[1] Samimi, K., Kamali-Bernard, S., Akbar Maghsoudi, A., Maghsoudi, M. and Siad, H. (2017) ,Influence of pumice and zeolite on compressive strength, transport properties and resistance to chloride penetration of high strength self-compacting concretes. Construction and Building Materials, Elsevier. Volume (151), Page(292–311).
[2] Samimi, K., Kamaragi, G.R.D. and Le Roy, R. (2019) ,Microstructure, thermal analysis and chloride penetration of self-compacting concrete under different conditions. Magazine of Concrete Research, Thomas Telford Ltd. Volume (71), Page(126–43).
[3] Samimi, K., Farahani, M., Pakan, M. and Shirzadi Javid, A.A. (2022) ,Influence of Pumice and Metakaolin on Compressive Strength and Durability of Concrete in Acidic Media and on Chloride Resistance under Immersion and Tidal Conditions. Iranian Journal of Science and Technology - Transactions of Civil Engineering, Springer. Volume (46), Page(1153–1175).
[4] Miller, S.A., Horvath, A. and Monteiro, P.J.M. (2018) ,Impacts of booming concrete production on water resources worldwide. Nature Sustainability, Nature Publishing Group. Volume (1), Page(69–76).
[5] Samimi, K. and Shirzadi Javid, A.A. (2021) ,Magnesium Sulfate (MgSO4) Attack and Chloride Isothermal Effects on the Self-consolidating Concrete Containing Metakaolin and Zeolite. Iranian Journal of Science and Technology - Transactions of Civil Engineering, Springer. Volume (45), Page(165–180).
[6] Oey, T., Kumar, A., Bullard, J.W., Neithalath, N. and Sant, G. (2013) , Magnesium Sulfate (MgSO4) Attack and Chloride Isothermal Effects on the Self-consolidating Concrete Containing Metakaolin and Zeolite. Journal of the American Ceramic Society, Wiley Online Library. Volume (96), Page(1978–1990).
[7] Korayem, A.H., Tourani, N., Zakertabrizi, M., Sabziparvar, A.M. and Duan, W.H. (2017) ,A review of dispersion of nanoparticles in cementitious matrices: Nanoparticle geometry perspective. Construction and Building Materials, Elsevier. Volume (153), Page(346–357).
[8] Qiu, L., Yang, X., Gou, X., Yang, W., Ma, Z.F., Wallace, G.G. et al. (2010) ,Dispersing carbon nanotubes with graphene oxide in water and synergistic effects between graphene derivatives. Chemistry - A European Journal, Wiley Online Library. Volume (16), Page(10653–10658).
[9] Kim, D.H., Yun, Y.S. and Jin, H.J. (2012) ,Difference of dispersion behavior between graphene oxide and oxidized carbon nanotubes in polar organic solvents. Current Applied Physics, Elsevier. Volume (12), Page(637–642).
[10] Gong, K., Pan, Z., Korayem, A.H., Qiu, L., Li, D., Collins, F. et al. (2015) ,Reinforcing Effects of Graphene Oxide on Portland Cement Paste. Journal of Materials in Civil Engineering, American Society of Civil Engineers. Volume (27), Page(A4014010).
[11] Xu, Y., Zeng, J., Chen, W., Jin, R., Li, B. and Pan, Z. (2018) ,A holistic review of cement composites reinforced with graphene oxide. Construction and Building Materials, Elsevier. Volume (171), Page(291–302).
[12] Seddighi, F., Pachideh, G. and Salimbahrami, S.B. (2021) ,A study of mechanical and microstructures properties of autoclaved aerated concrete containing nano-graphene. Journal of Building Engineering, Elsevier. Volume (43), Page ( 103106).
[13] Pachideh, G., Gholhaki, M. and Rezaifar, O. (2021) ,Experimental Study on Engineering Properties and Microstructure of Expansive Soils Treated by Lime Containing Silica Nanoparticles Under Various Temperatures. Geotechnical and Geological Engineering, Springer. Volume (39), Page (4157–4168).
[14] Pachideh, G., Gholhaki, M., Moshtagh, A. and Felaverjani, M.K. (2019) ,An investigation on the effect of high temperatures on the mechanical properties and microstructure of concrete containing multiwalled carbon nanotubes. Materials Performance and Characterization, ASTM International. Volume (8), Page (503–517).
[15] Chen, Z., Zhou, X., Wang, X. and Guo, P. (2018) ,Mechanical behavior of multilayer GO carbon-fiber cement composites. Construction and Building Materials, Elsevier. Volume (159), Page(205–212).
[16] Meng, W. and Khayat, K.H. (2016) ,Mechanical properties of ultra-high-performance concrete enhanced with graphite nanoplatelets and carbon nanofibers. Composites Part B: Engineering, Elsevier. Volume (107), Page(113–122).
[17] Yang, H., Monasterio, M., Cui, H. and Han, N. (2017) ,Experimental study of the effects of graphene oxide on microstructure and properties of cement paste composite. Composites Part A: Applied Science and Manufacturing, Elsevier. Volume (102), Page(263–272).
[18] Samimi, K. and Pakan, M. (2022) ,Study of mechanical properties and microstructure of cement paste containing graphene based on surfactant. Journal of Structural and Construction Engineering, Iranian Society of Structural Engineering (ISSE).
[19] Li, X., Korayem, A.H., Li, C., Liu, Y., He, H., Sanjayan, J.G. et al. (2016) ,Incorporation of graphene oxide and silica fume into cement paste: A study of dispersion and compressive strength. Construction and Building Materials, Elsevier. Volume (123), Page(327–335).
[20] Erzengin, S.G., Kaya, K., Perçin Özkorucuklu, S., Özdemir, V. and Yıldırım, G. (2018) ,The properties of cement systems superplasticized with methacrylic ester-based polycarboxylates. Construction and Building Materials, Elsevier. Volume (166), Page(96–109).
[21] Zhao, L., Guo, X., Ge, C., Li, Q., Guo, L., Shu, X. et al. (2016) ,Investigation of the effectiveness of PC@GO on the reinforcement for cement composites. Construction and Building Materials, Elsevier. Volume (113), Page(470–478).
[22] ASTM C494/C494M−19. (2019) ,Standard Specification for Chemical Admixtures for Concrete [Internet]. ASTM Int. ASTM International, Philadelphia.
[23] ASTM C150 / C150M-20. (2020) ,Standard Specification for Portland Cement. ASTM Int. p. 1–8.
[24] ASTM C31 / C31M - 21a. (2021) ,Standard Practice for Making and Curing Concrete Test Specimens in the Field. ASTM International, Philadelphia. p. 1–7.
[25] ASTM C511-19. (2019) ,Standard Specification for Mixing Rooms, Moist Cabinets, Moist Rooms, and Water Storage Tanks Used in the Testing of Hydraulic Cements and Concretes. ASTM Stand. Guid.
[26] ASTM C109 / C109M-21. (2021) ,Standard Test Method for Compressive Strength of Hydraulic Cement Mortars (Using 2-in. or [50 mm] Cube Specimens). ASTM. ASTM International, Philadelphia.
[27] ASTM C348-21. (2020) ,Standard Test Method for Flexural Strength of Hydraulic-Cement Mortars. ASTM International, Philadelphia.
[28] ASTM C642-13. (2013) ,Standard test method for density, absorption, and voids in hardened concrete [Internet]. ASTM Int. ASTM International, Philadelphia. p. 1–3.
[29] ASTM C1585-11. (2011) ,Standard Test Method for Measurement of Rate of Absorption of Water by Hydraulic Cement Concretes. ASTM Int. ASTM Philadelphia.
[30] Du, H. and Pang, S.D. (2015) ,Enhancement of barrier properties of cement mortar with graphene nanoplatelet. Cement and Concrete Research, Elsevier. Volume (76), Page(10–19).
[31] Peng, H., Ge, Y., Cai, C.S., Zhang, Y. and Liu, Z. (2019) ,Mechanical properties and microstructure of graphene oxide cement-based composites. Construction and Building Materials, Elsevier. Volume (194), Page(102–109).
[32] Du, H., Gao, H.J. and Pang, S.D. (2016) ,Improvement in concrete resistance against water and chloride ingress by adding graphene nanoplatelet. Cement and Concrete Research, Elsevier. Volume (83), Page(114–123).