Effects of Concrete Composition on Resistance to Microbially Induced Corrosion
Publication: Journal of Environmental Engineering
Volume 143, Issue 6
Abstract
Microbially induced corrosion (MIC) is a process that can take place in concrete sewers, septic tanks, and transfer stations and can result in concrete deterioration. MIC is attributable to the microbial oxidation of hydrogen sulfide () to sulfuric acid () by a biofilm community that is established on a concrete surface. The rate and extent of this process will be influenced by the environment in which it takes place (e.g., temperature, concentration), as well as the composition of the concrete itself. Laboratory experiments were conducted to examine the effect of concrete composition and admixtures on MIC. The experiments were conducted in an isolated chamber where the climate was controlled, including the concentration. Concrete specimens representing 13 mixtures were inoculated with an aqueous suspension containing a mixture of four Acidothiobacillus spp. that have been associated with MIC in sewer systems. Results indicated that calcium aluminate cement (CAC) mortar, blended cement, and incorporation of a silane quaternary amine (SQA) antimicrobial agent can improve resistance to MIC under moderate exposure conditions (i.e., surface ). The rapid deterioration of specimens exposed to more aggressive conditions in the chamber indicated that degradation of concrete under the most severe MIC conditions (i.e., concrete surface ) was not prevented by simply manipulating concrete mixture proportions. A second set of experiments was conducted to quantify the effectiveness of SQA for the inactivation of pure cultures of planktonic bacteria. Results indicated that the antimicrobial agent performed well for the inactivation of pure cultures of Acidothiobacillus spp., except A. thiooxidans, which represent bacteria that are likely to be active under the most severe conditions (i.e., surface ).
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Acknowledgments
This work was supported by Concrete Sealants, Inc. The authors wish to thank Chang Liao and Xuda Lin for their assistance.
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©2017 American Society of Civil Engineers.
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Received: Mar 3, 2016
Accepted: Oct 28, 2016
Published online: Feb 23, 2017
Published in print: Jun 1, 2017
Discussion open until: Jul 23, 2017
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