The inhibition of Carica papaya leaves extract on the corrosion of cold worked and annealed mild steel in HCl and NaOH solutions using a weight loss technique
Article Sidebar
Main Article Content
Abstract
The current work investigates the corrosion inhibition of cold worked and annealed mild steel in 0.5 M HCl and 0.5 M NaOH solutions with Carica papaya leaf extract as an inhibitor. The as-received diameter of the mild steel rods was 4.42 mm before some of them were cold drawn to 3.35 mm wire bars. Rods that were 30 mm in length were cut from the as-received, cold worked and annealed samples. The cut samples were thoroughly pickled, dried and weighed before they were suspended in an aggressive media that contained the inhibitor as well as in the media without inhibitor. The samples were examined on the 3rd, 5th, 7th, 10th, 12th, 14th and 17th days, and then, pickled, dried and reweighed. In the 0.5 M HCl solution without inhibitor, maximum corrosion rates of the as-received and cold worked samples were reported on the 5th day, and their values were 1.0x10-4 and 1.3x10-4 g/cm2h, respectively. The maximum corrosion rate of the annealed sample was reported on the 12th day and its value was 5.9x10-5 g/cm2h. The extract was able to reduce the maximum corrosion rates of the as-received, cold worked and annealed samples in 0.5 M HCl solution by 54.1 %, 42 %, and 23.1 %, respectively. Similarly, in a 0.5 M NaOH solution without inhibitor, maximum corrosion rates of the as-received and cold worked samples were reported on the 5th day. Their values were 7.0x10-5 and 8.8x10-5 g/cm2h, respectively. The maximum corrosion rate of the annealed sample was reported on the 12th day and its value was 4.1x10-5 g/cm2h. The inhibitor reduced the maximum corrosion rates in a 0.5 M NaOH solution by 53.8 %, 51.4 % and 33.3 % for the as-received, cold worked and annealed samples respectively. The corrosion rates of all the samples were reduced in the media that contained the inhibitor.
Article Details
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
References
Umunakwe R, Okoye OC, Madueke CI, Komolafe DO. Effects of carburization with palm kernel shell/coconut shell mixture on the tensile properties and case hardness of low carbon steel. FUOYE Journal of Engineering and Technology. 2017;2(1):101-5.
da Rocha JC, Gomes JA, D’Elia E. Aqueous extracts of mango and orange peel as green inhibitors for carbon steel in hydrochloric acid solution. Mater Res. 2014;17(6):1581-7.
Bhat IJ, Alva VD. Inhibition effects of miconazole nitrate on the corrosion of mild steel in hydrochloric acid medium. Int J Electrochem. 2011;2011:1-8.
Ashassi-Sorkhabi H, Shaabani B, Seifzadeh, D. Corrosion inhibition of mild steel by some Schiff base compounds in hydrochloric acid. Appl Surf Sci. 2005;239:154-64.
Omotoyinbo JA, Oloruntoba DT, Olusegun SJ. Corrosion inhibition of pulverized Jatropha curcas leaves on medium carbon steel in 0.5 M H2SO4 and NaCl environments. Int J Sci Tech. 2013;2(7);510-4.
Singh A, Kumar A, Pramanik T. A theoretical approach to the study of some plant extracts as a green corrosion inhibitor for mild steel in HCl solution. Orient J Chem. 2013;2(1):277-83.
Ikeda AI, Ita BI, Etiuma RA, Bassey VM, Ugi BU, Kporokpo EB. Green corrosion inhibitors for mild steel in H2SO4 solution: flavonoids of Gongronema latifolium. Chem Process Eng Res. 2015;34:1-9.
Al-Turkustani AM, Arab ST, Al-Reheli AA. Corrosion and corrosion inhibition of mild steel in H2SO4 solution by zizyphus Spina-Christi as a green inhibitor. Int J Chem. 2010;2(2):54-76.
Uwah IE, Ikeuba AI, Ugi BU, Udowo VM. Comparative study of the inhibition effects of alkaloid and non alkaloid fractions of the ethanolic extracts of Costus after stem on the corrosion of mild steel in 5 M HCl solution. Global J Pure Appl Sci. 2013;19(1):23-31.
Sharma SK, Mudhoo A, Jain G, Sharma J. Corrosion inhibition and adsorption properties of Azadirachta indica mature leaves extract as a green inhibitor for mild steel in HNO3. Green Chem Lett Rev. 2010;3(1):7-15.
Kolo AM, Idris S, Bamishaiye OM. Corrosion inhibition potential of ethanol extract of Bryophyllum pinnatum leaves for zinc in acidic medium. Edelweiss Applied Science and Technology. 2018;2:18-25.
Ugi BU, Ekerete J, Ikeuba IA, Uwah IE. Mangifera indica leaves extracts as organic inhibitors on the corrosion of zinc sheet in 5 M H2SO4 solution. J Appl Sci Environ Manag. 2015;1(1):145-52.
Challouf H, Souissi MN, Ben M, Abidi R, Madani A. Origanum majorana extracts as mild steel corrosion green inhibitors in aqueous chloride medium. J Environ Protect. 2016;7:532-44.
Ogwo KD, Osuwa JC, Udoinyang IE, Nnanna LA. Corrosion inhibition of mild steel and aluminum in 1 M hydrochloric acid by leaves extracts of Ficus sycomorus. Phys Sci Int J. 2017;14(3):1-10.
Okafor PC, Ebenso EE. Inhibitive action of Carica papaya extracts on the corrosion of mild steel in acidic media and their adsorption characteristics. Pigm Resin Technol. 2007;36(3):134-40.
Ajanaku KO, Aladesuyi O, Anake WU, Edobor-Osoh A, Ajanaku CO, Siyanbola TO, et al. Inhibitive properties of Carica papaya leaf extract on aluminum in 1.85M HCl. J Adv Chem. 2014;8(20):1651-9.
Omotioma M, Onukwuli OD. Evaluation of pawpaw leaves extracts as an anti-corrosion agent for aluminum in hydrochloric acid medium. Niger J Technol. 2017;36(2):496-504.
Loto CA, Loto RT, Popoola AP. Inhibition effect of extracts of Carica papaya and Camellia sinensis leaves on the corrosion of duplex (α β) brass in 1M nitric acid. Int J Electrochem Sci. 2011;6:4900-14.
Kasuga B, Park E, Machunda RL. Inhibition of aluminum corrosion using Carica papaya leaves extract in sulphuric acid. J Miner Mater Char Eng. 2018;6:1-14.
Al-zubidy EA, Hummza RA. Corrosion behavior of copper and carbon steel in acidic media. Baghdad Sci J. 2014;11(4):1577-82.
Raji NA, Oluwole OO. The effects of full annealing on the microstructure and mechanical properties of cold drawn low carbon steel. NSE Technical Transactions. 2013;7(2):1-10.
Yaylacı Ç, Uzun G, Ural G. Cold working and hot working and annealing [Internet]. Turkey: Department of Chemical Engineering, Hacettepe University: [updated 2010 Dec 29; cited 2018 Oct] Available from https://www.academia.edu/38921625/ Cold_Hot_Working_Annealing
Bossom F, Driver JH. Deformation banding mechanisms during plain strain compression of cube oriented F.C.C. crystals. Acta Mater. 2000;48:2101-15.
Dahiwade PA, Shrivastava S, Sagar NK. Study on the effect of hardness of steel by annealing and normalizing during hot rolling processes. Int J Innovat Res Tech. 2014;1(2):12-7.
Fadare DA, Fadara TG, Akanbi OY. Effect of heat treatment on mechanical properties and microstructure of NST 37-2 steel. J Miner Mater Char Eng. 2011;10(3):299-308.
Foroulis ZA. Effect of cold work and heat treatment on corrosion of iron-carbon-silicon alloys in hydrochloric acid. Corrosion Sci. 1965;5:39-46.
Uzorh AC. Corrosion properties of plain carbon steels. Int J Eng Sci. 2013;2(11):18-24.
Adnan MA, Kee KE, Raja PB, Ismail MC, Kakooei S. Influence of heat treatment on the corrosion of carbon steel in an environment containing carbon dioxide and acetic acid. IOP Conf Ser: Mater Sci Eng. 2018;370:1-7.
Seidu SO, Kutelu BJ. Effect of heat treatments on corrosion of welded low-carbon steel in acid and salt environments. J Miner Mater Char Eng. 2013;1(3):95-100.
Dar AB. A review: plant extracts and oils as corrosion inhibitors in aggressive media. Ind Lubr and Tribol. 2011;63(4):227-33.