Bio-Engineered Concrete: A Critical Review on The Next Generation of Durable Concrete

https://doi.org/10.22146/jcef.65317

Md. Fahad Shahriar Zawad(1), Md. Asifur Rahman(2*), Sudipto Nath Priyom(3)

(1) Department of Civil Engineering, Chittagong University of Engineering & Technology (CUET), Chattogram-4349, BANGLADESH
(2) Department of Civil Engineering, Chittagong University of Engineering & Technology (CUET), Chattogram-4349, BANGLADESH
(3) Department of Civil Engineering, Chittagong University of Engineering & Technology (CUET), Chattogram-4349, BANGLADESH
(*) Corresponding Author

Abstract


Concrete is a prerequisite material for infrastructural development, which is required to be sufficiently strong and durable. It consists of fine, coarse, and aggregate particles bonded with a fluid cement that hardens over time. However, micro cracks development in concrete is a significant threat to its durability. To overcome this issue, several treatments and maintenance methods are adopted after construction, to ensure the durability of the structure. These include the use of bio-engineered concrete, which involved the biochemical reaction of non-reacted limestone and a calcium-based nutrient with the help of bacteria. These bio-cultures (bacteria) act as spores, which have the ability to survive up to 200 years, as they are also found to start the mineralization process and the filling of cracks or pores when in contact with moisture. Previous research proved that bio-engineered concrete is a self-healing technology, which developed the mechanical strength properties of the composite materials. The mechanism and healing process of the concrete is also natural and eco-friendly. Therefore, this study aims to critically analyze bio-engineered concrete and its future potentials in the Structural Engineering field, through the use of literature review. The data analysis was conducted in order to provide gradual and informative ideas on the historical background, present situation, and main mechanism process of the materials. According to the literature review, bio-engineered concrete has a promising outcome in the case of strength increment and crack healing. However, the only disadvantage was its less application in the practical fields. The results concluded that bio-engineered concrete is a new method for ensuring sustainable infrastructural development. And also, it indicated that more practical outcome-based analysis with extensive application in various aspects should be conducted, in order to assess the overall durability.


Keywords


Bio-Engineered Concrete; Mineral Precipitation; Bio-Culture; Self-Healing; Mechanical Strength

Full Text:

PDF


References

Abo-El-Enein, S. A., Ali, A. H., Talkhan, F. N., & Abdel-Gawwad, H. A. 2013. Application of microbial biocementation to improve the physico-mechanical properties of cement mortar. HBRC Journal, 9, pp. 36-40.

Achal, V., Mukherjee, A., & Reddy, M.S. 2010. Microbial Concrete: way to enhance the durability of building structures. Journal of Materials in Civil Engineering. Vol. 23, рр. 730–734.

Alazhari, M., Sharma, T., Heath, A., Cooper, R., & Paine, K. 2018. Application of expanded perlite encapsulated bacteria and growth media for self-healing concrete. Construction and Building Materials. Vol. 160, pp.610–619. doi: 10.1016/j.conbuildmat.2017.11.08.

Al-Salloum, Y., Abbas, H., Sheikh, I. Q., Hadi, S., Alsayed, S., & Almusallam, T. 2017. Effect of some biotic factors on microbially-induced calcite precipitation in cement mortar. Saudi Journal of Biological Sciences. Vol. 24 (2), рр. 286–294. doi: 10.1016/j. sjbs.2016.01.016.

Alshalif, A. F., Irwan, J. M., Othman, N., Al-Gheethi, A., & Khalid, F.S. 2019. Improvement of mechanical properties of bio-concrete using Enterococcus faecalis and Bacillus cereus. Environmental Engineering Research. 24, pp. 630–637. doi: 10.4491/eer.2018.306.

Anbu, P., Kang, C, Shin, Y., & So., J. 2016. Formations of Calcium Carbonate Minerals by Bacteria and its Multiple Applications: Review. Springer Plus. 5:250. doi: 10.1186/s40064-016- 1869-2.

Andalib, R., Majid, M. Z. A., Hussin, M. W., Ponraj, M., Keyvanfar, A., Mirza, J., & Lee, H. S. 2016. Optimum concentration of Bacillus megaterium for strengthening structural concrete. Construction and Building Materials. 118, pp. 180–193.

Balam, H. N., Mostofinejad, D., & Eftekhar, M. 2017. Effects of bacterial remediation on compressive strength, water absorption, and chloride permeability of lightweight aggregate concrete. Construction and Building Materials. Vol. 145, рр. 107–116. doi: 10.1016/j. conbuildmat.2017.04.003.

Beltran, M.G. & Jonkers, H. M. 2015. Crack Self-Healing Technology Based on Bacteria. Journal of Ceramic Processing Research, 2015. 16(1), pp. 33-39.

Castro-Alonso, Montañez-Hernandez, Lilia, Muñoz, María, Franco, Mariel, Narayanasamy, R., & Balagurusamy, N. (2019). Microbially Induced Calcium Carbonate Precipitation (MICP) and Its Potential in Bioconcrete: Microbiological and Molecular Concepts. Frontiers in Materials. 6. 126. doi: 10.3389/fmats.2019.00126.

Chen, H., Qian, C., & Huang, H. 2016.Self-healing cementitious materials based on bacteria and nutrients immobilized respectively. Construction and Building Materials, 126, pp. 297–303

De Belie, N. 2016. Application of bacteria in concrete: A critical evaluation of the current status. RILEM Technical Letters, 10, pp. 56-61. doi: 10.21809/rilemtechlett.2016.14.

De Belie, N., & Wang, J. 2015. Bacteria-based repair and self-healing of concrete, Journal of Sustainable Cement-Based Materials, 5 (1-2), pp. 35-36. doi: 10.1080/21650373.2015.1077754.

De Muynck, W., Cox, K., Belie, N. D., & Verstraete, W. 2008. Bacterial carbonate precipitation as an alternative surface treatment for concrete. Construction and Building Materials, 22(5), pp. 875-885.

Dhami, N.K., Reddy, M.S., & Mukherjee, A. 2013. Bacillus megaterium mediated mineralization of calcium carbonate as biogenic surface treatment of green building materials. World Journal of Microbiology and Biotechnology (Formerly MIRCEN Journal of Applied Microbiology and Biotechnology). Vol. 29, рр. 2397–2406. doi: 10.1007/s11274-013-1408-z.

Gandhimathi, A., Suji, D., & Elayarajah, B. 2015. Bacterial concrete: Development of concrete to increase the compressive and split-tensile strength using Bacillus sphaericus. International Journal of Applied Engineering Research. 10, pp. 7125–7132.

Ghosh, P., Mandal, S., Chattopadhyay, B. D., & Pal, S. 2005. Use of microorganism to improve the strength of cement mortar. Cement and Concrete Research, 35(10), pp. 1980–1983. doi:10.1016/j.cemconres.2005.03.005.

Hassan, M., Milla, J., Rupnow, T., & Soysal, A. 2019. Self-Healing concrete using encapsulated bacterial spores in a simulated hot subtropical climate. Report of Tran-SET Project No. 18CLSU02

Islam, S. M., Sinha, T., & Uddin, M. K2019. An experimental investigation on improvement of concrete strength using bacterial approach. In: 4th International Conference on Advances in Civil Engineering 2018, CUET. pp. 683-688.

Jagadeesha, K.B.G., Prabhakara, & Pushpa, H.. 2013. Effect of bacterial calcite precipitation on compressive strength of mortar cubes. International Journal of Engineering and Advanced Technology. 2. pp. 486-491.

Jagannathan, P., Narayanan, K. S. S., Arunachalam, K. D., & Annamalai, S. K. 2018. Studies on the mechanical properties of bacterial concrete with two bacterial species. Materials Today: Proceedings. 5. pp. 8875-8879. doi: 10.1016/j.matpr.2017.12.320.

Jonkers, H. 2011. Bacteria-based self-healing concrete. Heron. 56.

Jonkers, H. M., & Schlangen, E. 2007. Self-healing of cracked concrete: A bacterial approach. In: Proceedings of the 6th International Conference on Fracture Mechanics of Concrete and Concrete Structures, 3, pp.1821-1826.

Jonkers, H. M., Thijssen, A., Muyzer, G., Copuroglu, O., & Schlangen, E. 2010. Application of bacteria as selfhealing agent for the development of sustainable concrete. Ecological engineering, 36(2), pp. 230-235.

Joshi, S., Goyal, S., Mukherjee, A., & Reddy, M. S. 2017. Microbial Healing of Cracks in Concrete: A Review. Journal of Industrial Microbiology and Biotechnology, 44, pp. 1511-1525.

Khaliq, W., & Ehsan, M. B. 2016.Crack healing in concrete using various bio influenced self-healing techniques. Construction and Building Materials, 102, pp. 349–357. doi: 10.1016/j.conbuildmat.2015.11.006

Le Métayer-Levrel, G., Castanier, S., Orial, G., Loubière, J.-F., & Perthuisot, J.-P. 1999. Applications of bacterial carbonatogenesis to the protection and regeneration of limestones in buildings and historic patrimony. Sedimentary Geology. Vol. 26, pp. 25–34.

Ling, H., & Qian, C. 2017. Effects of self-healing cracks in bacterial concrete on the transmission of chloride during electromigration. Construction and Building Materials. 144, pp. 406–411. doi: 10.1016/j.conbuildmat.2017.02.160.

Mors, R., & Jonkers, H. M. 2019. Bacteria-Based Self-Healing Concrete: Evaluation of Full Scale Demonstrator Projects. RILEM Tech Lett 2019, 4, 138-144.

Mullem, T., Gruyaert, E., Caspeele, R., & De Belie, N. 2020. First Large Scale Application with Self-Healing Concrete in Belgium: Analysis of the Laboratory Control Tests. Materials. 13. 10.3390/ma13040997.

Nguyen, T.H., Ghorbel, E., Fares, H., & Cousture, A. 2019. Bacterial self-healing of concrete and durability assessment. Cement and Concrete Composites. 104. pp. 103340. doi: 10.1016/j.cemconcomp.2019.103340.

Nosouhian, F., Mostofinejad, D., & Hasheminejad, H. 2015. Concrete durability improvement in a sulfate environment using bacteria. Journal of Materials in Civil Engineering, 28. doi: 10.1061/ (ASCE)MT.1943-5533.0001337.

Nugroho, A., Satyarno, I., & Subyakto, S. 2015. Bacteria as Self-Healing Agent in Mortar Cracks. Journal of Engineering and Technological Sciences. 47. pp. 279-295.

Oriola, F., Sani, J.E., & Adah, A.M. 2018. Evaluation of the effect of Bacillus Pumilus precipitate on the strength and durability of concrete. Civil and Environmental Research. Vol. 10, pp. 1–10.

Paine, K., Alazhari, M., Sharma, T., Cooper, R., & Heath, A. 2016. Design and performance of bacteria-based self-healing concrete. In: M R Jones, M D Newlands, J E Halliday, L J Csetenyi, L Zheng, M. J. McCarthy, & T D Dyer (Eds.), The 9th International Concrete Conference 2016: Environment, Efficiency and Economic Challenges for Concrete. pp. 545-554.

Priyom, S. N., Islam, M., & Islam, S. 2018. An experimental investigation on the performance of bacterial concrete. In: 4th International Conference on Advances in Civil Engineering, CUET, pp. 392-397.

Priyom, S. N., Islam, M. M., & Shumi, W. 2021. The Utilization of Bacillus Subtilis Bacteria for Improving Mechanical Properties of Concrete. Journal of the Civil Engineering Forum. 7(1). pp. 97-doi: 108. 10.22146/jcef.60216.

Priyom, S. N., Zawad, M. F. S., Rahman, M. A., & Islam, M. M. 2020. Microstructure Analysis of Microbial Concrete: A Comparative Study. DUET Journal, 6. pp. 9-16.

Reinhardt, H. W., & Jooss, M. 2003. Permeability and self-healing of cracked concrete as a function of temperature and crack width. Cem. Concr. Res., 33, pp.981–985.

Raina, S. S., Singla, Er. S., & Batra, Dr. V. 2018.Comparative analysis of compressive strength and water absorption in bacterial concrete. International Journal of Engineering Development and Research , 6(3), pp. 281-286.

Selvan, V. A. T., & Dharani, D. 2016. An experimental investigation of bacterial concrete incorporated with bacillus cereus. IJDR 6(11):10042-10045.

Silva, F. 2015. Up-Scaling the Production of Bacteria for Self-Healing Concrete Application. PhD Thesis, Ghent University.

Soleimani, S., Ormeci, B., & Isgor, O.B. 2013. Growth and characterization of Escherichia coli DH5α biofilm on concrete surfaces as a protective layer against microbiologically influenced concrete deterioration (MICD). Appl Microbiol Biotechnol, 97(3), pp. 1093-102. doi: 10.1007/s00253-012-4379-3.

Sreenivasulu, B., Lingamgunta, L.K., Kannali, J., Gajula, S.K., Bandikari, R., Dasari, S., Dalavai, V., Chinthala, P., Gundala, P.B., Kutagolla, P., & Balaji, V.K. 2018. Subsurface endospore-forming bacteria possess biosealant properties. Scientific Reports. 8. doi: 10.1038/s41598-018-24730-3.

Stooks-Fischer, S., Galinat, J. K., & Bang, S. S. 1999. Microbiological precipitation of CaCO3, Soil Biology Biochemistry. 31 (11), pp. 1563-1571.

Thakur, A., & Singh, K. 2017. Bacterial concrete and effect of different bacteria on the strength and water absorption characteristics of concrete: A review. 10.13140/RG.2.2.15736.75525.

Tittelboom, K. V., Belie, N. D., Muynck, W. D., & Verstraete, W. 2010. Use of bacteria to repair cracks in concrete. Cement and Concrete Research 40(1). pp. 157–166. doi: 10.1016/j.cemconres.2009.08.025.

Tziviloglou, E., Wiktor, V., Jonkers, H. M., & Schlangen, E. 2016.Bacteria-based self-healing concrete to increase liquid tightness of cracks. Construction and Building Materials, 122, pp. 118–125.

Vijay, K., Murmu, M., & Deo, S. 2017. Bacteria based self-healing concrete – A review. Construction and Building Materials, 152. pp. 1008-1014. 10.1016/j.conbuildmat.2017.07.040.

Wang, J., Jonkers, H. M., Boon, N., & De Belie, N. 2017. Bacillus sphaericus LMG 22257 is physiologically suitable for self-healing concrete. Applied Microbiology and Biotechnology, 101(12), pp. 5101–5114. doi:10.1007/s00253-017-8260-2.

Wang, J., Mignon, A., Snoeck, D., Wiktor, V., Boon, N. & De Belie., N. 2015. Application of Modified-Alginate Encapsulated Carbonate Producing Bacteria in Concrete: A Promising Strategy for Crack Self-Healing. Frontiers in Microbiology. 6. pp. 1-14.

Wang, J. Y., Snoeck, D., Van Vlierberghe, S., Verstraete, W., & De Belie, N. 2014. Application of hydrogel encapsulated carbonate precipitating bacteria for approaching a realistic self-healing in concrete. Construction and Building Materials, 68, pp. 110–119. doi: 10.1016/j.conbuildmat.2014.06.018.

Wang, J.Y., Soens, H., Verstraete, W., & De Belie, N. 2014. Selfhealing concrete by use of microencapsulated bacterial spores. Cement and Concrete Research. Vol. 56, pp. 139–152.

Wiktor, V. & Jonkers, H. M. 2015. Field performance of bacteria-based repair system: Pilot study in a parking garage. Case Stud. Constr. Mater., 2, pp. 11-17.

Xu, J., & Wang, X. 2018. Self-healing of concrete cracks by use of bacteria-containing low alkali cementitious material. Construction and Building Materials. 167. pp. 1-14.

Xu, J., Wang, X., Zuo, J., & Liu, X. 2018. Self-Healing of concrete cracks by ceramsite-loaded microorganisms. Advance in Materials Science and Engineering. doi: 10.1155/2018/5153041.

Yoon, H.-S., Yang, K.-H., & Lee, S.-S. 2019. Evaluation of sulfuric acid resistance of biomimetic coating mortars for concrete surface protection. Journal of the Korea Concrete Institute. 31, pp. 61–68. doi: 10.4334/JKCI.2019.31.1.061.

Zhang, Y., Guo, H. X., & Cheng, X. H. 2015. Role of calcium sources in the strength and microstructure of microbial mortar. Construction and Building Materials, 77, pp.160–167.

Zhang, X., & Qian, C. 2020. Engineering application of microbial self-healing concrete in lock channel wall. Case Studies in Construction Materials. doi: 10.1016/j.cscm.2020.e00398.

Zulfikar, R., Putra, H., Yasuhara, H. 2021. The Utilization of Soybean as a Catalyst Material in Enzyme-Mediated Calcite Precipitation (EMCP) for Crack Healing Concrete. Journal of the Civil Engineering Forum. 7 (1). pp. 59-70



DOI: https://doi.org/10.22146/jcef.65317

Article Metrics

Abstract views : 5132 | views : 2908

Refbacks

  • There are currently no refbacks.




Copyright (c) 2022 The Author(s)


The content of this website is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
ISSN 5249-5925 (online) | ISSN 2581-1037 (print)
Jl. Grafika No.2 Kampus UGM, Yogyakarta 55281
Email : jcef.ft@ugm.ac.id
Web Analytics JCEF Stats