The Influence of Micro Algae on Corrosion of Steel in Fly Ash Geopolymer Concrete: A Preliminary Study

Monita Olivia; Navid Moheimani; Reza Javaherdashti; Hamid R. Nikraz; Michael A. Borowitzka

doi:10.4028/www.scientific.net/AMR.626.861

Paper Titles

Effect of Curing Regime on Compressive Strength of Concrete Containing Malaysian Laterite Aggregate
p.839

Post-Growth Annealing Effects on the Photoluminescence of ZnO Nanoparticle-Based Discs
p.844

Microstructures Study on Cuprous Oxide Thin Films Deposited on Different Substrates by Using Sol-Gel Technique
p.849

Ultra Compact 1×11 Power Splitter Using Polydiacetylene Multimode Interference Coupler
p.853

The Influence of Micro Algae on Corrosion of Steel in Fly Ash Geopolymer Concrete: A Preliminary Study
p.861

A Brief Review of the Current Technologies Used for the Fabrication of Metal-Molecule-Metal Junction Electrodes
p.867

Application of Clay - Based Geopolymer in Brick Production: A Review
p.878

Effect of Cobalt Stearate on Outdoor Exposure of LLDPE/Soy Spent Powder Blends
p.883

Preparation of Activated Carbon from Durian Shell and Seed
p.887

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 626The Influence of Micro Algae on Corrosion of Steel...

The Influence of Micro Algae on Corrosion of Steel in Fly Ash Geopolymer Concrete: A Preliminary Study

Abstract:

Chloride is not the only main cause of corrosion of reinforced concrete structures in seawater environment. Microorganisms, such as bacteria and microalgae, in the seawater can induce microbiologically influenced corrosion (MIC) that leads to degradation of the concrete structures by formation of biofilm on the metallic surface. In this preliminary study, the impact of microalgae on the corrosion of steel reinforced bars in fly ash geopolymer concrete was studied. Corrosion potential, algae cells number, and pH measurement were carried out for fly ash geopolymer concrete and a control mix (Ordinary Portland Cement) samples. The results indicate that the corrosion potential of fly ash geopolymer concrete was influenced by the cathodic reaction during photosynthesis activities. The geopolymer concrete in algae-inoculated medium was found to be more tolerant to algal growth than the control mix (OPC concrete). There was a positive correlation between algae cell densities and the potential reading of the geopolymer.

You might also be interested in these eBooks

Advanced Materials Engineering and Technology

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 626)

Pages:

861-866

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.626.861

Citation:

Cite this paper

Online since:

December 2012

Authors:

Monita Olivia, Navid Moheimani, Reza Javaherdashti, Hamid R. Nikraz, Michael A. Borowitzka

Keywords:

Algae, Biofilm, Corrosion, Geopolymer, pH

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] N. De Belie, J. Monteny, A. Beeldens, E. Vincke, D. Van Gemert, and W. Verstraete: Cement and Concrete Research Vol 34 (2004) p.2223.

DOI: 10.1016/j.cemconres.2004.02.015

Google Scholar

[2] R. Javaherdashti: Microbiologically Influenced Corrosion- An Engineering Insight. (Springer-Verlag, London 2008).

Google Scholar

[3] R.G. Edyvean, and L.A. Terry, in: The influence of micro-algae on corrosion of structural steels used in the North Sea, edited by T.A. Oxley, and S. Barry, volume 5 Biodeterioration, John Wiley and Sons (1983).

Google Scholar

[4] L.A. Terry, and R.G.J. Edyvean, in: Algal Biofouling, edited by L.V. Evans, and K.D. Hoagland, Elsevier (1986).

Google Scholar

[5] R. Javaherdashti, H. Nikraz, M. Borowitzka, N. Mohaemani, and M. Olivia: European Journal of Scientific Research Vol 36 (2009) p.394.

Google Scholar

[6] T. Bakharev: Cement and Concrete Research Vol 35 (2005) p.1233.

Google Scholar

[7] X. Song: Development and Performance of Class F Fly Ash Based Geopolymer Concretes against Sulphuric Acid Attack (School of Civil and Environmental Engineering, The University of New South Wales, Australia 2007).

Google Scholar

[8] J.M. Miranda, A. Fernandez-Jimenez, J.A. Gonzalez, and A. Palomo: Cement and Concrete Research Vol 35 (2005) p.1210.

Google Scholar

[9] D.M. Bastidas, A. Fernandez-Jimenez, A. Palomo, and J.A. Gonzalez: Corrosion Science Vol 50 (2008) p.1058.

Google Scholar

[10] Shindunata, J.S.J. van Deventer, G.C. Lukey, and H. Xu: Industrial & Engineering Chemistry Research Vol 45 (2006) p.3559.

Google Scholar

[11] M. Olivia, and H. Nikraz: Materials and Design Vol 36 (2012) p.191.

Google Scholar

[12] N. R. Moheimani: The Culture of Coccolithophorid Algae for Carbondioxide Bioremediation, (School of Biological Sciences and Biotechnology, Murdoch University, Australia 2005).

Google Scholar

[13] O. Aviam, G. Bar-Nes, Y. Zeiri, A. Sivan: Applied and Environmental Microbiology Vol 70 (2004) p.6031.

Google Scholar

[14] B.P. Guilbeau, F.P. Harry, R.P. Gambrell, F.C. Knopf, and K.M. Dooley: Ecological Engineering Vol 20 (2003) p.309.

Google Scholar

[15] B. Little, R. Day, P. Wagner, Z. Lewandowski, W.L. Lee, W.G. Charcklis, and F. Mansfeld: Biofouling Vol 3 (1991) p.45.

Google Scholar

[16] N.J.E. Dowling, J. Guezennec, J. Bullen, B. Little, and D.C. White: Biofouling Vol 5 (1992) pp.315-322.

Google Scholar