[1] H. Ebrahimnezhad Khaljiri, R. Eslami Farsani, H. Khorsand, K. Abbas Banaie, Hybridization effect of fibers reinforcement on tensile properties of epoxy composites, Journal of Science and Technology of Composite, Vol. 1, No. 2, pp. 21-28, 2015. (in Persian).
[2] F. Bahari-Sambran, R. Eslami-Farsani, H. Ebrahimnezhad-Khaljiri, Experimental investigation of flexural behavior of basalt fibers/epoxy-aluminum laminate composites containing nanoclay particles, Iranian Journal of Manufacturing Engineering, Vol. 5, No. 1, pp. 45-54, 2018. (in Persian).
[3] M. Y. Khalid, Z.U. Arif, A. Al Rashid, M.I. Shahid, W. Ahmed, A.F. Tariq, Z. Abbas, Interlaminar shear strength (ILSS) characterization of fiber metal laminates (FMLs) manufactured through VARTM process, Forces in Mechanics, Vol. 4, 100038, 2021.
[4] M. Shamohammadi Maryan, H. Ebrahimnezhad-Khaljiri, R. Eslami-Farsani, The experimental assessment of the various surface modifications on the tensile and fatigue behaviors of laminated aluminum/aramid fibers-epoxy composites, International Journal of Fatigue, Vol. 154, 106560, 2022.
[5] R. Eslami-Farsani, H. Aghamohammadi, S. M. R. Khalili, H. Ebrahimnezhad-Khaljiri, H. Jalali, Recent trend in developing advanced fiber metal laminates reinforced with nanoparticles: A review study, Journal of Industrial Textiles, Accessed on 26 August 2020. doi:10.1177/1528083720947106.
[6] A. Vlot, M. Krull, Impact damage resistance of various fibre metal laminates. Journal de Physique IV Proceedings, EDP Sciences, Vol. 07, pp. 1045-4050, 1997.
[7] J. I. Múgica, L. Aretxabaleta, I. Ulacia, J. Aurrekoetxea, Impact characterization of thermoformable fibre metal laminates of 2024-T3 aluminium and AZ31B-H24 magnesium based on self-reinforced polypropylene, Composites Part A: Applied Science and Manufacturing, Vol. 61, pp. 67-75, 2014.
[8] J. Fan, Z. W. Guan, W. J. Cantwell, Numerical modelling of perforation failure in fibre metal laminates subjected to low velocity impact loading, Composite Structures, Vol. 93, No. 9, pp. 2430-2436, 2011.
[9] T. Pärnänen, R. Alderliesten, C. Rans, T. Brander, O. Saarela, Applicability of AZ31B-H24 magnesium in Fibre Metal Laminates – An experimental impact research, Composites Part A: Applied Science and Manufacturing, Vol. 43, No. 9, pp. 1578-1586, 2012.
[10] M. H. Pol, G. Liaghat, E. Zamani, A. Ordys, Investigation of the ballistic impact behavior of 2D woven glass/epoxy/nanoclay nanocomposites, Journal of Composite Materials, Vol. 49, No. 12, pp. 1449-1460, 2015.
[11] S. D. Malingam, F. A. Jumaat, L. F. Ng, K. Subramaniam, A. F. A. Ghani, Tensile and impact properties of cost-effective hybrid fiber metal laminate sandwich structures, Advances in Polymer Technology, Vol. 37, No. 7, pp. 2385–2393, 2018.
[12] L. M. G. Vieira, J. C. dos Santos, T. H. Panzera, J. C. C. Rubio, F. Scarpa, Novel fibre metal laminate sandwich composite structure with sisal woven core, Industrial Crops and Products, Vol. 99, pp.189–195, 2017.
[13] M. Najafi, R. Ansari, Influence of thermal aging on mechanical properties of fiber metal laminates hybridized with nanoclay, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, Vol. 233, No. 19-20, pp. 7003-7018, 2019.
[14] M. A. Azghan, R. Eslami-farsani, The effects of stacking sequence and thermal cycling on the flexural properties of laminate composites of aluminium-epoxy / basalt-glass fibres, Materials Research Express, Vol. 5, 025302, 2018.
[15] A. da Costa, D. F. N. R. da Silva, D. N. Travessa, E. C. Botelho, The effect of thermal cycles on the mechanical properties of fiber-metal laminates, Materials and Design, Vol. 42, pp. 434-440, 2012.
[16] H. Ebrahimnezhad-Khaljiri, R. Eslami-Farsani, S. Talebi, Investigating the high velocity impact behavior of the laminated composites of aluminum/jute fibers- epoxy containing nanoclay particles, Fibers and Polymers, Vol. 21, No. 11, pp. 2607-2613, 2020.
[17] H. Rahmani, R. Eslami-Farsani, H. Ebrahimnezhad-Khaljiri, High velocity impact response of aluminum- carbon fibers-epoxy laminated composites toughened by nano silica and zirconia, Fibers and Polymers, Vol. 21, No. 1, pp. 170-178, 2020.
[18] M. Najafi, R. Eslami-Farsani, A. Saeedi, H. Ebrahimnezhad-Khaljiri, The effect of environmental conditions on the synthetic fiber-reinforced epoxy composites, S. M. Rangappa, J. Parameswaranpillai, S. Siengchin, S. Thomas (Eds), Handbook of Epoxy/Fiber Composites, pp. 16.1-16.51, Singapore: Springer, 2022.
[19] G. C. Papanicolaou, A. G. Xepapadaki, G. D. Tagaris, Effect of thermal shock cycling on the creep behavior of glass-epoxy composites, Composite Structures, Vol. 88, No. 3, pp. 436-442, 2009.
[20] T. Akderya, Investigation of thermal-oil environmental ageing effect on mechanical and thermal behaviours of E-glass fibre / epoxy composites, Journal of Polymer Research, Vol. 25, 214, 2018.
[21] B. C. Ray, Temperature effect during humid ageing on interfaces of glass and carbon fibers reinforced epoxy composites, Journal of Colloid and Interface Science, Vol. 298, No. 1, pp. 111-117, 2006.
[22] H. Ebrahimnezhad-Khaljiri, Hygrothermal aging and their influence on mechanical properties of the bio-composites, C. Muthukumar, S. Krishnasamy, S. M. K. Thiagamani, S. Siengchin, (Eds), Aging Effects on Natural Fiber-Reinforced Polymer Composites: Durability and Life Prediction. pp. 115-136, Singapore: Springer, 2022.
[23] B. Müller, M. Hagenbeek, J. Sinke, Thermal cycling of (heated) fibre metal laminates, Composite Structures, Vol. 152, pp. 106-116, 2016.
[24] M. Zhang, B. Sun, B. Gu, Accelerated thermal ageing of epoxy resin and 3-D carbon fiber/epoxy braided composites, Composites Part A: Applied Science and Manufacturing, Vol. 85, pp. 163-171, 2016.
[25] B. C. Ray, Adhesion of Glass / Epoxy Composites Influenced by Thermal and Cryogenic Environments, Journal of Applied Polymer Science, Vol. 102, No. 2, pp. 1943-1949, 2006.