[1] C.L. Page, M.M. Page, Durability of Concrete and Cement Composites, Elsevier, 2007.
[2] MK Sharbatdar, F Rahmati, Experimental evaluation of multi-functional effects of fibers on mechanical and performance properties of Roller-compacted concrete pavements (RCCP), Construction and Building Materials, 2022, 316, 125890.
[3] MK Sharbatdar, A Tajari, Experimental in-plane seismic strengthening of masonry infilled reinforced concrete frames by engineered cementitious composites (ECC), Construction and Building Materials, 2021, 293, 123529.
[4] V.R. Zivica, A. Bajza, Acidic attack of cement-based materials- a review: Part 2. Factors of rate of acidic attack and protective measures, Constr. Build. Mater. 16 (4) (2002) 215–222.
[5] Pachideh G, Gholhaki M, Moshtagh A. On the post-heat performance of cement mortar containing silica fume or Granulated Blast-Furnace Slag. Journal of Building Engineering, (2019), 24, 100757.
[6] Pachideh G, Gholhaki M. Effect of pozzolanic materials on mechanical properties and water absorption of autoclaved aerated concrete. Journal of Building Engineering, (2019), 26, 100856
[7] Amar, M., Benzerzour, M., Safhi, A.E.M., Abriak, N.-E., 2018. Durability of a cementitious matrix based on treated sediments. Case Stud. Constr. Mater. 8, 258–276.
[8] Rao, K.J., Keerthi, K., Vasam, S., 2018. Acid resistance of quaternary blended recycled aggregate concrete. Case Stud. Constr. Mater. 8, 423–433.
[9] Binici H, Aksogan O, Sevinc AH, Cinpolat E. Mechanical and radioactivity shielding performances of mortars made with cement, sand and egg shells. Construction and Building Materials. 2015 Sep 15; 93: 1145-50.
[10] Angelin AF, Lintz RC, Gachet-Barbosa LA, Osorio WR. The effects of porosity on mechanical behavior and water absorption of an environmentally friendly cement mortar with recycled rubber. Construction and Building Materials. 2017 Oct 1; 151: 534-45.
[11] Pachideh G, Gholhaki M, Ketabdari H. Effect of pozzolanic wastes on mechanical properties, durability and microstructure of the cementitious mortars. Journal of Building Engineering. 2020 May 1; 29: 101178.
[12] Patel D, Shrivastava R, Tiwari RP, Yadav RK. Properties of cement mortar in substitution with waste fine glass powder and environmental impact study. Journal of Building Engineering. 2020 Jan 1; 27: 100940.
[13] Gupta T, Siddique S, Sharma RK, Chaudhary S. Effect of aggressive environment on durability of concrete containing fibrous rubber shreds and silica fume. Structural Concrete. 2021 Oct;22(5):2611-23.
[14] Tayeh BA, Al Saffar DM. Utilization of waste iron powder as fine aggregate in cement mortar. journal of engineering research and technology. 2018;5(2).
[15] Pham NP, Toumi A, Turatsinze A. Evaluating damage of rubberized cement-based composites under aggressive environments. Construction and Building Materials. 2019 Aug 30; 217: 234-41.
[16] Tayeh BA, Al Saffar DM, Aadi AS, Almeshal I. Sulphate resistance of cement mortar contains glass powder. Journal of King Saud University-Engineering Sciences. 2020 Dec 1; 32(8):495-500.
[17] Gupta T, Siddique S, Sharma RK, Chaudhary S. Behaviour of waste rubber powder and hybrid rubber concrete in aggressive environment. Construction and Building Materials. 2019 Aug 30; 217: 283-91.
[18] Collins, F., J. Lambert, and W.H. Duan, the influences of admixtures on the dispersion, workability, and strength of carbon nanotube–OPC paste mixtures. Cement and Concrete Composites, 2012. 34(2): p. 201-207.
[19] NF EN 12390-13 AFNOR. 2013 Testing hardened concrete, in: Determination of Secant Modulus of Elasticity in Compression, 418–455.
[20] ASTM C1609/C1609M. Standard Test Method for Flexural Performance of Fiber‐Reinforced Concrete (Using Beam with Third‐Point Loading); ASTM International: West Conshohocken, PA, USA, 2012; pp. 1–9.
[21] ASTM C642-13, Standard Test Method for Density, Absorption, and Voids in Hardened Concrete, ASTM International, West Conshohocken, PA, (2013),
www.astm.org.
[22] Pliya P, Cree D. Limestone derived eggshell powder as a replacement in Portland cement mortar. Construction and Building Materials. 2015 Oct 1; 95: 1-9.
[23] Omar Ibrahim O.M, Tayeh B.A. Combined effect of lightweight fine aggregate and micro rubber ash on the properties of cement mortar. Advances in concrete construction. 2020; 10(10 (6) 537-546).
[24] Vafaei M, Allahverdi A, Dong P, Bassim N. Acid attack on geopolymer cement mortar based on waste-glass powder and calcium aluminate cement at mild concentration. Construction and Building Materials. 2018 Dec 30; 193: 363-372.
[26] Cree D, Pliya P. Effect of elevated temperature on eggshell, eggshell powder and eggshell powder mortars for masonry applications. Journal of Building Engineering. 2019, 26, 100852.
[27] Chaïd R, Kenaï S, Zeroub H, Jauberthie R. Microstructure and permeability of concrete with glass powder addition conserved in the sulphatic environment. European Journal of Environmental and Civil Engineering. 2015, 19: 2, 219-237.
[28] Othman R, Wei Chong B, Putra Jaya R, Mohd Hasan MR, Al Bakri Abdullah MM, Haziman M. Wan Ibrahim. Evaluation on the rheological and mechanical properties of concrete incorporating eggshell with tire powder. journal of materials research and technology 2021, 14: 439-451.
[29] Ramdani S, Guettala A, Benmalek ML, B.Aguiar J. Physical and mechanical performance of concrete made with waste rubber aggregate, glass powder and silica sand powder. Journal of Building Engineering. 2019, 21, 302-311.
[30] Lal Jain K, Sancheti G, Kumar Gupta L. Durability performance of waste granite and glass powder added Concrete. Construction and Building Materials. 2020, 252, 119075.
[31] Shamsudeen Abdulazeez A, Usman N, Adamu Idi M, Gabriel U. Suitability of Waste Glass Powder as Partial Cement Replacement in Concrete Subject to Chemical Aggressive Environment. International Journal of Latest Technology in Engineering, Management & Applied Science (IJLTEMAS). 2020, 9: 2, 45-52.