Recent Advances in Science and Technology of Materials: Volume 2

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Composite materials technology plays a significant role in the development of modern science and technology. Composite material technologies are widely used in advanced structures and replacing traditional materials at a growing pace. Composite materials have enhanced mechanical properties compared to traditional materials and have potential application in the manufacture of aerospace components, aircraft, boat hulls, car bodies, electronic devices, biomedical prosthesis etc. Recent advances in composite technology is a special issue peer-reviewed international journal dedicated to the publication of original full-length research papers and review articles of the highest quality which address the advances in the research and development of composite materials technology.

The key focus are on the advances in the processing, manufacturing of the metal matrix composites, fiber reinforced composites, ceramic composites, nanocomposites and biomedical composites, addressing, not only just the usual topics but also on more novel areas such as intelligent composite materials, recyclability of composites etc. You have to register yourself first. Mukopadhyay, S.

Kawasaki, F. Okino, H. Shirai, W. Xu, T. Kyotani, and A. Property control of new forms of carbon materials by fluorination. Stevens, A. Huang, H. Peng, I. Chiang, V. Khabashesku, and J. Sidewall amino-functionalization of single-walled carbon nanotubes through fluorination and subsequent reactions with terminal diamines. Nano Letters, Volume 3, Issue 3, , Pages Li and F. Li, The effect of carbonyl, carboxyl and hydroxyl groups on the capacitance of carbon nanotubes.

Chen, M. Hamon, H. Hu, Y. Chen, A. Rao, P. Eklund, and R. Solution properties of single-walled carbon nanotubes. Hu, B. Zhao, M. Hamon, K. Kamaras, M. Itkis, and R. Holzinger, J. Abraham, P. Whelan, R. Graupner, L. Ley, F. Kappes, and A. Functionalization of single-walled carbon nanotubes with r- oxycarbonyl nitrenes. Unger, A. Graham, F. Kreupl, M. Liebau, and W.

Electrochemical functionalization of multi-walled carbon nanotubes for solvation and purification. Kim, D. Bae, J. Kim, K. Park, S. Lim, J. Kim, W. Choi, C. Park, and Y. Modification of electronic structures of a carbon nanotube by hydrogen functionalization. Advanced Materials, Volume 14, Issue 24, , Pages Ruiz-Rosas, E.

Functionalization of carbon nanotubes using aminobenzene acids and electrochemical methods. Electroactivity for the oxygen reduction reaction. Esumi, M. Ishigami, A. Nakajima, K. Sawada, and H. Chemical treatment of carbon nanotubes. Carbon, Volume 34, Issue 2, , Pages Yu, L. Chen, Q. Liu, J. Lin, K. Tan, S. Ng, H. Chan, G. Xu, and T. Platinum deposition on carbon nanotubes via chemical modification. Chemistry of Materials, Volume 10, Issue 3, , Pages Hiura, T. Ebbesen, and K.

Opening and purification of carbon nanotubes in high yields. Advanced Materials, Volume 7, Issue 3, , Pages Luo, Y. Liu, H. Wei, B. Wang, K. Wu, B. Zhang, and D. A green and economical vapor-assisted ozone treatment process for surface functionalization of carbon nanotubes. Green Chemistry, Volume 19, Issue 4, , Pages Chang, and C. Enhancement of electrochemical properties of screen-printed carbon electrodes by oxygen plasma treatment.

Electrochimica Acta, Volume 54, Issue 21, , Pages Cruz-Delgado, M. Surface modification of carbon nanotubes with ethylene glycol plasma. Carbon, Volume 47, Issue 8, , Pages Ma, J. Kim, and B. Functionalization of carbon nanotubes using a silane coupling agent.

Carbon, Volume 44, Issue 15, , Pages Modifications of carbon nanotubes with polymers. Hui, P. Bhowmik, H. Ester-functionalized soluble single-walled carbon nanotubes. Liu, A. Rinzler, H. Dai, J. Hafner, R. Bradley, P. Boul, A. Lu, T. Iverson, K. Shelimov, C. Huffman, F.

Rodriguez-Macias, Y. Shon, T.

Recent Advances in Science and Technology of Materials

Lee, D. Colbert, and R. Fullerene pipes. Stephenson, A. Sadana, A. Higginbotham, and J. Highly functionalized and soluble multiwalled carbon nanotubes by reductive alkylation and arylation: The Billups reaction. Chemistry of Materials, Volume 18, Issue 19, , Pages Karousis, N. Tagmatarchis, and D. Current progress on the chemical modification of carbon nanotubes. Chemical Reviews, Volume , Issue 9, , Pages Mc Carthy, J. Coleman, R. Czerw, A. Dalton, D. Carroll, and W. Microscopy studies of nanotube-conjugated polymer interactions. Synthetic Metals, Volume , Issues , , Pages Li, F.

Cheng, A. Duft, and A. Cui, R. Canet, A. Derre, M. Couzi, and P. Characterization of multiwall carbon nanotubes and influence of surfactant in the nanocomposite processing. Carbon, Volume 41, Issue 4, , Pages Vaisman, G. Marom, and H. Dispersions of surface-modified carbon nanotubes in water-soluble and water-insoluble polymers. O'Connell, S. Bachilo, C. Huffman, V.

Moore, M. Strano, E. Haroz, K. Rialon, P. Boul, W. Noon, C. Kittrell, J. Ma, R. Hauge, R. Weisman, and R. Band gap fluorescence from individual single-walled carbon nanotubes. Bystrzejewski, A. Huczko, H. Lange, T. Gemming, B. Dispersion and diameter separation of multi-wall carbon nanotubes in aqueous solutions. Kim, C. Doe, S.

Kline, and S. Advanced Materials, Volume 19, Issue 7, , Pages Whitsitt and A. Silica coated single walled carbon nanotubes. Nano Letters, Volume 3, Issue 6, , Pages Clark, S. Subramanian, and R. Understanding surfactant aided aqueous dispersion of multi-walled carbon nanotubes. Grossiord, J. Loos, O. Regev, and C. Toolbox for dispersing carbon nanotubes into polymers to get conductive nanocomposites.

Chemistry of Materials, Volume 18, Issue 5, , Pages Georgakilas, D. Gournis, V. Tzitzios, L. Pasquato, D. Guldi, and M. Decorating carbon nanotubes with metal or semiconductor nanoparticles. Tsang, Z. Guo, Y. Green, H. Hill, T. Hambley, and P. Immobilization of platinated and iodinated oligonucleotides on carbon nanotubes. Pachekoski, S. Amico, S.

Pezzin, and J. Carbon nanotube hybrid polymer composites: Recent advances in mechanical characterization. In: V. Thakur, M. Thakur, and A. Pappu Eds. Wong, M. Paramsothy, X. Xu, Y. Ren, S. Li, and K. Physical interactions at carbon nanotube-polymer interface. Polymer, Volume 44, Issue 25, , Pages Sahoo, S. Rana, J. Cho, L. Li, and S.

1st Edition

Polymer nanocomposites based on functionalized carbon nanotubes. Yamamoto and K. Synthesis of composite polymer particles with carbon nanotubes and evaluation of their mechanical properties. Desai and M. Mechanics of the interface for carbon nanotube-polymer composites. Szleifer and R. Polymers and carbon nanotubes-dimensionality, interactions and nanotechnology. Polymer, Volume 46, Issue 19, , Pages Rahmat and P. Carbon nanotube-polymer interactions in nanocomposites: A review. Evidence of the reinforcement role of chemical vapour deposition multi-walled carbon nanotubes in a polymer matrix.

Carbon, Volume 41, Issue 6, , Pages Nan, Z. Shi, and Y. A simple model for thermal conductivity of carbon nanotube-based composites. Lau, and D. The revolutionary creation of new advanced materials-carbon nanotube composites. Barber, S. Cohen, and H. Measurement of carbon nanotube-polymer interfacial strength. Donnet, T. Peng, and S. Carbon Fibers, 3rd ed. Ding, A. Eitan, F. Fisher, X. Chen, D. Dikin, R. Andrews, L. Brinson, L. Schadler, and R. Direct observation of polymer sheathing in carbon nanotube-polycarbonate composites. Nano Letters, Volume 3, Issue 11, , Pages Zhou, X.

Wang, X. Liu, and D. Influence of multi-walled carbon nanotubes on the cure behavior of epoxy-imidazole system. Carbon, Volume 47, Issue 4, , Pages Frankland and V. Analysis of carbon nanotube pull-out from a polymer matrix. Gou, B. Minaie, B. Liang, and C. Computational and experimental study of interfacial bonding of single-walled nanotube reinforced composites. Dai and A. Surface and interface control of polymeric biomaterials, conjugated polymers, and carbon nanotubes.

Karami, M. Asadi, and M. Pulse electropolymerization and the characterization of polyaniline nanofibers. Electrochimica Acta, Volume 61, , Pages Burroughes, D. Bradley, A. Brown, R. Marks, K. Mackay, R. Friend, P. Burns, and A. Light-emitting diodes based on conjugated polymers. Coleman, A. Curran, A. Rubio, A. Davey, A.

Drury, B. McCarthy, B. Lahr, P. Ajayan, S. Roth, R. Barklie, W. Phase separation of carbon nanotubes and turbostratic graphite using a functional organic polymer. Advanced Materials, Volume 12, Issue 3, , Pages Zengin, W. Zhou, J. Jin, R. Czerw, D. Smith Jr. Echegoyen, D. Carroll, S. Foulger, and J. Carbon nanotube doped polyaniline. Advanced Materials, Volume 14, Issue 20, , Pages Dalton, W.

Blau, G. Chambers, J. Coleman, K. Henderson, S. Lefrant, B. McCarthy, C. Stephan, and H. A functional conjugated polymer to process, purify and selectively interact with single wall carbon nanotubes. Star, J. Stoddart, D. Steuerman, M. Diehl, A.

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Boukai, E. Wong, X. Yang, S. Chung, H. Choi, and J. Preparation and properties of polymer-wrapped single-walled carbon nanotubes. Steuerman, A. Star, R. Narizzano, H. Choi, R. Ries, C. Nicolini, J. Stoddart, and J. Interactions between conjugated polymers and single-walled carbon nanotubes.

Polymer-assisted dispersion of single-walled carbon nanotubes in alcohols and applicability toward carbon nanotube sol-gel composite formation. Langmuir, Volume 21, Issue 3, , Pages Dai, and T. Carbon nanotube-conducting-polymer composite nanowires. Langmuir, Volume 21, Issue 1, , Pages Guo, P. Sadler, and S. Immobilization and visualization of DNA and proteins on carbon nanotubes. Advanced Materials, Volume 10, Issue 9, , Pages Chou, H. Ribeiro, E. Barros, A. Santos, D. Nezich, Ge. Samsonidze, C.

Fantini, M. Pimenta, A. Jorio, F. Plentz Filho, M. Dresselhaus, R. Saito, M. Zheng, G. Onoa, E. Semke, A. Swan, M. Optical characterization of DNA-wrapped carbon nanotube hybrids. Zheng, A. Jagota, E.

Semke, B. Diner, R. Mclean, S. Lustig, R. Richardson, and N. DNA-assisted dispersion and separation of carbon nanotubes. Nature Materials, Volume 2, Issue 5, , Pages Jagota, M. Strano, A. Santos, P. Barone, S. Chou, B. Diner, M. Mclean, G. Onoa, G. Samsonidze, E. Semke, M. Usrey, and D. Structure-based carbon nanotube sorting by sequence-dependent DNA assembly. Matyshevska, A. Karlash, Y. Shtogun, A. Benilov, Yu. Kirgizov, K. Gorchinskyy, E. Buzaneva, Y. Prylutskyy, and P. Self-organizing DNA-carbon nanotube molecular films. Erlanger, B. Zhu, and L.

Binding of an anti-fullerene IgG monoclonal antibody to single wall carbon nanotubes. Nano Letters, Volume 1, Issue 9, , Pages Barisci, M.

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Tahhan, G. Wallace, S. Badaire, T. Vaugien, M. Maugey, and P. Properties of carbon nanotube fibers spun from DNA-stabilized dispersions. Keren, S. Berman, E. Buchstab, U. Sivan, and E. DNA-templated carbon nanotube field-effect transistor. Gao and Y. Simulation of DNA-nanotube interactions. Dieckmann, A. Dalton, P. Johnson, J. Razal, J. Chen, G. Giordano, E. Musselman, R. Baughman, and R. Controlled assembly of carbon nanotubes by designed amphiphilic peptide helices. O'Connell, P. Boul, L. Ericson, C. Huffman, Y. Wang, E. Haroz, C.

Kuper, J. Tour, K. Ausman, and R. Reversible water-solubilization of single-walled carbon nanotubes by polymer wrapping. Star, D. Steuerman, J. Heath, and J. Starched carbon nanotubes. Wagner and R. Nanocomposites: issues at the interface. Materials Today, Volume 7, Issue 11, , Pages Gotovac, H. Honda, Y. Hattori, K. Takahashi, H. Kanoh, and K.

Effect of nanoscale curvature of single-walled carbon nanotubes on adsorption of polycyclic aromatic hydrocarbons. Nano Letters, Volume 7, Issue 3, , Pages Moreno, S. Aspera, M. David, and H. A computational study on the effect of local curvature on the adsorption of oxygen on single-walled carbon nanotubes. Carbon, Volume 94, , Pages Zaeri, S. Ziaei-Rad, A. Vahedi, and F. Mechanical modelling of carbon nanomaterials from nanotubes to buckypaper.

Carbon, Volume 48, Issue 13, , Pages Yu, B. Yakobson, and R. Controlled sliding and pullout of nested shells in individual multiwalled carbon nanotubes. Qian, W. Liu, and R. Load transfer mechanism in carbon nanotube ropes. Qian, E.

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Dickey, R. Andrews, and T. Load transfer and deformation mechanisms in carbon nanotube-polystyrene composites. Tang and J. A review of methods for improving the interfacial adhesion between carbon fiber and polymer matrix. Polymer Composites, Volume 18, Issue 1, , Pages Mu and K. Improved load transfer in nanotube-polymer composites with increased polymer molecular weight. Cadek, J. Ryan, V. Nicolosi, G. Bister, A. Fonseca, J. Nagy, K. Szostak, F. Nano Letters, Volume 4, Issue 2, , Pages Gao, M.

Loi, E. Selective wrapping and supramolecular structures of polyfluorene-carbon nanotube hybrids. Yi, A. Malkovskiy, Y. Xu, X. Wang, A. Sokolov, M. Lebron-Colon, M. Meador, and Y. Polymer conformation-assisted wrapping of single-walled carbon nanotube: The impact of cis-vinylene linkage. Polymer, Volume 51, Issue 2, , Pages Tallury and M. Molecular dynamics simulations of polymers with stiff backbones interacting with single-walled carbon nanotubes.

Kusner and S. Conformational behavior of semi-flexible polymers confined to a cylindrical surface. Molecular dynamics simulations of flexible polymer chains wrapping single-walled carbon nanotubes. Mei, P. Schmidt, G. Osuna, L. Fang, C. Tassone, A. Zoombelt, A. Sokolov, K. Houk, M. Toney, and Z. Scalable and selective dispersion of semiconducting arc-discharged carbon nanotubes by dithiafulvalene-thiophene copolymers for thin film transistors. Zhang, W. Lin, C. Wong, D. Bucknall, and S. Nanocomposites of carbon nanotube fibers prepared by polymer crystallization.

Didenko, V. Moore, D. Baskin, and R. Visualization of individual single-walled carbon nanotubes by fluorescent polymer wrapping. Nano Letters, Volume 5, Issue 8, , Pages Choi, and S. Improvement of interfacial interaction via ATRP in polycarbonate-carbon nanotube nanocomposites. Buffa, G. Abraham, B. Grady, and D. Effect of nanotube functionalization on the properties of single-walled carbon nanotube-polyurethane composites.

Zheng, Q. Xue, K. Yan, X. Gao, Q. Li, and L. Effect of chemisorption on the interfacial bonding characteristics of carbon nanotube-polymer composites. Polymer, Volume 49, Issue 3, , Pages