Carbon nanotube-reinforced composites

Seidel, G. D. and Lagoudas, D. C. Micromechanical analysis of the effective elastic properties of carbon nanotube reinforced composites. Mech of Mater., 38, 884-907 (2006). [Pg.252]

Tserpes, K. I., Panikos, R, Labeas, G., and Panterlakis, S. G. Multi-scale modeling of tensile behavior of carbon nanotube-reinforced composites. Theoret and Appl Fract Mech., 49,51-60(2008). [Pg.252]

Thostenson, E. T. and Chou, T-W. Aligned multi-walled carbon nanotube-reinforced composites processing and mechanical characterization. JPhys D Appl Phys., 35, 77-80 (2002). [Pg.254]

Tan, H., Jiang, L. Y, Huang, Y, Liu, B., and Hwang, K. C. The effect of van der Waals-based interface cohesive law on carbon nanotube-reinforced composite materials. Composites Science and Technology, 67,2941-2946 (2007). [Pg.255]

Liew, K.M., Lei, Z.X., Zhang, L.W. Mechanical analysis of functionally graded carbon nanotube reinforced composites a review. Compos. Struct. 120, 90-97 (2015)... [Pg.13]

Yang J-P et al (2012) Cryogenic mechanical behaviors of carbon nanotube reinforced composites based on modified epoxy by poly(ethersulfone). Compos B Eng 43(l) 22-26... [Pg.345]

Carbon Nanotube Reinforced Composites, Marcio Loos (ISBN 9781455731954)... [Pg.330]

Joshi, U. A., Sharma, S. C., and Harsha, S. P. Modeling and analysis of mechanical behavior of carbon nanotube reinforced composites. Pmc. IMechE, PartN Journal of Nanoengineering and Nanosystems, 225,23-31 (2011). [Pg.52]

Roy D, Bhattacharyya S, Rachamim A, Plati A, Saboungi M-L (2010) Measurement of interfacial shear strength in single wall carbon nanotubes reinforced composite using Raman spectroscopy. J Appl Phys 107(4), art no 043501... [Pg.207]

For CNTs not well bonded to polymers, Jiang et al. [137] established a cohesive law for carbon nanotube/polymer interfaces. The cohesive law and its properties (e.g., cohesive strength, cohesive energy) are obtained directly from the Lennard-Jones potential from the van der Waals interactions. Such a cohesive law is incorporated in the micromechanics model to study the mechanical behavior of carbon nanotube-reinforced composite materials. CNTs indeed improve the mechanical behavior of composite at the small strain. However, such improvement disappears at relatively large strain beeause the eompletely debonded nanotubes behave like voids in the matrix and may even weaken the composite. The increase of interface adhesion between CNTs and polymer matrix may significantly improve the composite behavior at the large strain [138]. [Pg.162]

Thostenson, E. R. Z., Chou, T. W. (2002),Alignedmulti-waUed carbon nanotube-reinforced composites Processing and mechanical characterization, Jo ma/ ofPhysicsD Applied Physics, 35, L77-L80. [Pg.256]

Another method to improve the mechanical properties such as interfacial strength is to add nanosized carbon fiber-reinforced particles into the composite [18-20]. A strong influence of a uniform dispersion of the small-sized fibers or partides on the composite properties of advanced nanocomposites, such as carbon nanotube-reinforced composites was also reported [21-24]. However, few papers mention the enhancing method for improving the interfacial adhesion between fiber and matrix in a natural BF composite. [Pg.317]

L. Ci, J. Suhr, V. Pushparaj, X. Zhang, P.M. Ajayan, Continuous carbon nanotube reinforced composites. Nano Lett. 8(9), 2762-2766 (2008)... [Pg.642]

Effective elastic properties for carbon nanotube reinforced composites are obtained through a variety of micromechanics techniques [76]. Using... [Pg.116]

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