Mobile QR Code QR CODE
Export citation EndNote

References

1 
Anthierens, T., Ragaert, P., Verbrugghe, S., Ouchchen, A., De Geest, B. G., Noseda, B., Mertens, J., Beladijal, L., Cuyper, D. D., Diericks, W., Prez, F. D., and Devlieghere, F. (2011) Use of Endospore-forming Bacteria as an Active Oxygen Scavenger in Plastic Packaging Materials. Innovative Food Science and Emerging Technologies 12(4), 594-599.DOI
2 
Bots, P., Benning, L. G., Rodriguez-Blanco, J. D., Roncal-Herrero, T., and Shaw, S. (2012) Mechanistic Insights into the Crystallization of Amorphous Calcium Carbonate (ACC). Crystal Growth and Design 12(7), 3806-3814.DOI
3 
Castro-Alonso, M. J., Montañez-Hernandez, L. E., Sanchez- Muñoz, M. A., Macias Franco, M. R., Narayanasamy, R., and Balagurusamy, N. (2019) Microbially Induced Calcium Carbonate Precipitation (MICP) and Its Potential in Bioconcrete: Microbiological and Molecular Concepts. Frontiers in Materials 6, 126.DOI
4 
Cheung, J., Jeknavorian, A., Roberts, L., and Silva, D. (2011). Impact of Admixtures on the Hydration Kinetics of Portland Cement. Cement And Concrete Research 41(12), 1289-1309.DOI
5 
Christy, A. G. (2017) A Review of the Structures of Vaterite: the Impossible, the Possible, and the Likely. Crystal Growth and Design 17(6), 3567-3578.DOI
6 
Chung, S. Y., Lehmann, C., Abd Elrahman, M., and Stephan, D. (2017) Pore Characteristics and Their Effects on the Material Properties of Foamed Concrete Evaluated Using Micro-CT Images and Numerical Approaches. Applied Sciences 7(6), 550.DOI
7 
De Belie, N., Gruyaert, E., Al-Tabbaa, A., Antonaci, P., Baera, C., Bajare, D., Darquennes, A., Davies, R., Ferrara, L., Jefferson, T., Litina, C., Milijecic, B., Otlewska, A., Ranogajec, J., Roig-Flores, M., Paine, K., Lukowski, P., Serna, P., Tuliani, J. M., Vucetic, S., Wang, J., and Jonkers, H. M. (2018) A Review of Self-healing Concrete for Damage Management of Structures. Advanced Materials Interfaces 5(17), 180007.DOI
8 
Dembovska, L., Bajare, D., Korjakins, A., Toma, D., and Jakubovica, E. (2019) Preliminary Research for Long Lasting Self-healing Effect of Bacteria-based Concrete with Lightweight Aggregates. In IOP Conference Series: Materials Science and Engineering 660(1), IOP Publishing. 012034.DOI
9 
Hossain, M. R., Sultana, R., Patwary, M. M., Khunga, N., Sharma, P., and Shaker, S. J. (2022) Self-healing Concrete for Sustainable Buildings. A Review. Environmental Chemistry Letters. 1-9.DOI
10 
Hwang, J. W., Yang, K. H., Yoon, H. S., and Lee, S. S. (2022) Feasibility Tests of Bacteria-Based Self-Healing Pellets to Repair Mortar Cracks. Journal of the Korea Concrete Institute 34(5), 487-496. (In Korean)DOI
11 
KATS (2022) Testing Method for Compressive Strength of Hydraulic Cement Mortars (KS L 5105). Seoul, Korea: Korea Agency for Technology and Standards (KATS), Korea Standard Association (KSA). 1-6. (In Korean)URL
12 
Kim, W. J., Kim, S. T., Park, S. J., Ghim, S. Y., and Chun, W. Y. (2009) A Study on the Development of Self-healing Smart Concrete Using Microbial Biomineralization. Journal of the Korea Concrete Institute 21(4), 501-511. (In Korean)DOI
13 
Lee, Y. S., and Park, W. (2018) Current Challenges and Future Directions for Bacterial Self-healing Concrete. Applied Microbiology and Biotechnology 102, 3059-3070.DOI
14 
Li, V. C., and Yang, E. H. (2007) Self Healing in Concrete Materials. In Self Healing Materials: an Alternative Approach to 20 Centuries of Materials Science. Dordrecht: Springer Netherlands. 161-193.DOI
15 
Wang, H. L., Dai, J. G., Sun, X. Y., and Zhang, X. L. (2016) Characteristics of Concrete Cracks and Their Influence on Chloride Penetration. Construction and Building Materials 107, 216-225.DOI
16 
Zhou, G. T., Yao, Q. Z., Fu, S. Q., and Guan, Y. B. (2010) Controlled Crystallization of Unstable Vaterite with Distinct Morphologies and Their Polymorphic Transition to Stable Calcite. European Journal of Mineralogy 22(2), 259-269.DOI
17 
Zingg, T. (1935) Beitrag zur Schotteranalyse. Doctoral Thesis, ETH Zurich.URL