References
- Vakhshouri B, Nejadi S. Mix design of light-weight self-compacting concrete. Case Stud Const Mat. 2016;4:1–14.
- Mo KH, Alengaram UJ, Jumaat MZ. Bond properties of lightweight concrete – a review. Const Build Mat. 2016;112:478–496.
- Juradin S, Baloevic G, Harapin A. Experimental testing of the effects of fine particles on the properties of the self-compacting lightweight concrete. Adv Mat Sci Eng. 2012;2012:1–8.
- Abouhussien AA, Hassan AAA, Ismail MK. Properties of semi-lightweight self-consolidating concrete containing lightweight slag aggregate. Const Build Mat. 2015;75:63–73.
- EPG. The European guidelines for self-compacting concrete specification production and use. 2005. http://www.efnarc.org/pdf/SCCGuidelinesMay2005.pdf.
- Yehia S, Hamaydeh M, Farrag S. High-strength lightweight SCC matrix with partial normal-weight coarse-aggregate replacement: strength and durability evaluations. J Mat Civil Eng. 2014;26:1–10.
- Mo KH, Yeap KW, Alengaram UJ, et al. Bond strength evaluation of palm oil fuel ash-based geopolymer normal weight and lightweight concretes with steel reinforcement. J Adhes Sci Technol. 2018;32:19–35.
- Ali AA, Erhan Y, Ozge AC. Water transport of lightweight concrete with different aggregate saturation levels. ACI Mat J. 2015;112:681–691.
- Lachemi M, Bae S, Hossain KMA, et al. Steel–concrete bond strength of lightweight self-consolidating concrete. Mater Struct. 2009;42:1015–1023.
- Mor A. Steel-concrete bond in high-strength lightweight concrete. ACI Mat J. 1993;89:76–82.
- Hossain KMA. Bond characteristics of plain and deformed bars in lightweight pumice concrete. Const Build Mat. 2008;22:1491–1499.
- Guneyisi E, Gesoglu M, Ipek S. Effect of steel fiber addition and aspect ratio on bond strength of cold-bonded fly ash lightweight aggregate concrete. Const Build Mat. 2013;47:358–365.
- Chen HJ, Huang CH, Kao ZY. Experimental investigation on steel-concrete bond in lightweight and normal weight concrete. Struct Eng Mech. 2004;17:141–152.
- Bogas JA, Gomes MG, Real S. Bonding of steel reinforcement in structural expanded clay lightweight aggregate concrete: the influence of failure mechanism and concrete composition. Const Build Mat. 2014;65:350–359.
- Ohama Y. Handbook of polymer-modified concrete and mortars. Koriyama: Nihon University; 1995; 245 p.
- Ates M. A review on conducting polymer coatings for corrosion protection. J Adhes Sci Technol. 2016;30:1510–1536.
- Assaad JJ. Feasibility of specialty cement possessing improved bond properties. Adv Cem Res. 2017;29:302–312. http://dx.doi.org/10.1680/jadcr.17.00031
- Lee YH, Kim MS, Kim H, et al. Experimental study on bond strength of fiber reinforced polymer rebars in normal strength concrete. J Adhes Sci Technol. 2013;27:508–522.
- Issa C, Assaad JJ. Stability and bond properties of polymer-modified self-consolidating concrete for repair applications. Mat Struct. 2017;50:1–16.
- Assaad JJ. Development of polymer-modified cement for adhesive and repair applications. Const Build Mat. 2018;163:139–148.
- Ribeiro MSS, Goncalves AF, Branco FAB. Styrene-butadiene polymer action on compressive and tensile strengths of cement mortars. Mater Struct. 2008;41:1263–1273.
- Assaad JJ, Daou Y. Behavior of structural polymer-modified concrete containing recycled aggregates. J Adhes Sci Tech. 2017;31:874–896.
- Assaad JJ, Issa C. Mixture optimization of polymer-modified lightweight SCC. Mag Conc Res. 2017;69:745–756. http://dx.doi.org/10.1680/jmacr.16.00409
- Kim DJ, Kim MS, Yun GY, et al. Bond strength of steel deformed rebars embedded in artificial lightweight aggregate concrete. J Adhes Sci Technol. 2013;27:490–507.
- Assaad J, Issa C. Effect of recycled acrylic-based polymers loss on bond stress-slip behavior in reinforced concrete structures. J Mat Civil Eng. 2017;29.
- Assaad J, Daou Y. Cementitious grouts with adapted rheological properties for injection by vacuum techniques. Cem Conc Res. 2014;59:43–54.
- Metelli G, Plizzari G. Influence of the relative rib area on bond behavior. Mag Conc Res. 2014;66:277–294.
- ACI 213R. Guide for structural lightweight-aggregate concrete. Farmington Hills: American Concrete Institute; 2014.
- Yang KH, Chung HS, Ashour AF. Influence of type and replacement level of recycled aggregates on concrete properties. ACI Mat J. 2008;105:289–296.
- Assaad JJ. Influence of recycled aggregates on dynamic/static stability of self-consolidating concrete. J Sust Cem-Based Mater. 2017;6:345–365.
- ACI Committee 548. Guide for the use of polymers in concrete. Farmington Hills: American Concrete Institute; 2011.
- ASTM A944. Standard test method for comparing bond strength of steel reinforcing bars to concrete using beam-end specimens. West Conshohocken: ASTM Standards; 2015; 12 p.
- Expanded Shale, Clay & Slate Institute (ESCSI). Internal curing using expanded shale, clay and slate lightweight aggregate. Publication #. 2006;4362:8 p.
- Kwasny J, Sonebi M, Taylor SE, et al. Influence of the type of coarse lightweight aggregate on properties of semi lightweight self-consolidating concrete. J Mater Civil Eng. 2012;24:1474–1483.
- Assaad JJ, Matar P. Regression models to predict SCC pressure exerted on formworks containing vertical and transverse reinforcing bars. Mater Struct. 2018;51:62. https://doi.org/10.1617/s11527-018-1188-x
- Fib (International Federation for Structural Concrete). Model code for concrete structures. Berlin: Ernst & Sohn; 2013.
- ACI 318-14. Building code requirements for reinforced concrete. Farmington Hills: American Concrete Institute; 2014.
- EN 1992-1-1. Eurocode 2: design of concrete structures – part 1-1: general rules and rules for buildings. London: British Standards Institution; 2004.