An Investigation on the Effect of Acidithiobacillus Ferrooxidans Bacteria on Biomachining of Titanium Alloy and Copper
Subject Areas :
Mehrdad
Ghani
1
(Researcher in Biotechnology lab, University of Esfahan, Esfahan, Iran)
Hamid
Soleimanimehr
2
(Department of Mechanical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran)
Elham
Shirani Bidabadi
3
(Department of Biotechnology, University of Isfahan, Esfahan, Iran)
Keywords: medium, Biomachining, Acidithiobacillus Ferrooxidans Bacteria,
Abstract :
Recent advances in technology have increased the necessity of using components with Micro and Nano dimensions. In recent years, the use of bacteria as a renewable tool has hopeful applications in producing different work-pieces. In this study, the effect of Acidithiobacillus Ferrooxidans (A.F) on Vt20 (Titanium alloy) and Cu were investigated. The results illustrated that in the medium of the Aerobic bacteria A.F, the layer of TiO2 on the surface of Vt20 is formed and this oxide layer impedes Vt20 corrosion. Furthermore, it was observed that Cu in a medium of A.F is corroded in the same condition. According to these results, biomachining by A.F is considered as a new approach that is used for Micro-Bio grooving on Cu, but this method has different effects on Vt20. So that due to improving the hardness of Vt20 and high resistance of this alloy against abrasion, this method can be used for coating space traveling equipment, automotive industries and home appliance. On the other hand the effect of pH and temperature on Vt20 were studied and it was observed that the increase in pH and temperature improve the resistance of Vt20 against the surface corrosion.
[1] Jadhav, U. and Hocheng, H. 2014. Use of Aspergillus niger 34770 culture supernatant for tin metal removal. Corrosion science. 82: 248-254.
[2] Xenofontos, E., Feidiou, A., Constantinou, M., Constantinides, G., Vyrides, I. 2015. Copper biomachining mechanisms using the newly isolated Acidithiobacillus Ferrooxidans B1. Corrosion Science. 100: 642-650.
[3] Chang, J., Hocheng, H., Chang, H., Shih, A. 2008. Metal removal rate of Thiobacillus thiooxidans without pre-secreted metabolite. Journal of materials processing technology. 201 (1): 560-564.
[4] Rai-Choudhury, P. 1997. Handbook of microlithography, micromachining and microfabrication: microlithography: Institution of Engineering And Technology.
[5] Roy, S., Ferrara, L. A., Fleischman, A. J., Benzel, E.C. 2001. Micro-electromechanical systems and neurosurgery: a new era in a new millennium. Neurosurgery. 49 (4): 779-798.
[6] Jain, V.K. 2013. Micromanufacturing Processes. New York: Taylor and Francis.
[7] Hocheng, H., Chang, J.H. and Jadhav, U. U. 2012. Micromachining of various metals by using Acidithiobacillus ferrooxidans 13820 culture supernatant experiments. Journal of Cleaner Production. 20 (1): 180-185.
[8] Istiyanto, J., Kim, M. Y. and Ko, T. J. 2011. Profile characteristics of biomachined copper. Microelectronic Engineering. 88 (8): 2614-2617.
[9] Istiyanto, J., Ko, T. J. and Yoon, I. C. 2010. A study on copper micromachining using microorganisms. International Journal of Precision Engineering and Manufacturing. 11 (5): 659-664.
[10] Jadhav, U. U., Hocheng, H. and Weng, W.H. 2013. Innovative use of biologically produced ferric sulfate for machining of copper metal and study of specific metal removal rate and surface roughness during the process. Journal of Materials Processing Technology. 213 (9): 1509-1515.
[11] Eskandarian, M., Karimi, A. and Shabgard, M. 2013. Studies on enzymatic biomachining of copper by glucose oxidase. Journal of the Taiwan Institute of Chemical Engineers. 44 (2): 331-335.
[12] Lorenzetti, M., Dogsa, I., Stosicki, T. A., Kalin, M., Kobe, S. and Novak, S. 2015. The influence of surface modification on bacterial adhesion to titanium-based substrates. ACS applied materials & interfaces. 7 (3): 1644-1651.
[13] Visai, L., De Nardo, L., Punta, C., Melone, L., Cigada, A., Imbriani, M., Arciola, CR. 2011. Titanium oxide antibacterial surfaces in biomedical devices. International Journal of Artificial Organs. 34 (9): 929-946.
[14] Choi, J. Y., Kim, K. H., Choy, K. C., Oh, K.T., Kim, K.N. 2007. Photocatalytic antibacterial effect of TiO2 film formed on Ti and TiAg exposed to Lactobacillus acidophilus. Journal of Biomedical Materials Research Part B: Applied Biomaterials. 80 (2): 353-359.
[15] Johnson, D., Warner, R. and Shih, A. J. 2007. Surface roughness and material removal rate in machining using microorganisms. Journal of Manufacturing Science and Engineering. 129 (1): 223-227.
[16] Istiyanto, J., Saragih, A.-S. and Ko, T. J. 2012. Metal based micro-feature fabrication using biomachining process. Microelectronic Engineering. 98: 561-565.
[17] Kumada, M., Kawakado, T., Kobuchi, S. and Uno, Y. 2001. Investigation of fine biomachining of metals by means of microbially influenced corrosion: differences between steel and copper in metal biomachining using Thiobacillus Ferrooxidans. Corrosion Engineering. 50 (9): 585-596.
[18] Uno, Y., Kaneeda, T. and Yokomizo, S. 1996. Fundamental study on biomachining: machining of metals by Thiobacillus Ferrooxidans. JSME international Journal. Ser. C, Dynamics, control, robotics, design and manufacturing. 39 (4): 837-842.
[19] Zhang, D. and Li, Y. 1998. Possibility of biological micromachining used for metal removal. Science in ChinaSeries C: Life Sciences, 41 (2): 151-156.
[20] Hocheng, H., Chang, J., Hsu, H., Chang, Y.L. and Jadhav, U.U. 2012. Metal removal by Acidithiobacillus ferrooxidans through cells and extra-cellular culture supernatant in biomachining. CIRP Journal of Manufacturing Science and Technology. 5 (2): 137-141.