-Ahmed, H. U., Faraj, R. H., Hilal, N., Mohammed, A. A., & Sherwani, A. F. H. (2021), “Use of recycled fibers in concrete composites: A systematic comprehensive review”, Composites Part B: Engineering, 108769.
-ASTM C1611, (2018), “Standard test method for slump flow of self-consolidating concrete, ASTM International”, West Conshohocken, PA.
-ASTM C1621, (2017), “Standard Test Method for Passing Ability of Self-Consolidating Concrete by J-Ring, ASTM International, West Conshohocken, PA.
-ASTM C293, (2016), “Standard Test Method for Flexural Strength of Concrete (Using Simple Beam With Center-Point Loading)”, ASTM International, West Conshohocken, PA, pp. 19428-2959.
-Awal, A. A., & Mohammadhosseini, H., (2016), “Green concrete production incorporating waste carpet fiber and palm oil fuel ash”, Journal of Cleaner Production, 137, pp.157-166.
-EFNARC, (2005), “The European guidelines for self-compacting concrete, Specification, Production and Use”.
-Cunningham, P. R., Green, P. G., & Miller, S. A., (2021), “Utilization of post-consumer carpet calcium carbonate (PC4) from carpet recycling as a mineral resource in concrete”, Resources, Conservation and Recycling, 169, pp.105496.
-Choobbasti, A. J., Samakoosh, M. A., & Kutanaei, S. S., (2019), “Mechanical properties soil stabilized with nano calcium carbonate and reinforced with carpet waste fibers”, Construction and Building Materials, 211, pp.1094-1104.
-De Gutiérrez, R. M., Diaz, L. N., & Delvasto, S., (2005), “Effect of pozzolans on the performance of fiber-reinforced mortars”, Cement and Concrete Composites, 27(5), pp.593-598.
-BS EN 12350-10, (2010), “Testing fresh concrete, Self-compacting concrete, L box test, British Standard Int.
- Fashandi, H., Pakravan, H. R., & Latifi, M., (2019), “Application of modified carpet waste cuttings for production of eco-efficient lightweight concrete”, Construction and Building Materials, 198, pp.629-637.
-EN 12350-9, Testing self-compacting concrete: V-Funnel test, British Standard Int.
- Karahan, O., & Atiş, C. D., (2011), “The durability properties of polypropylene fiber reinforced fly ash concrete, Materials & Design, 32(2), pp.1044-1049.
-Mo, K. H., Alengaram, U. J., Jumaat, M. Z., & Liu, M. Y. J., (2015), “Contribution of acrylic fibre addition and ground granulated blast furnace slag on the properties of lightweight concrete”, Construction and Building Materials, 95, pp.686-695.
-Mohammad Hosseini, H., Alyousef, R., Lim, N. H. A. S., Tahir, M. M., Alabduljabbar, H., & Mohamed, A. M., (2020), “Creep and drying shrinkage performance of concrete composite comprising waste polypropylene carpet fibres and palm oil fuel ash”, Journal of Building Engineering, 30, 101250.
-Mohammadhosseini, H., & Awal, A. S. M. A., (2014), "Physical and mechanical properties of concrete containing fibers from industrial carpet waste, Doctoral dissertation, Universiti Teknologi Malaysia.
-Ramezanianpour, A. A., Esmaeili, M., Ghahari, S. A., & Najafi, M. H., (2013), "Laboratory study on the effect of polypropylene fiber on durability, and physical and mechanical characteristic of concrete for application in sleepers", Construction and Building Materials, 44, pp.411-418.
- Pereira-de-Oliveira, L. A., Castro-Gomes, J. P., & Nepomuceno, M. C., (2012), "Effect of acrylic fibres geometry on physical, mechanical and durability properties of cement mortars", Construction and Building Materials, 27(1), pp.189-196.
-Mohammad hosseini, H., & Yatim, J. M., (2017), "Evaluation of the effective mechanical properties of concrete composites using industrial waste carpet fiber", INAE Letters, 2(1), pp.1-12.
-Mastali, M., Dalvand, A., & Sattarifard, A. R., (2016), "The impact resistance and mechanical properties of reinforced self-compacting concrete with recycled glass fibre reinforced polymers", Journal of Cleaner Production, 124, pp.312-324.
-Packard, R. G., (1984), “Thickness design for concrete highway and street pavements”.
-Silva, E. R., Coelho, J. F. J., & Bordado, J. C., (2013), “Strength improvement of mortar composites reinforced with newly hybrid-blended fibres”, Influence of fibres geometry and morphology, Construction and Building Materials, 40, pp.473-480.
-Schmidt, H., & Cieślak, M., (2008), “Concrete with carpet recyclates: Suitability assessment by surface energy evaluation”, Waste Management, 28(7), pp.1182-1187.
-Wang, Y., Zureick, A. H., Cho, B. S., & Scott, D. E., (1994), “Properties of fibre reinforced concrete using recycled fibres from carpet industrial waste”, Journal of materials science, 29(16), pp.4191-4199.
-Wang, Y., (1999), “Utilization of recycled carpet waste fibers for reinforcement of concrete and soil”, Polymer-Plastics Technology and Engineering, 38(3),
pp.533-546.
-Zarei, A., Rooholamini, H., & Ozbakkaloglu, T., (2021), “Evaluating the Properties of Concrete Pavements Containing Crumb Rubber and Recycled Steel Fibers Using Response Surface Methodology”, International Journal of Pavement Research and Technology, pp.1-15.