Application of Carbon Dots as Corrosion Inhibitor: A Systematic Literature Review
Muhamad Jalil Baari(1*), Ravensky Yurianty Pratiwi(2)
(1) Department of Chemistry, Faculty of Science and Technology, Universitas Sembilanbelas November Kolaka, Jl. Pemuda, Kolaka 93517, Indonesia
(2) Department of Chemistry Education, Universitas Islam Negeri Raden Fatah Palembang, Jl. Prof. KH Zainal Abidin Fikri Km 3.5, Palembang 30126, South Sumatera, Indonesia
(*) Corresponding Author
Abstract
Corrosion is spontaneity and unavoidable reactions which cause degradation in the quality of the materials. Most industries have been harmed by the corrosion of manufacturing equipment. Several methods can be applied to control this problem. The use of corrosion inhibitors is an effective and practical way to decrease metal deterioration significantly. Many commercial inorganic and organic compounds are effective inhibitors, but most of them are not completely safe and relatively expensive. Carbon dots and their derivatives are potential compounds for resolving corrosion reactions on metal surfaces. Carbon dots can be synthesized from various natural sources to be more environmentally friendly. This systematic review aims to summarize the concept of corrosion, types of carbon dots-based corrosion inhibitor and their effectiveness on various metals, inhibition mechanism, surface analysis of the protected metals, kinetics, thermodynamics, and quantum computational chemistry studies. This review also presents the significance and the prospects of carbon dots-based corrosion inhibitors.
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[1] Stalheim, D., 2011, Metallurgical optimization of microalloyed steels for oil and gas transmission pipelines, Proceedings of 6th International Conference on High Strength Low Alloy Steels (HSLA Steels 2011), Chinese Society for Metals, Beijing, China, May 31 – June 2, 2011.
[2] Adewuyi, A., Göpfert, A., and Wolff, T., 2014, Succinyl amide gemini surfactant from Adenopus breviflorus seed oil: A potential corrosion inhibitor of mild steel in acidic medium, Ind. Crops Prod., 52, 439–449.
[3] Yilmaz, N., Fitoz, A., Ergun, Ü., and Emregül, K.C., 2016, A combined electrochemical and theoretical study into the effect of 2-((thiazole-2-ylimino)methyl)phenol as a corrosion inhibitor for mild steel in a highly acidic environment, Corros. Sci., 111, 110–120.
[4] Cen, H., Chen, Z., and Guo, X., 2019, N,S-co-doped carbon dots as effective corrosion inhibitor for carbon steel in CO2-saturated 3.5% NaCl solution, J. Taiwan Inst. Chem. Eng., 99, 224–238.
[5] Kadry, S., 2008, Corrosion analysis of stainless steel, Eur. J. Sci. Res., 22 (4), 508–516.
[6] Patel, A.S., Panchal, V.A., Mudaliar, G.V., and Shah, N.K., 2013, Impedance spectroscopic study of corrosion inhibition of Al-Pure by organic Schiff base in hydrochloric acid, J. Saudi Chem. Soc., 17 (1), 53–59.
[7] Anbarasi, C.M., and Divya, G., 2017, A Green approach to corrosion inhibition of aluminium in acid medium using Azwain seed extract, Mater. Today: Proc., 4 (4), 5190–5200.
[8] Lopez-Garrity, O., and Frankel, G.S., 2014, Corrosion inhibition of aluminum alloy 2024-T3 by sodium molybdate, J. Electrochem. Soc., 161 (3), C95–C106.
[9] Ambat, R., and Dwarakadasa, E.S., 1994, Studies on the influence of chloride ion and pH on the electrochemical behaviour of aluminium alloys 8090 and 2014, J. Appl. Electrochem., 24 (9), 911–916.
[10] Sequeira, C.A.C., 2011, “Copper and Copper Alloys” in Uhlig’s Corrosion Handbook, 3rd Ed., Eds. Revie, R.W., John Wiley & Sons, Inc. USA, 757–785.
[11] Huang, H., Wang, Z., Gong, Y., Gao, F., Luo, Z., Zhang, S., and Li, H., 2017, Water soluble corrosion inhibitors for copper in 3.5 wt% sodium chloride solution, Corros. Sci., 123, 339–350.
[12] Antonijević, M.M., Milić, S.M., and Petrović, M.B., 2009, Films formed on copper surface in chloride media in the presence of azoles, Corros. Sci., 51 (6), 1228–1237.
[13] Pahuja, P., Dahiya, S., and Lata, S., 2018, A review on herbal drugs as corrosion inhibitor for low alloy steel, BMIET J. Sci. Technol. Manage., 2 (1), 7–19.
[14] Lv, J., Fu, L., Zeng, B., Tang, M., and Li, J., 2019, Synthesis and Acidizing corrosion inhibition performance of N-doped carbon quantum dots, Russ. J. Appl. Chem., 92 (6), 848–856.
[15] Usman, B.J., and Ali, S.A., 2018, Carbon dioxide corrosion inhibitors: A review, Arabian J. Sci. Eng., 43 (1), 1–22.
[16] Umoren, S.A., AlAhmary, A.A., Gasem, Z.M., and Solomon, M.M., 2018, Evaluation of chitosan and carboxymethyl cellulose as ecofriendly corrosion inhibitors for steel, Int. J. Biol. Macromol., 117, 1017–1028.
[17] Qiang, A.Y., Zhang, S., Yan, S., Zou, X., and Chen, S., 2017, Three indazole derivatives as corrosion inhibitors of copper in a neutral chloride solution, Corros. Sci., 126, 295–304.
[18] Baari, M.J., Bundjali, B., and Wahyuningrum, D., 2020, Synthesis of oligosuccinimide and evaluation of its corrosion inhibition performance on carbon steel in CO2-saturated 1% NaCl solution, J. Math. Fundam. Sci., 52 (2), 202–221.
[19] Baari, M.J., Bundjali, B., and Wahyuningrum, D., 2021, Performance of N,O-carboxymethyl chitosan as corrosion and scale inhibitors in CO2-saturated brine solution, Indones. J. Chem., 21 (4), 954–967.
[20] Somers, A.E., Hinton, B.R.W., de Bruin-Dickason, C., Deacon, G.B., Junk, P.C., and Forsyth, M., 2018, New, environmentally friendly, rare earth carboxylate corrosion inhibitors for mild steel, Corros. Sci., 139, 430–437.
[21] Biswas, A., Pal, S., and Udayabhanu, G., 2015, Experimental and theoretical studies of xanthan gum and its graft co-polymer as corrosion inhibitor for mild steel in 15% HCl, Appl. Surf. Sci., 353, 173–183.
[22] Qiang, Y., Zhang, S., Zhao, H., Tan, B., and Wang, L., 2019, Enhanced anticorrosion performance of copper by novel N-doped carbon dots, Corros. Sci., 161, 108193.
[23] Cen, H., Zhang, X., Zhao, L., Chen, Z., and Guo, X., 2019, Carbon dots as effective corrosion inhibitor for 5052 aluminium alloy in 0.1 M HCl solution, Corros. Sci., 161, 108197.
[24] Song, Y., Zhu, C., Song, J., Li, H., Du, D., and Lin, Y., 2017, Drug-derived bright and color-tunable N-doped carbon dots for cell imaging and sensitive detection of Fe3+ in living cells, ACS Appl. Mater. Interfaces, 9 (8), 7399–7405.
[25] Jiang, K., Sun, S., Zhang, L., Lu, Y., Wu, A., Cai, C., and Lin, H., 2015, Red, green, and blue luminescence by carbon dots: Full-color emission tuning and multicolor cellular imaging, Angew. Chem., Int. Ed., 54 (18), 5360–5363.
[26] Tao, S., Song, Y., Zhu, S., Shao, J., and Yang, B., 2017, A new type of polymer carbon dots with high quantum yield: From synthesis to investigation on fluorescence mechanism, Polymer, 116, 472–478.
[27] Guo, L., Li, L., Liu, M., Wan, Q., Tian, J., Huang, Q., Wen, Y., Liang, S., Zhang, X., and Wei, Y., 2018, Bottom-up preparation of nitrogen doped carbon quantum dots with green emission under microwave-assisted hydrothermal treatment and their biological imaging, Mater. Sci. Eng., C, 84, 60–66.
[28] Zhang, H., Huang, H., Ming, H., Li, H., Zhang, L., Liu, Y., and Kang, Z., 2012, Carbon quantum dots/Ag3PO4 complex photocatalysts with enhanced photocatalytic activity and stability under visible light, J. Mater. Chem., 22 (21), 10501–10506.
[29] Pan, L., Sun, S., Zhang, A., Jiang, K., Zhang, L., Dong, C., Huang, Q., Wu, A., and Lin, H., 2015, Truly fluorescent excitation-dependent carbon dots and their applications in multicolor cellular imaging and multidimensional sensing, Adv. Mater., 27 (47), 7782–7787.
[30] Roy, P., Chen, P.C., Periasamy, A.P., Chen, Y.N., and Chang, H.T., 2015, Photoluminescent carbon nanodots: Synthesis, physicochemical properties and analytical applications, Mater. Today, 18 (8), 447–458.
[31] Yang, Z., Xu, M., Liu, Y., He, F., Gao, F., Su, Y., Wei, H., and Zhang, Y., 2014, Nitrogen-doped, carbon-rich, highly photoluminescent carbon dots from ammonium citrate, Nanoscale, 6 (3), 1890–1895.
[32] Wang, Y., and Hu, A., 2014, Carbon quantum dots: Synthesis, properties and applications, J. Mater. Chem. C, 2 (34), 6921–6939.
[33] Xia, C., Zhu, S., Feng, T., Yang, M., and Yang, B., 2019, Evolution and synthesis of carbon dots: From carbon dots to carbonized polymer dots, Adv. Sci., 6 (23), 1901316.
[34] Arukalam, I.O., Madufor, I.C., Ogbobe, O., and Oguzie, E.E., 2014, Inhibition of mild steel corrosion in sulfuric acid medium by hydroxyethyl cellulose, Chem. Eng. Commun., 202 (1), 112–122.
[35] Shen, J., Zhang, T., Cai, Y., Chen, X., Shang, S., and Li, J., 2017, Highly fluorescent N,S-co-doped carbon dots: Synthesis and multiple applications, New J. Chem., 41 (19), 11125–11137.
[36] Dang, D.K., Sundaram, C., Ngo, Y.L.T., Chung, J.S., Kim, E.J., and Hur, S.H., 2018, One pot solid-state synthesis of highly fluorescent N and S co-doped carbon dots and its use as fluorescent probe for Ag+ detection in aqueous solution, Sens. Actuators, B, 255, 3284–3291.
[37] Zhu, C., Fu, Y., Liu, C., Liu, Y., Hu, L., Liu, J., Bello, I., Li, H., Liu, N., Guo, S., Huang, H., Lifshitz, Y., Lee, S.T., and Kang, Z., 2017, Carbon dots as fillers inducing healing/self-healing and anticorrosion properties in polymers, Adv. Mater., 29 (32), 1701399.
[38] Pathak, R.K., and Mishra, P., 2016, Drugs as corrosion inhibitors: A review, Int. J. Sci. Res., 5 (4), 671–677.
[39] Salleh, N.I.H., and Abdullah, A., 2019, Corrosion inhibition of carbon steel using palm oil leaves extract, Indones. J. Chem., 19 (3), 747–752.
[40] Cui, M., Ren, S., Xue, Q., Zhao, H., and Wang, L., 2017, Carbon dots as new eco-friendly and effective corrosion inhibitor, J. Alloys Compd., 726, 680–692.
[41] Xiang, Y., Long, Z., Li, C., Huang, H., and He, X., 2017, Inhibition of N80 steel corrosion in impure supercritical CO2 and CO2-saturated aqueous phases by using imino inhibitors, Int. J. Greenhouse Gas Control, 63, 141–149.
[42] Wang, W.C., Natelson, R.H., Stikeleather, L.F., and Roberts, W.L., 2012, CFD simulation of transient stage of continuous countercurrent hydrolysis of canola oil, Comput. Chem. Eng., 43, 108–119.
[43] Tamalmani, K., and Husin, H., 2020, Review on corrosion inhibitors for oil and gas corrosion issues, Appl. Sci., 10 (10), 3389.
[44] Ye, Y., Zou, Y., Jiang, Z., Yang, Q., Chen, L., Guo, S., and Chen, H., 2020, An effective corrosion inhibitor of N doped carbon dots for Q235 steel in 1 M HCl solution, J. Alloys Compd., 815, 152338.
[45] Liu, Z., Ye, Y.W., and Chen, H., 2020, Corrosion inhibition behavior and mechanism of N-doped carbon dots for metal in acid environment, J. Cleaner Prod., 270, 122458.
[46] Zhu, M., He, Z., Guo, L., Zhang, R., Anadebe, V.C., Obot, I.B., and Zheng, X., 2021, Corrosion inhibition of eco-friendly nitrogen-doped carbon dots for carbon steel in acidic media: Performance and mechanism investigation, J. Mol. Liq., 342, 117583.
[47] Cui, M., Ren, S., Zhao, H., Wang, L., and Xue, Q., 2018, Novel nitrogen doped carbon dots for corrosion inhibition of carbon steel in 1 M HCl solution, Appl. Surf. Sci., 443, 145–156.
[48] Saraswat, V., and Yadav, M., 2020, Carbon Dots as green corrosion inhibitor for mild steel in HCl solution, ChemistrySelect, 5 (25), 7347–7357.
[49] Ye, Y., Yang, D., Chen, H., Guo, S., Yang, Q., Chen, L., Zhao, H., and Wang, L., 2020, A high-efficiency corrosion inhibitor of N-doped citric acid-based carbon dots for mild steel in hydrochloric acid environment, J. Hazard. Mater., 381, 121019.
[50] Yang, D., Ye, Y., Su, Y., Liu, S., Gong, D., and Zhao, H., 2019, Functionalization of citric acid-based carbon dots by imidazole toward novel green corrosion inhibitor for carbon steel, J. Cleaner Prod., 229, 180–192.
[51] Cao, S., Liu, D., Wang, T., Ma, A., Liu, C., Zhuang, X., Ding, H., Mamba, B.B., and Gui, J., 2021, Nitrogen-doped carbon dots as high-effective inhibitors for carbon steel in acidic medium, Colloids Surf., A, 616, 126280.
[52] Cao, C., 1996, On electrochemical techniques for interface inhibitor research, Corros. Sci., 38 (12), 2073–2082.
[53] Anindita, F., Darmawan, N., and Mas’ud, Z.A., 2018, Fluorescence carbon dots from durian as an eco-friendly inhibitor for copper corrosion, AIP Conf. Proc., 2014, 020008.
[54] Ye, Y., Yang, D., and Chen, H., 2019, A green and effective corrosion inhibitor of functionalized carbon dots, J. Mater. Sci. Technol., 35 (10), 2243–2253.
[55] Li, J., Lv, J., Fu, L., Tang, M., and Wu, X., 2020, New ecofriendly nitrogen-doped carbon quantum dots as effective corrosion inhibitor for saturated CO2 3% NaCl solution, Russ. J. Appl. Chem., 93 (3), 380–392.
[56] Cui, M., Qiang, Y., Wang, W., Zhao, H., and Ren, S., 2021, Microwave synthesis of eco-friendly nitrogen doped carbon dots for the corrosion inhibition of Q235 carbon steel in 0.1 M HCl, Int. J. Electrochem. Sci., 16, 151019.
[57] Cui, M., Yu, Y., and Zheng, Y., 2021, Effective corrosion inhibition of carbon steel in hydrochloric acid by dopamine-produced carbon dots, Polymers, 13 (12), 1923.
[58] Luo, J., Cheng, X., Zhong, C., Chen, X., Ye, Y.W., Zhao, H., and Chen, H., 2021, Effect of reaction parameters on the corrosion inhibition behavior of N-doped carbon dots for metal in 1 M HCl solution, J. Mol. Liq., 338, 116783.
[59] Xu, Q., Ge, K., Zhang, S., and Tan, B., 2021, Understanding the adsorption and inhibitive properties of nitrogen-doped carbon dots for copper in 0.5 M H2SO4 solution, J. Taiwan Inst. Chem. Eng., 125, 23–34.
[60] Zhang, Y., Zhang, S., Tan, B., Guo, L., and Li, H., 2021, Solvothermal synthesis of functionalized carbon dots from amino acid as an eco-friendly corrosion inhibitor for copper in sulfuric acid solution, J. Colloid Interface Sci., 604, 1–14.
[61] Luo, J., Cheng, X., Chen, X., Zhong, C. F., Xie, H., Ye, Y.W., Zhao, H.C., Li, Y., and Chen, H., 2021, The effect of N and S ratios in N,S co-doped carbon dot inhibitor on metal protection in 1 M HCl solution, J. Taiwan Inst. Chem. Eng., 127, 387–398.
[62] Zhu, M., Guo, L., He, Z., Marzouki, R., Zhang, R., and Berdimurodov, E., 2022, Insights into the newly synthesized N-doped carbon dots for Q235 steel corrosion retardation in acidizing media: A detailed multidimensional study, J. Colloid Interface Sci., 608, 2039–2049.
[63] Pan, L., Li, G., Wang, Z., Liu, D., Zhu, W., Tong, C., Zhu, R., and Hu, S., 2021, Carbon dots as environment-friendly and efficient corrosion inhibitors for Q235 steel in 1 M HCl, Langmuir, 37 (49), 14336–14344.
[64] Saraswat, V., Kumari, R., and Yadav, M., 2022, Novel carbon dots as efficient green corrosion inhibitor for mild steel in HCl solution: Electrochemical, gravimetric and XPS studies, J. Phys. Chem. Solids, 160, 110341.
[65] Hosseini, S.M.A., Salari, M., Jamalizadeh, E., Khezripoor, S., and Seifi, M., 2010, Inhibition of mild steel corrosion in sulfuric acid by some newly synthesized organic compounds, Mater. Chem. Phys., 119 (1-2), 100–105.
[66] Kahyarian, A., and Nesic, S., 2019, A new narrative for CO2 corrosion of mild steel, J. Electrochem. Soc., 166 (11), C3048–C3063.
[67] Li, J.X., Schieberle, P., and Steinhaus, M., 2017, Insights into the key compounds of durian (Durio zibethinus L. ‘Monthong’) pulp odor by odorant quantitation and aroma simulation experiments, J. Agric. Food Chem., 65 (3), 639–647.
[68] Ashassi-Sorkhabi, H., Majidi, M.R., and Seyyedi, K., 2004, Investigation of inhibition effect of some amino acids against steel corrosion in HCl solution, Appl. Surf. Sci., 225 (1-4), 176–185.
[69] Hu, Z., Meng, Y., Ma, X., Zhu, H., Li, J., Li, C., and Cao, D., 2016, Experimental and theoretical studies of benzothiazole derivatives as corrosion inhibitors for carbon steel in 1 M HCl, Corros. Sci., 112, 563–575.
[70] Liu, J., Wang, D., Gao, L., and Zhang, D., 2016, Synergism between cerium nitrate and sodium dodecylbenzenesulfonate on corrosion of AA5052 aluminium alloy in 3 wt.% NaCl solution, Appl. Surf. Sci., 389, 369–377.
[71] Abdallah, M., Sobhi, M., and Altass, H.M., 2016, Corrosion inhibition of aluminum in hydrochloric acid by pyrazinamide derivatives, J. Mol. Liq., 223, 1143–1150.
[72] Li, X., Deng, S., and Xie, X., 2014, Experimental and theoretical study on corrosion inhibition of oxime compounds for aluminium in HCl solution, Corros. Sci., 81, 162–175.
[73] Dariva, C.G., and Galio, A.F., 2014, “Corrosion Inhibitors – Principles, Mechanisms and Applications” in Developments in Corrosion Protection, Eds. Aliofkhazraei, M., IntechOpen, Rijeka, Croatia, 365–379.
[74] Yaro, A.S., Khadom, A.A., and Ibraheem, H.F., 2011, Peach juice as an anti-corrosion inhibitor of mild steel, Anti-Corros. Methods Mater., 58 (3), 116–124.
[75] Issaadi, S., Douadi, T., and Chafaa, S., 2014, Adsorption and inhibitive properties of a new heterocyclic furan Schiff base on corrosion of copper in HCl 1M: Experimental and theoretical investigation, Appl. Surf. Sci., 316, 582–589.
[76] Rudnick, L.R., 2009, Lubricant Additives: Chemistry and Applications, 2nd Ed., CRC Press, USA.
[77] Tang, Z., 2019, A review of corrosion inhibitors for rust preventative fluids, Curr. Opin. Solid State Mater. Sci., 23 (4), 100759.
[78] Fayomi, O.S.I., Anawe, P.A.L., and Daniyan, A., 2018, “The Impact of Drugs as Corrosion Inhibitors on Aluminum Alloy in Coastal-Acidified Medium, in Corrosion Inhibitors, Principles and Recent Applications” in Corrosion Inhibitors, Principles and Recent Applications, Eds. Aliofkhazraei, M., IntechOpen, Rijeka, Croatia, 81–94.
[79] Berdimurodov, E., Kholikov, A., Akbarov, K., Xu, G., Abdullah, A.M., and Hosseini, M., 2020, New anti-corrosion inhibitor (3ar,6ar)-3a,6a-di-p-tolyltetrahydroimidazo[4,5-d]imidazole-2,5(1 h,3h)-dithione for carbon steel in 1 M HCl medium: gravimetric, electrochemical, surface and quantum chemical analyses, Arabian J. Chem., 13 (10), 7504–7523.
[80] Khadiri, A., Saddik, R., Bekkouche, K., Aouniti, A., Hammouti, B., Benchat, N., Bouachrine, M., and Solmaz, R., 2016, Gravimetric, electrochemical and quantum chemical studies of some pyridazine derivatives as corrosion inhibitors for mild steel in 1 M HCl solution, J. Taiwan Inst. Chem. Eng., 58, 552–564.
[81] Anejjar, A., Salghi, R., Zarrouk, A., Benali, O., Zarrok, H., Hammouti, B., and Ebenso, E.E., 2014, Inhibition of carbon steel corrosion in 1 M HCl medium by potassium thiocyanate, J. Assoc. Arab Univ. Basic Appl. Sci., 15, 21–27.
[82] Ferreira, E.S., Giacomelli, C., Giacomelli, F.C., and Spinelli, A., 2004, Evaluation of the inhibitor effect of L-ascorbic acid on the corrosion of mild steel, Mater. Chem. Phys., 83 (1), 129–143.
[83] Behpour, M., Ghoreishi, S.M., Soltani, N., and Salavati-Niasari, M., 2009, The inhibitive effect of some bis-N,S-bidentate Schiff bases on corrosion behaviour of 304 stainless steel in hydrochloric acid solution, Corros. Sci., 51 (5), 1073–1082.
[84] Wang, D., Li, Y., Chen, B., and Zhang, L., 2020, Novel surfactants as green corrosion inhibitors for mild steel in 15% HCl: Experimental and theoretical studies, Chem. Eng. J., 402, 126219.
[85] Ismail, A., Irshad, H.M., Zeino, A., and Toor, I.H., 2019, Electrochemical corrosion performance of aromatic functionalized imidazole inhibitor under hydrodynamic conditions on API X65 carbon steel in 1 M HCl solution, Arabian J. Sci. Eng., 44 (6), 5877–5888.
[86] Goni, L.K.M.O., Mazumder, M.A.J., Ali, S.A., Nazal, M.K., and Al-Muallem, H.A., 2019, Biogenic amino acid methionine-based corrosion inhibitors of mild steel in acidic media, Int. J. Miner. Metall. Mater., 26 (4), 467–482.
[87] Wahyuningrum, D., Achmad, S., Syah, Y.M., Buchari, B., and Ariwahjoedi, B., 2008, The Synthesis of imidazoline derivative compounds as corrosion inhibitor towards carbon steel in 1% NaCl solution, ITB J. Sci.,40 (1), 33–48.
[88] Li, X., Deng, S., Lin, T., Xie, X., and Du, G., 2019, Cassava starch ternary graft copolymer as a corrosion inhibitor for steel in HCl solution, Integr. Med. Res., 9 (2), 2196–2207.
[89] Lahrour, S., Benmoussat, A., Bouras, B., Mansri, A., Tannaouga, L., and Marzorati, S., 2019, Glycerin-grafted starch as corrosion inhibitor of C-Mn steel in 1 M HCl solution, Appl. Sci., 9 (21), 4684.
[90] Baari, M.J., and Sabandar, C.W., 2021, A Review on expired drug-based corrosion inhibitors: chemical composition, structural effects, inhibition mechanism, current challenges, and future prospects, Indones. J. Chem., 21 (5), 1316–1336.
[91] Singh, P., Chauhan, D.S., Srivastava, K., Srivastava, V., and Quraishi, M.A., 2017, Expired atorvastatin drug as corrosion inhibitor for mild steel in hydrochloric acid solution, Int. J. Ind. Chem., 8 (4), 363–372.
DOI: https://doi.org/10.22146/ijc.72327
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