Nanotechnology carbon nanotube

Williams KA, Veenhuizen PTM, de la Torre BG, Eritja R, Dekker C (2002) Nanotechnology -Carbon nanotubes with DNA recognition. Nature 420 761. 

Oxana Vasilievna Kharissova, PhD, is currently a professor and researcher at the Universidad Autonoma de Nuevo Leon (UANL), Monterrey, Mexico. She received her MS in crystallography in 1994 from Moscow State University, Moscow, Russia, and her PhD in materials in 2001 from the UANL, Mexico. She received the UANL Research Award in 2001 for her work in research and publications, as well as the TECNOS Award from the State Government of Nuevo Leon in 2004 for several of her research works. She is a member of National Researchers System (Level I), Mexican Academy of Science, and the Materials Research Society. Dr. Kharissova is also the coauthor of 2 books and 60 articles and has 2 patents. Her research interests include nanotechnology (carbon nanotubes, nanometals, and fullerenes), microwave irradiation, and crystallography. 

Dexter J. Carbon Nanotubes Enable Pumpless Liquid Cooling System for Computers IEEE Spectrum s nanotechnology blog. URL http spectrum.ieee.org/nanoclast/ semiconductors/nanotechnology/carbon-nanotubes-enable-pumpless-liquid-cooling-system-for-computers. 

E.l You have become very excited about the possibilities of nanotechnology, especially the creation of fibers one atom wide. Suppose you were able to string together 1.00 mole of silver atoms, which have a radius of 144 pm, by encapsulating them in carbon nanotubes (see Box 14.1). How long could the fiber extend ... 

There is currently considerable interest in processing polymeric composite materials filled with nanosized rigid particles. This class of material called "nanocomposites" describes two-phase materials where one of the phases has at least one dimension lower than 100 nm [13]. Because the building blocks of nanocomposites are of nanoscale, they have an enormous interface area. Due to this there are a lot of interfaces between two intermixed phases compared to usual microcomposites. In addition to this, the mean distance between the particles is also smaller due to their small size which favors filler-filler interactions [14]. Nanomaterials not only include metallic, bimetallic and metal oxide but also polymeric nanoparticles as well as advanced materials like carbon nanotubes and dendrimers. However considering environmetal hazards, research has been focused on various means which form the basis of green nanotechnology. 

Carbon nanotubes (CNTs) are a set of materials with different structures and properties. They are among the most important materials of modern nanoscience and nanotechnology field. They combine inorganic, organic, bio-organic, coUoidal, and polymeric chemistry and are chemically inert. They are insoluble in any solvent and their chemistry is in a key position toward interdisciphnary applications, for example, use as supports for catalysts and catalytic membranes [20, 21]. 

In general, nanotechnology MBBs are distinguished for their unique properties. They include, for example, graphite, fullerene molecules made of various numbers of carbon atoms (C60, C70, C76, C240, etc.), carbon nanotubes, nanowires, nanocrystals, amino acids, and diamondoids [97]. All these molecular building blocks are candidates for various applications in nanotechnology. 

Poland, C.A. et al. (2008) Carbon nanotubes introduced into the abdominal cavity of mice show asbestoslike pathogenicity in a pilot study. Nature Nanotechnology, 3 (7), 423-428. 

Mitchell, L.A. et al. (2009) Mechanisms for how inhaled multiwalled carbon nanotubes suppress systemic immune function in mice. Nature Nanotechnology, 4 (7), 451 156. 

Wang, H. F. et al. (2004) Biodistribution of carbon single-wall carbon nanotubes in mice. Journal of Nanoscience and Nanotechnology, 4 (8), 1019—1024. 

Kostarelos, K. et al. (2007) Cellular uptake of functionalized carbon nanotubes is independent of functional group and cell type. Nature Nanotechnology, 2 (2), 108-113. 

Kagan, V.E. et al. (2010) Carbon nanotubes degraded by neutrophil myeloperoxidase induce less pulmonary inflammation. Nature Nanotechnology,... 

Tutak, W. et al. (2009) Toxicity induced enhanced extracellular matrix productionin osteoblastic cells cultured on single-walled carbon nanotube networks. Nanotechnology, 20 (25). 255101. 

A. Guiseppi-Elie, C.H. Lei, and R.H. Baughman, Direct electron transfer of glucose oxidase on carbon nanotubes. Nanotechnology 13, 559-564 (2002). 

E. Buzaneva, A. Karlash, K. Yakovkin, Y. Shtogun, S. Putselyk, D. Zherebetskiy, A. Gorchinskiy, G. Popova, S. Prilutska, O. Matyshevska, Y. Prilutskyy, P. Lytvyn, P. Scharff, and P. Eklund, DNA nanotechnology of carbon nanotube cells physico-chemical models of self-organization and properties. Mat. Sci. Eng. C-Bio. S. 19, 41 15 (2002). 

Warheit, D.B., B.R. Laurence, K.L. Reed, D.H. Roach, G.A. Reynolds, T.R. Webb, Lung toxicity bioassay study in rats with single-wall carbon nanotubes. Proceedings of the ACS Symposium Series, 890 (Nanotechnology and the Environment), 2005, pp. 67-90. 

Langbrg Hu, a scientist si Llmdynri, checks a carbon nanotube. Unidym uses nanotechnology to help produce touch screens for cellphones and ATMs. 

Carbon monoxide off-gas, from phosphorus manufacture, 19 12 Carbon nanostructures, 27 46-58 Carbon Nanotechnologies, Inc., 2 718, 719 Carbon-nanotube fibers, 23 385-386 Carbon nanotubes (CNTs), 2 655, 693, 694, 719-722 20 434 27 47 8 ... 

Rohrs, H. W. and Ruoff, R. S. Use of carbon nanotubes in hybrid nanometer scale devices, in Lee, S. C. and Savage, L. (eds), Biological Molecules in Nanotechnology the Convergence of Biotechnology, Polymer Chemistry and Materials Science, IBC Press, Southborough, MA, USA, 1998, pp. 33-38. 

Buzaneva E, Karlash A, Yakovkin K, Shtogun Y, Putselyk S, Zherebetskiy D, Gorchinskiy A, Popova G, Prilutska S, Matyshevska O, Prilutskyy Y, Lytvyn P, Scharff P, Eklund P (2002) DNA nanotechnology of carbon nanotube cells Physico-chemical models of self-organization and properties. Mater. Sci. Eng. C 19 41 15. 

Dwyer C, Guthold M, Falvo M, Washburn S, Superfine R, Erie D (2002) DNA-functionalized single-walled carbon nanotubes. Nanotechnology 13 601-604. 

Cui D, Tian F, Kong Y, Titushikin I, Gao H (2004b). Effects of single-walled carbon nanotubes on Polymerase Chain Reaction (2004). Nanotechnology 15 154-157. 

Pan B, Cui D, Gao F, He R (2006). Growth of multi-amine terminated poly(amidoamine)dendrim ers on the surface of carbon nanotubes. Nanotechnology 17 2483-2489. 

Berger C, Poncharal P, Yi Y, de Heer W (2003) Ballistic conduction in multiwalled carbon nanotubes. Journal of Nanoscience and Nanotechnology 3 171-177. 

Monteiro-Riviere NA, Inman AO, Wang YY, Nemanich RJ (2005a) Surfactant effects on carbon nanotube interactions with human keratinocytes. Nanomedicine Nanotechnology, Biology and Medicine 1 293-299. 

Wang X, Sun B, Yang HK (2006) Stability of multi-walled carbon nanotubes under combined bending and axial compression loading. Nanotechnology 17 815-823. 

Xin HJ, Woolley AT (2005) High-yield DNA-templated assembly of surfactant-wrapped carbon nanotubes. Nanotechnology 16 2238-2241. 

Cai D, Doughty CA, Potocky TB, Dufort FJ, Huang Z, Blair D, Kempa K, Ren ZF, Chiles TC (2007) Carbon nanotube-mediated delivery of nucleic acids does not result in non-specific activation of B lymphocytes. Nanotechnology 18 Art. No. 365101. 

Garibaldi S, Brunelli C, Bavastrello V, Ghigliotti G, Nicolini C (2006) Carbon nanotube biocompatibility with cardiac muscle cells. Nanotechnology 17 391-397. 

Hilder TA, Hill JM (2007) Modelling the encapsulation of the anticancer drug cisplatin into carbon nanotubes. Nanotechnology 18 Art. No. 275704. 

Polizu S, Savadogo O, Poulin P, Yahia L (2006) Applications of carbon nanotubes-based biomaterials in biomedical nanotechnology. J Nanosci Nanotechnol 6 1883-1904. 

Reilly RM (2007) Carbon nanotubes potential benefits and risks of nanotechnology in nuclear medicine. J Nucl Med 48 1039-1042. 

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