Authors: Davoud Beheshtizadeh, Davood Jafari

Abstract:

Concrete, with its unique properties and advantages, has gained widespread and increasing use in the construction industry, particularly in a country's infrastructure. However, concrete exhibits certain defects, most notably the presence of micro-cracks that occur after the setting process, leading to increased costs for infrastructure repair and maintenance. As a result, self-healing concretes have garnered attention in various countries in recent years. These concretes employ different mechanisms for repair, including physical, chemical, biological, and combined approaches, each with its own subsets and implementation methods. Certain mechanisms hold significant importance, leading to specialized production methods. Given the novelty of this subject in Iran, there is limited knowledge or, in some cases, a complete lack of understanding. This paper presents various self-healing concrete mechanisms and the advantages, disadvantages, and application scope of each method.

Keywords: Micro-cracks, self-healing concrete, microcapsules, concrete, cement, self-sensitive.

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References:

[1] M. Amiri, J. M. Sardroud, and A. G. Pahlaviani, “Self-healing Concrete and Environmental Health,” vol. 5, no. 3, pp. 107–112, 2018, doi: 10.15171/ijer.2018.23.
[2] R. O. Gara and R. Mason, “Self-Healing Concrete: The Use of Microencapsulation to Repair Infrastuctural Deterioration Forms of Self-Healing Concrete Future of Microencapsulation.”
[3] S. Guo and S. Chidiac, “Self-Healing Concrete: A Critical Review,” no. Edvardsen 1999, pp. 1–10, 2019.
[4] S. HussainJoo, “Prevention of corrosion in rcc by using bacteria,” no. July 2019, 2020, doi: 10.13140/RG.2.2.34905.13920.
[5] X. W. and Z. H. Wei Wang, Tieyi Zhong, “Research Status of Self-healing Concrete Research Status of Self-healing Concrete,” Conf. Ser. Earth Environ. Sci. 218, 2019, doi: 10.1088/1755-1315/218/1/012037.
[6] S. S. Lucas, C. Moxham, E. Tziviloglou, and H. Jonkers, “ScienceDirect Study of self-healing properties in concrete with bacteria encapsulated in expanded clay,” vol. 30, pp. 93–98, 2018.
[7] S. Z. Xiaopeng Li and and S. Wang, “Status-of-the-Art for Self-healing Concrete Status-of-the-Art for Self-healing Concrete,” J. Phys. Conf. Ser., 2020, doi: 10.1088/1742-6596/1622/1/012011.
[8] L. Souza and A. Al-tabbaa, “Microfluidic fabrication of microcapsules tailored for self-healing in cementitious materials,” Constr. Build. Mater., vol. 184, pp. 713–722, 2018, doi: 10.1016/j.conbuildmat.2018.07.005.
[9] M. W. Lee, “Prospects and Future Directions of Self-Healing Fiber-Reinforced Composite Materials,” pp. 10–15, 2020.
[10] 10 S. K. Das, S. R. David, R. Rajabalaya, and T. Halder, “Microencapsulation techniques and its practices,” no. January, 2011.
[11] Sun, G. and Zhang, Z. 2002. Mechanical Strength of Microcapsules Made of Different Wall Materials. International Journal of Pharmaceutics 242 (1–2): 307–11.
[12] Tan, N. P. B., Keung, L. H., Choi, W. H. Lam, W. C. and Leung, H. N. 2016. Silica-Based Self-Healing Microcapsules for Self-Repair in Concrete. Journal of Applied Polymer Science 133 (12).
[13] 13.Thao, T.D. P. Johnson, T. J. S. Tong, Q. S. and Dai, P. S. 2009. Implementation of Self-Healing in Concrete – Proof of Concept. The IES Journal Part A: Civil & Structural Engineering 2 (2): 116–25.
[14] 14. Van Tittelboom, K. and De Belie, N. 2013. Self-Healing in Cementitious Materials—A Review. Materials 6 (6): 2182–2217.
[15] 15. Ortegarosales, J., & Eltawil, S. (2004). Prestressing concrete using shape memory alloy tendons. Aci Structural Journal, 101(6), 846-851.
[16] 16. Lee, M.W.; An, S.; Lee, C.; Liou, M.; Yarin, A.L.; Yoon, S.S. Self-healing transparent core-shell nanofiber coatings for anti-corrosive protection. J. Mater. Chem. A 2014, 2, 7045–7053. (CrossRef)