References
- Iijima S. Helical microtubules of graphitic carbon. Nature. 1991;354:56.
- Fiedler B, Gojny FH, Wichmann MHG, et al. Fundamental aspects of nano-reinforced composites. Compos Sci Technol. 2006;66:3115–3125.
- Wang CM, Tan VBC, Zhang YY. Timoshenko beam model for vibration analysis of multi-walled carbon nanotubes. J Sound Vib. 2006;294:1060–1072.
- Wang Q, Varadan VK. Wave characteristics of carbon nanotubes. Int J Solids Struct. 2005;43:254–265.
- Rajagopal SV, Singh G, Rao YVKS. Large-deflection and nonlinear vibration of multilayered sandwich plates. AIAA J. 1987;25:130–133.
- Shiau LC, Kuo SY. Free vibration of thermally buckled composite sandwich plates. J VibA Coust. 2006;128:1–7.
- Formica G, Lacarbonara W, Alessi. R. Vibrations of carbon nanotube-reinforced composites. J Sound Vib. 2010;329:1875–1889.
- Reddy JN. Nonlocal theories for bending, buckling and vibration of beams. Int J Eng Sci. 2007;45:288–307.
- Aksencer T, Aydogdu M. Levy type solution method for vibration and buckling of nanoplates using nonlocal elasticity theory. Physica E. 2011;43:954–959.
- Jomehzadeh E, Saidi AR. Decoupling the nonlocal elasticity equations for three dimensional vibration analysis of nano-plates. Compos Struct. 2011;93:1015–1020.
- Odegard GM, Gates TS, Nicholson LM, et al. Equivalent-continuum modeling of nano-structured materials. Compos Sci Technol. 2002;62:1869–1880.
- Odegard GM, Gates TS, Wise KE, et al. Constitutive modeling of nanotube-reinforced polymer composites. Compos Sci Technol. 2003;63:1671–1687.
- Hu N, Fukunaga H, Lu C, et al. Prediction of elastic properties of carbon nanotube reinforced composites. Proc R Soc A. 2005;461:1685–1710.
- Wuite J, Adali S. Deflection and stress behaviour of nanocomposite reinforced beams using a multiscale analysis. Compos Struct. 2005;71:388–396.
- Hashemi SH, Mojtaba Z, Nazemnezhad R. An exact analytical approach for free vibration of mindlin rectangular nano plates via non local elasticity. Compos Struct. 2013;100:290–299.
- Anomshoa ARSA, Shahidi SH, Kamrani M. Fundamental size dependant natural frequencies of non uniform orthotropic nano scaled plates using non local variational principle and finite element method. Appl Math Modell. 2013;37:7047–7061.
- Shen SH. Nonlinear bending of functionally graded carbon nanotube- reinforced composite plates in thermal environments. Compos Struct. 2009;91:9–19.
- Shooshtari A, Rafiee M. Vibration characteristics of nanocomposite plates under thermal conditions including nonlinear effects. Int J Appl Res Mech Eng. 2011;1:60–69.
- Wang Z-X, Shen H-S. Nonlinear vibration and bending of sandwich plates with nanotube-reinforced composite face sheets. Compos Part B. 2012;43(2):411–421.
- Zhu P, Lei ZX, Liew KM. Static and free vibration analyses of carbon nanotube-reinforced composite plates using finite element method with first order shear deformation plate theory. Compos Struct. 2012;94:1450–1460.
- Kundalwal SI, Ray MC. Effective properties of a novel composite reinforced with short carbon fibers and radially aligned carbon nanotubes. Mech Mater. 2012;53:47–60.
- Oskouie MF, Hassanzadeh-Aghdam MK, Ansari R. A new numerical approach for low velocity impact response of multiscale-reinforced nanocomposite plates. Eng Comput. 2019;37:713–730.
- Khare S, Mittal ND. Axisymmetric bending and free vibration of symmetrically laminated circular and annular plates having elastic edge constraints. Ain Shams Eng J. 2019;10(2):343–352.
- Ziou H, Guenfoud H, Guenfoud M. Buckling analysis behavior of functionally graded beams. Jordan J Civ Eng. 2020;14(3):347–358.
- Ziou H, Guenfoud H, Guenfoud M. A simple higher-order shear deformation theory for static bending analysis of functionally graded beams. Jordan J Civ Eng. 2021;15(2):209–224.
- Raghavandra S, Subba RDN, Prabhakara SS. Tensile, impact and fracture toughness properties of banana fibre-reinforced polymer composites. Adv Mater Process Technol. 2020;6(4):661–668.
- Singh SK, Chakrabarti A, Bera P, et al. An efficient C0 FE model for the analysis of composite and sandwich laminates with general layup. L. A. J. Solids Struct. 2011;8(2):197–212.
- Badrish A, Morchhale A, Kotkunde N, et al. Experimental and finite element studies of springback using split-ring test for Inconel 625 alloy. 2020;6(3):540–546.
- Purohit R, Qureshi MMU, Jain A. Forming behaviour of aluminium matrix nano Al2O3 composites for automotive applications. Adv Mater Process Technol. 2020;6(2):272–283.
- Han Y, Elliott J. Molecular dynamics simulations of the elastic properties of polymer/carbon nanotube composites. Comput Mater Sci. 2007;39:315–323.
- Esawi AMK, Farag MM. Carbon nanotube reinforced composites: potential and current challenges. Mater Des. 2007;28:2394–2401.
- Fidelus JD, Wiesel E, Gojny FH, et al. Thermo-mechanical properties of randomly oriented carbon/epoxy nanocomposites. Compos Part A Appl Sci Manuf. 2005;36:1555–1561.
- Liew KM, Wang J, Ng TY, et al. Free vibration and buckling analyses of shear deformable plates based on FSDT meshfree method. J Sound Vib. 2004;276:997–1017.
- Zhang CL, Shen HS. Temperature-dependent elastic properties of single-walled carbon nanotubes: prediction from molecular dynamics simulation. Appl Phys Lett. 2006;2006:89.