. J., and Gunko, Y. K. 2006. Small but strong A review of the mechanical properties of carbon nanotube-polymer composites. Carbon 44 1624-52. [Pg.28]

CNTs can enhance the thermal properties of CNT-polymer nanocomposites. The reinforcing function is closely associated with the amount and alignment of CNTs in the composites. Well-dispersed and long-term stable carbon nanotubes/ polymer composites own higher modulus and better thermal property as well as better electronic conductivity (Valter et al., 2002 Biercuk et al., 2002). Both SWNT and MWNT can improve the thermal stability and thermal conductivity of polymer, the polymer-CNT composites can be used for fabricating resistant-heat materials. [Pg.212]

Camponeschi E, Vance R, Al-Haik M, Garmestani H, Tannenbaum R (2007). Properties of carbon nanotube-polymer composites aligned in a magnetic field. Carbon 45 2037-2046. [Pg.214]

Ultrafast optical switching properties of single-wall carbon nanotube polymer composites at 1.55 pm. Appl. Phys. Lett. 81 975-977. [Pg.215]

Enhancement of thermal and electrical properties of carbon nanotube polymer composites by magnetic field processing. J. Appl. Phys. 94 6034-6039. [Pg.215]

Gong XY, Liu J, Baskaran S, Voise RD, Young JS (2000). Surfactant-assisted processing of carbon nanotube/polymer composites. Chem. Mater. 12 1049-1052. [Pg.216]

Kymakis E, Amaratunga GAJ (2003). Photovoltaic cells based on dye-sensitisation of single-wall carbon nanotubes in a polymer matrix. Solar Ener. Mater. Solar Cells 80 465 172.Kymakis E, Alexandrou I, Amaratunga GAJ (2003). High open-circuit voltage photovoltaic devices from carbon-nanotube-polymer composites. J. Appl. Phys. 93 1764-1768. [Pg.217]

Wong M, Paramsothy M, Xu XJ, Ren Y, Li S, Liao K (2003). Physical interactions at carbon nanotube-polymer interface. Polymer 44 7757-7764. [Pg.220]

Woo FIS, Czerw R, Webster S, Carroll DL, Ballato J, Strevens AE, O Brien D, Blau WJ (2000). Flole blocking in carbon nanotube-polymer composite organic light-emitting diodes based on poly (m-phenylene vinylene-co-2, 5-dioctoxy-p-phenylene vinylene). Appl. Phys. Lett. 77 1393-1395. [Pg.222]

Mechanical properties of doped carbon nanotubes-polymer composites... [Pg.92]

S. Harrison, AC and DC Percolative conductivity of single wall carbon nanotube polymer composites,/. Potym.Sci. B, vol. 43, pp. 3273-3287, 2005. [Pg.118]

Y. Y. Huang, J. E. Marshall, C. Gonzalez-Lopez, E. M. Terentjev, Variation in carbon nanotube polymer composite conductivity from the effects of processing, Dispersion, Aging and Sample Size, Mater. Express, vol. 1, pp. 315-328, 2011. [Pg.119]

Spitalsky, Z., et al., Carbon nanotube-polymer composites Chemistry, processing, mechanical and electrical properties. Progress in Polymer Science, 2010. 35(3) p. 357-401. [Pg.162]

Cosnier, S. and M. Holzinger, Design of carbon nanotube-polymer frameworks by electropolymerization of SWCNT-pyrrote derivatives. Electrochimica Acta, 2008. 53(11) p. 3948-3954. [Pg.168]

Bauhofer W, Kovacs JZ. A review and analysis of electrical percolation in carbon nanotube polymer composites. Composites Science and Technology. 2009 Aug 69(10) 1486-98. [Pg.250]

Wang C, Chen T, Chang S, Cheng S, Chin T. Strong carbon-nanotube-polymer bonding by microwave irradiation. Advanced Functional Materials. 2007 Aug 13 17(12) 1979-83. [Pg.251]

Andrews, R. and Weisenberger, M. C. 2004. Carbon nanotube polymer composites. Current Opinion in Solid State Materials Science 8 31-37. [Pg.346]

E. Kymakis, I. Alexandu, G.A.J. Amaratunga, Single-walled carbon nanotube-polymer composites Electrical, optical and structural investigation, Synth. Met. 127 (2002) 59-62. [Pg.164]

The viscoelastic properties of carbon nanotube/polymer composites have both practical importance related to composite processing and scientific importance as a probe of the composite dynamics and microstructure. The viscosity for CNT/PU dispersion at mixing is also very important for in-situ formation of polyurethane nanocomposite. Lower viscosity means a better flow ability and more homogenous mixing with isocyanate. Furthermore, low viscosity is very helpful to remove the bubbles before curing, which is a key step for polyurethane preparation. [Pg.157]

Pioggia, G., Francesco, F. Di., Ferro, M., Sorrentino, F., Salvo, P., and Ahluwalia, A. (2008). Characterization of a carbon nanotube polymer composite sensor for an impedimetric electronic tongue. Mikrochim. Acta 163, 57-62. [Pg.211]

Porous materials discussed at the International Conference on Materials for Advanced Technologies 2005 included clay minerals, silicates, aluminosilicates, organosilicas, metals, silicon, metal oxides, carbons and carbon nanotubes, polymers and coordination polymers, or metal-organic frameworks (MOFs), metal and metal oxide nanoparticles, thin films, membranes, and monoliths (Zhao, 2006). [Pg.1]

Kymakis E, Amaratunga GAJ (2002) Single-wall carbon nanotube/polymer photovoltaic devices. Appl Phys Lett 80 112... [Pg.85]

Kymakis E, Alexandrou 1, Amaratunga GAJ (2003) High open-circuit voltage photovoltaic devices from carbon-nanotube-polymer composites. J Appl Phys 93 1764... [Pg.85]

Landi BJ, Raffaelle RP, Castro SL, Bailey SG (2005) Single-wall carbon nanotube-polymer solar cells. Prog Photovoltaics Res Appl 13 165... [Pg.85]

Luo, C, Zuo, X, Wang, L, Wang, E, Song, S, Wang, J, Fan, C, Cao, Y. 2008. Flexible carbon nanotube-polymer composite films with high conductivity and superhydrophobicity made by solution process. Nano Lett 8 4454-4458. [Pg.321]

M. Trchova, E. N. Konyushenko, J. Stejskal, J. Kovafova, and G. Ciric-Marjanovic, The conversion of polyaniline nanotubes to nitrogen-containing carbon nanotubes and their comparison with multi-walled carbon nanotubes, Polym. Degrad. Stab., 94, 929-938 (2009). [Pg.94]

M. Baibarac, I. Baltog, S. Lefi t, and P. Gomez-Romero, Spectroscopic evidence for the bulk polymerization of N-vinyl carbazole in the presence of single-walled carbon nanotubes. Polymer, 48, 5279-5288 (2007). [Pg.251]

J.Y. Kim, M. Kim, and J.H. Choi, Characterization of light emitting devices based on a single-walled carbon nanotube-polymer composite, Synth. Met., 139, 565-568 (2003). [Pg.259]

Byrne, M.T., Gun ko, Y.K., 2010. Recent advances in research on carbon nanotube-polymer composites. Adv. Mater. 22,1672-1688. [Pg.142]

Chen, L., Liu, C., Liu, K., Meng, C., Hu, C., Wang, J., Fan, S., 2011. High-performance, low-voltage, and easy-operable bending actuator based on aligned carbon nanotube/polymer composites. ACS Nano 5, 1588-1593. [Pg.142]

Philip, B., Xie, J., Abraham, J.K., Varadan, VK., 2005. PolyanUlne/carbon nanotube composites starting with phenylamino functionalized carbon nanotubes. Polym BuU. 53,127-138. [Pg.146]

Yu, Z., Niu, X., Liu, Z., Pei, Q., 2011c. Intrinsically stretchable polymer Ught-emitting devices using carbon nanotube-polymer composite electrodes. Adv. Mater. 23,3989-3994. [Pg.148]

Huang, S., Li, L., Yang, Z., Zhang, L., Saiyin, H., Chen, X, Peng, H., 2011. A new and general fabrication of an aligned carbon nanotube/polymer film for electrode applications. Adv. Mater. 23,4707-4710. [Pg.235]

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