[1] Natsuki, T., Tantrakarn, K., and Endo, M. 2004. Prediction of elastic properties for single walled carbon nanotubes. Carbon 42: 39–45.
[2] Chopra, N., Benedict, L., Crespi, V., Cohen, M., Louie, S., and Zettl, A. 1995. Fully collapsed carbon nanotubes. Nature (London) 377: 135-138.
[3] Xiao, J.R., Gama, B.A., and Gillespie, JW. 2005. An analytical molecular structural mechanics model for the mechanical properties of carbon nanotubes. Int J. Solids and Struct 42: 3075–3092.
[4] Wu, Y., Zhang, X., Leung, AY.T., and Zhong, W. 2006. An energy-equivalent model on studying the mechanical properties of single-walled carbon nanotubes. Thin-walled Structures 44: 667–676.
[5] Rafii-Tabar, H. 2004. Computational modelling of thermo-mechanical and transport properties of carbon nanotubes. Physics Reports 390: 235–452.
[6] Lu, Q., and Bhattacharya, B. 2005. The role of atomistic simulations in probing the small scale aspects of fracture – a case study on a single-walled carbon nanotube. Engineering Fracture Mechanics 72: 2037–2071.
[7] Odegard, G.M., Gates, T.S., Nicholson, L.M., and Wise, K.E. 2002. Equivalent-continuum modeling of nano-structured materials. Comp Sci and Tech 62: 1869–1880.
[8] Li, C., and Chou, T.W. 2003. A structural mechanics approach for the analysis of carbon nanotubes. Int J. Solids and Struct 40: 2487–2499.
[9] Cornwell, C.F., and Wille, L.R. 1997. Elastic properties of single-walled carbon nanotubes in Compression. Solid State Commun 101(8): 555-558.
[10] Yao, N., and Lordi, V. 1998. Young’s modulus of single-walled carbon nanotubes. J. App Phys 84(4): 1939-1943.
[11] Zhang, H.W., Wang, J.B., and Guo, X. 2005. Predicting the elastic properties of single-walled carbon nanotubes. J. the Mech and Phys of Sol 53: 1929–1950.
[12] Gao, X.L., and Li, K. 2003. Finite deformation continuum model for single-walled carbon nanotubes. Int J. Solids and Struct 40: 7329–7337.
[13] Shokrieh, M.M., and Rafiee, R. 2010. On the tensile behavior of an embedded carbon nanotube in polymer matrix with nonbonded interphase region. Composite Structures 92: 647–652.
[14] Ayatollahi, M.R., Shadlou, S., and Shokrieh M.M. 2011. Multiscale modeling for mechanical properties of carbon nanotube reinforced nanocomposites subjected to different types of loading. Composite Structures 93: 2250–2259.
[15] Gogotsi, Y. Ed. 2006. Nanomaterials Handbook, London & New York: CRC Press.
[16] Gelin, B.R. 1994. Molecular modeling of polymer structures and properties, Germany: Hanser/Gardner Publishers.
[17] Wernik, J.M.,· and Meguid, S. A. 2011. Multiscale modeling of the nonlinear response of nano reinforced polymers. Acta Mech 217: 1-16.
[18] Inc, ANSYS. 2009. ANSYS Guide. Europe.
[19] Xiaoxing, Lu, and Zhong, Hu. 2012. Mechanical property evaluation of single-walled carbon nanotubes by finite element modeling. Composites: Part B 43: 1902–1913.
[20] Krishnan, A., Dujardin, E., Ebbesen, T.W., and Treacy, M.M.J. 1998. Young's modulus of single-walled nanotubes. Phys Rev B 58: 14013–9.