- citati u SCIndeksu: 0
- citati u CrossRef-u:0
- citati u Google Scholaru:[
 ]
- posete u poslednjih 30 dana:10
- preuzimanja u poslednjih 30 dana:6
|
|
|
2022, vol. 63, br. 3, str. 230-237
|
|
Elektrohemijska istraživanja o korozijskom ponašanju aluminijuma u alkalnoj sredini
Electrochemical studies on the corrosion behaviour of Aluminium in an alkaline medium
aAnna University - University College of Engineering, Visting Faculty, Department of Chemistry, Dindigul, Tamilnadu, India bPSNA College of Engineering and Technology, Department of Chemistry, Dindigul, India cAnna University, Department of Civil, Chennai Tamilnadu, India dRajapalayam Rajus College, Department of Chemistry, Rajapalayam, Tamilnadu, India eSt. Antony's College of Arts and Sciences for Women Thamaraipady, Department of Chemistry, Tamil Nadu, India fSt. Antony's College of Arts and Sciences for Women Thamaraipady, Department of Chemistry, Tamil Nadu, India + Pondicherry Uniersity, Puducherry, India gUniverzitet u Beogradu, Poljoprivredni fakultet, Srbija
e-adresa: senthilsatya1228@gmail.com
Sažetak
Korozija metala aluminijuma na pH 10 je kontrolisana dikarboksilnim kiselinama kao što su oksalna kiselina (OA) i adipinska kiselina (AA). Efikasnost inhibicije (IE) je određena klasičnom metodom gubitka težine. Maksimalna efikasnost inhibicije (IE) koju nude sistem oksalne kiseline (OA) i adipinske kiseline (AA) 250 ppm i Zn2+ 50 ppm iznosi 88% i 96%. Za određivanje vrednosti linearne polarizacione otpornosti (LPR) i struje korozije (Icorr), korišćena je potenciodinamička studija polarizacije.
Abstract
Corrosion of Aluminum metal at pH 10 has been controlled by dicarboxylic acids such as oxalic acid (OA) and adipic acid (AA).The Inhibition efficiency (IE) has been determined by the classical weight loss method. The maximum inhibition efficiency (IE) offered by the oxalic acid (OA) and adipic acid (AA) 250 ppm and Zn2+ 50 ppm system are 88 and 96%. To determine the values of Linear Polarization Resistance (LPR) and corrosion Current (Icorr), potentiodynamic polarization study has been used.
|
|
|
|
Reference
|
|
|
*** (2009) Rising Chinese costs to support Aluminum prices. Bloomberg News, Nov 23
|
|
2   
|
Ashassi-Sorkhabi, H., Ghasemi, Z., Seifzadeh, D. (2005) The inhibition effect of some amino acids towards the corrosion of aluminum in 1M HCl+1M HSO solution. Applied Surface Science, 249(1-4): 408
|
|
|
Aytac, A. (2010) Cu(II), Co(II) and Ni(II) complexes of -Br and -OCH2CH3 substituted Schiff bases as corrosion inhibitors for aluminium in acidic media. Journal of Materials Science, 45(24): 6812-6818
|
|
|
Berthier, P. (2007) Today in science history
|
|
|
Ch, C.M.A., Rajendran, S., Al, H.H., Rathish, R.J., Umasankareswari, T., Jeyasundari, J. (2015) Corrosion Resistance of mild steel in simulated produced water in presence of sodium potassiumtartrate. Int J. Nano Corr. Sci. Engg, 2(1), 42-50
|
|
|
Cochran, J.F., Mapother, D.E. (1958) Superconducting transition in Aluminum. Physical Review, 111(1): 132-142
|
|
|
Deville, Hes-C. (1859) De l'aluminium, ses propriétés, sa fabrication. Paris
|
|
1
|
Epshiba, R., Peter, A., Regis, P., Rajendran, S. (2014) Inhibition of corrosion of carbon steel in a well water by sodium molybdate-zn 2 system. Int.J. Nano. Corr. Sci. Engg., 1(1): 1-11
|
|
|
Gowrani, T., Manjula, P., Baby, N., Manonmani, K.N., Sudha, R., Vennila, T. (2015) Thermodyna mical analysis of MBTA on the corrosion inhibition of brass In 3% NaCl medium. Int.J. Nano. Corr. Sci. Engg., 2(1), 12-21
|
|
|
Hetherington, L.E., Brown, T.J., Benham, A.J., Lusty, P., Idoine, N.E. (2007) Worldmineral production 2001-2005: British geological survey
|
|
|
Johnsirani, V., Rajendran, S., Christy, A., Mary, C., Rathish, R.J., Umasankareswari, T., Jeyasundari, J. (2015) Corrosion inhibition by dyes from plants. Int. J. Nano Corr Sci and Engg, 2(3): 22-28
|
|
3
|
Kavitha, N., Manjula, P. (2014) Corrosion Inhibition of Water Hyacinth Leaves, Zn2+ and TSC on Mild Steel in neutral aqueous medium. Int.J. Nano. Corr. Sci. Engg., 1(1): 31-38
|
|
|
Millberg, L.S. (2007) Aluminum foil: How products are made. Aug 11
|
|
1
|
Nagalakshmi, R., Nagarajan, L., Joseph, R., Rathish, S., Prabha, S., Vijaya, N., Jeyasundari, J., Rajendran, S. (2014) Corrosion Resistance of SS316l in artificial urine in presence of d-glucose. Int. J. Nano Corros. Sci and Engg., 1(1): 39-49
|
|
|
Namita, K., Johar, K., Bhrara, V., Epshiba, R., Singh, G. (2015) Effect of polyethoxyethylene N, N, N' 1, 3 diamino propane on the corrosion of mild steel in acidic solutions. Int. J.Nano Corr. Sci. Engg., 2(1): 12-21
|
|
4
|
Nithya, A., Shanthy, P., Vijaya, N., Rathish, R.J., Prabha, S.S., Joany, R.M., Rajendran, S. (2015) Inhibition of corrosion of Aluminium by an aqueous extract of beetroot (Betanin). Int. J. Nano Corr. Sci. Engg, 2: 1-11
|
|
|
Nithya, D.P., Sathiyabama, J., Rajendran, S., Rathish, P.R.J.S.S. (2015) Influence of citric acid-Zn2+ system on inhibition of corrosion of mild steel in simulated concrete pore solution. Int. J.Nano Corr. Sci. Engg, 2(1): 22-31
|
|
|
Obot, I.B., Obi-Egbedi, N.O. (2008) Fluconazole as an inhibitor for aluminium corrosion in 0.1M HCl. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 330(2-3): 207-212
|
|
1
|
Oguzie, E.E. (2007) Corrosion inhibition of aluminium in acidic and alkaline media by Sansevieria trifasciata extract. Corrosion Science, 49(3): 1527-1539
|
|
1
|
Polmear, I.J. (1995) Light alloys: Metallurgy of the light metals. Arnold
|
|
2
|
Rosliza, R., Wan, N.W.B., Senin, H.B. (2008) The effect of inhibitor on the corrosion of aluminum alloys in acidic solutions. Materials Chemistry and Physics, 107(2-3): 281-288
|
|
1
|
Thangakani, J.A., Rajendran, S., Sathiabama, J., Joany, R.M., Rathish, R.J., Prabha, S.S. (2014) Inhibition of corrosion of carbon steel in aqueous solution containing low chloride ion by Glycine-Zn2+ system. Int. J. Nano. Corr. Sci. Engg, 1: 50-62
|
|
|
Umoren, S.A. (2009) Polymers as corrosion inhibitors for metals in different media. Open Corros. J., 2(1): 175-188
|
|
|
|
|