https://orcid.org/0000-0001-7643-9747
References
- Ogunsanya IG, Strong V, Hansson CM, et al. Corrosion behaviour of austenitic 304L and 316LN stainless steel clad reinforcing bars in cracked concrete. Mater and Corr. 2020;71:1066–1080.
- Mehta PK, Monterio PJM, et al. Concrete micro structure properties and material. 3rd ed. New York (NY): McGraw-Hill; 2006.
- Neville AM, Brooks jj et al. Concrete technology. 2nd edition. Pearson Education Canada; March 25, 2010.
- Inan Sezer G. Compressive strength and sulphur resistance of limestone and/or silica fume mortars. Constr Build Mater. 2012;26:613–618.
- Giner VT, Ivorra S, Baeza FJ, et al. Silica fume admixture effect on the dynamic properties of concrete. Constr Build Mater. 2011;25(8):3272–3277.
- Siddique R, Klaus J. Influence of metakaolin on the properties of mortar and concrete: a review. Appl Clay Sci. 2009;43(3–4):392–400.
- Mervin EM, Anand N, Prince Arulraj G, et al. Rheological and mechanical characterization of self-compacting concrete with utilization of supplementary sustainable cementitious materials. Earth Environ Sci. 2020;491(1):012037.
- Song H-W, Saraswathy V. Studies on the corrosion resistance of reinforced steel in concrete with ground granulated blast-furnace slag-An overview. J Hazard Mater. 2006;138(2):226–233.
- Shaikh FUA, Supit SWM. Chloride induced corrosion durability of high-volume fly ash concretes containing nano particles. Constr Build Mater. 2015;99:208–225.
- Chandra S, Berndtson L. Use of silica fume in concrete. Waste Mater Used in Concr Manuf. 1996;1:554–623.
- Saraswathy V, Song H-W. Corrosion performance of rice husk ash blended concrete. Constr Build Mater. 2007;21(8):1779–1784.
- Mohamed AM. Influence of nano materials on flexural behavior and compressive strength of concrete. Hou Build Natio Res Cen. 2014;12:212–225.
- Kumar Sarker P. Strength of reinforcing steel embedded in fly ash-based geopolymer concrete. Mater Struct. 2011;44(5):1021–1030.
- Simoolavi Pehkonen, Shaojun Yuan. Tailored Thin Coatings for Corrosion Inhibition using a molecular approach. academic press; London, UK, 23:2-402.
- Sideris KK, Savva AE. Durability of mixtures containing calcium nitrite-based corrosion inhibitor. Cem Concr Compos. 2005;27(2):277–287.
- Jayasree S, Ganesan N, Abraham R. Effects of ferro cement jacketing on the flexural behavior of beam with corroded reinforcement. Constr Build Mater. 2016;121:92–99.
- Guneyisi E, Gesoglu M, Karaboga F, et al. Corrosion behavior of reinforcing steel embedded in chloride contaminated concretes with and without metakaolin. Compos-Part B. 2013;45:1288–1295.
- Kennedy C, Gbinu SK, Achiemeet Al LO. Effect of corrosive environment on reinforced concrete structures pullout bond strength of corroded and resins/exudates coated reinforcement. Inter J Sci Eng Res. 2018;9:1123–1134.
- Moon HY, Shin KJ. Evaluation on steel bar corrosion embedded in antiwashout underwater concrete containing mineral admixtures. Cem Concr Res. 2006;36(3):521–529.
- Haddad RH, Al Dalou AA. Experimental study on bond behavior between corrosion-cracked reinforced concrete and CFRP sheets. J Adhesi Sci and Tech. 2018;32(6):590–608.
- Pradhan B, Bhattacharjee B. Performance evaluation of rebar in chloride contaminated concrete by corrosion rate. Constr Build Mater. 2009;23(6):2346–2356.
- Pan C, Chen N, He J, Liu S, et al. Effects of corrosion inhibitor and functional components on the electrochemical and mechanical properties of concrete subject to chloride environment. Constr Build Mater. 2020;260:119724.
- Mohammed Sonebi, Richard Davidson, David Cl. Bond between Reinforcement and Concrete – Influence of Steel Corrosion. Inter conf on dura of build mater and compo. Porto-Portugal April12th-15th;2011.
- Hou J, Chung DDL. Effect of admixtures in concrete on the corrosion resistance of steel reinforced concrete. Corr Sci. 2000;42(9):1489–1507.
- Hosking NC, Strom MA, Shipway PH, et al. Corrosion resistance of zinc–magnesium coated steel. Corr Sci. 2007;49(9):3669–3695.
- Hak Lee Y, Kim MS, Kim H, et al. Experimental study on bond strength of fiber reinforced polymer rebars in normal strength concrete. J Adhesi Sci and Tech. 2013;27:508–522.
- Xing G, Zhou C, Wu T, et al. Experimental study on bond behaviour between plain reinforcing bars and concrete. Adv Struc Eng. 2015;2015:1–9.
- Faye PN, Ye Y, Diao B. Bond effects between concrete and steel bar using different diameter bars and different initial crack width. Adv Struc Eng. 2017;2017:1–11.
- Carmichae J, Arulraj GP. The investigation of the is strength and permeability studies on concrete with nano studies. Int J Civ Eng Tec. 2017;8:132–139.
- Varghese A, Anand N, Prince AG, et al. Influence of fibers on bond strength of concrete exposed to elevated temperature. J Adhesi Sci and Tech. 2019;33(14):1521–1543.
- Barkat A, Kenai S, Menadi B, et al. Effects of local metakaolin addition on rheological and mechanical performance of self compacting limestone cement concrete. J Adhesi Sci and Tech. 2019;33(9):963–985.
- Mo KH, Yeap KW, Alengaram UJ, et al. Bond strength evaluation of palm oil fuel ashbased geopolymer normal weight and lightweight concretes with steel reinforcement. J Adhesi Sci and Tech. 2018;32(1):19–35.
- IS:2692015. Ordinary portland cement – Specification. IS 269. Bureau of Indian standards (BIS), New Delhi, India.
- IS 3832016. Specification for coarse and fine aggregates from natural sources for concrete. Bureau of Indian standards, New Delhi, India.
- IS: 10262-2019. Concrete mix proportioning—Guidelines; 2019.
- ASTM C876, Standards test method for half-cell potentials of reinforcing steel in concrete; 1991.
- Indian Standard Methods of Testing Bond in Reinforced Concrete Part 1 Pull-Out Test 2007. Bureau of Indian Standards, Manak Bhavan, New Delhi.
- IS, BIS Code. "516–1959." Code of practice for methods of tests for strength of concrete; 2002.
- Standard test method for electrical indication of concrete’s ability to resist chloride ion penetration. ASTM C 1202-91. American Society for Testing and Materials; 1992.
- Sanjuan MA. Effect of curing temperature on corrosion of steel bars embedded in calcium aluminate mortars exposed to chloride solutions. Corro Sci. 1999;41:335–350.
- Mardani-Aghabaglou A, Sezer GI, Ramyar K. Comparssion of flyash and silica fume and metakaolin from mechanical properties and durable performance of mortar mixtures view point. Constr Build Mater. 2014;70:17–25.
- Almusallam AA, Al-Gahtani AS, Aziz AR, et al. Effect of reinforcement corrosion on bond strength. Constr Build Mater. 1996;10:123–129.
- Li L, Wang Q, Zhang G, et al. A method of detecting the cracks of concrete undergo high-temperature. Constr Build Mater. 2018;162:345–358.
- Arena A, Delle Piane C, Sarout J. A new computational approach to cracks quantification from 2D image analysis: application to micro-cracks description in rocks. Comput Geosci. 2014;66:106–120.
- Mindess S, Young, J. F., Darwin, D et al. Measuring and mentoring and modelling concrete properties. Concr Tech and engine. Northwestern University, USA. 2003;644.
- Kim D-J, Kim MS, Yun GY, et al. Bond strength of steel deformed rebars embedded in artificial lightweight aggregate concrete. J Adhesi Sci and Tech. 2013;27(5–6):490–507.
- Tanyildizi H, Coskun A, Somunkiran I, et al. An experimental investigation of bond and compressive strength of concrete with mineral admixtures at high temperatures. Arabian.J for Sci Eng. 2008;33:1–8.
- Qing Y, Zenan Z, Deyu K, et al. Influence of nano-SiO2 addition on properties of hardened cement paste as compared with silica fume. Constr Build Mater. 2007;21(3):539–545.
- Keleştemur O, Demirel B. Effect of metakaolin on the corrosion resistance of structural lightweight concrete. Constr Build Mater. 2015;81:172–178.
- Ghahari SA, Ramezanianpour AM, Ramezanianpour AA, et al. An accelerated test method of simultaneous carbonation and chloride ion ingress: durability of silica fume concrete in severe environments. Mat Sci and Eng. 2016;2016:1–12.
- Wee TH, Suryavanshi AK, Tin SS, et al. Evaluation of Rapid Chloride Permeability Test (RCPT) results for concrete containing mineral admixtures. Mate Jou. 2000;97:221–232.