Research Article
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Year 2024, Volume: 42 Issue: 2, 414 - 424, 30.04.2024

Abstract

References

  • [1] Ekins P, Vanner R, Firebrace J. Zero emissions of oil in water from offshore oil and gas installations: Economic and environmental implications. J Clean Prod 2007;15:1302–1315. [CrossRef]
  • [2] Lopez DA, Perez T, Simison SN. The influence of microstructure and chemical composition of carbon and low alloy steels in CO2 corrosion. A state-of-the-art appraisal. Mater Des 2003;24:561–575. [CrossRef]
  • [3] Liu X, Okafor PC, Zheng YG. The inhibition of CO2 corrosion of N80 mild steel in single liquid phase flow by aminoethyl imidazoline derivatives. Corros Sci 2009;51:744–751. [CrossRef]
  • [4] Corbin D, Willson E. New technology for real-time corrosion detection, In: Tri-Service Corrosion Conference; 2007 Jan; USA. 2007. pp. 114.
  • [5] Oxford W, Foss R. Corrosion of oil and gas well equipment. Nelson, Canada: Harropian Books; 1958.
  • [6] Brondel D, Edwards R, Hayman A, Hill D, Mehta S, Semerad T. Corrosion in the oil industry. Oilfield Rev 1994;6:4–18.
  • [7] Hadley R.F. Corrosion by micro-organisms in aqueous and soil environments. In: Uhlig HH editor. Corrosion handbook; 1948; USA: John Wiley & Sons; 1948.
  • [8] Videla HA. Microbially induced corrosion: An updated overview. Int Biodeterior Biodegr 2001;48:176–201. [CrossRef]
  • [9] Beech IB, Sunner J. Biocorrosion: Towards understanding interactions between biofilms and metals. Curr Opin Biotechnol 2004;15:181–186. [CrossRef]
  • [10] Magot M, Ollivier B, Patel BKC. Microbiology of petroleum reservoirs. Anton Leeuw 2000;77:103–116. [CrossRef]
  • [11] Videla HA, Herrera LK. Microbiologically influenced corrosion: ooking to the future. Int Microbiol 2005;8:169–180.
  • [12] Popoola LT, Grema AS, Latinwo GK, Gutti B, Balogun AS. Corrosion problems during oil and gas production and its mitigation. Int J Ind Chem 2013;4:1–15. [CrossRef]
  • [13] Okafor PC, Liu CB, Zhu YJ, Zheng YG. Corrosion and corrosion inhibition behavior of N80 and P110 carbon steels in CO2-saturated simulated formation water by rosin amide ımidazoline. Ind Eng Chem Res 2011;50:7273–7281. [CrossRef]
  • [14] Zhu SD, Fu AQ, Miao J, Yin ZF, Zhou GS, Wei JF. Corrosion of N80 carbon steel in oil field formation water containing CO2 in the absence and presence of acetic acid. Corros Sci 2011;53:3156–165. [CrossRef]
  • [15] Liu H, Fu C, Gu T, Zhang G, Lv Y, Wang H, et al. Corrosion behavior of carbon steel in the presence of sulfate reducing bacteria and iron oxidizing bacteria cultured in oilfield produced water. Corros Sci 2015;100:484–495. [CrossRef]
  • [16] Tüccar T, Sungur E. Potential syntrophic halophilic partners in sulfate-reducing bacterial enrichments obtained from an oil field, In: World Microbe Forum (Online Worldwide, An ASM & FEMS collaboration); 2021 Jun.
  • [17] ASTM-American Society for Testing And Material. Standard practice for preparing, Cleaning, and Evaluating Corrosion Test Specimens [standard G1-03], In: ASTM Int. ASTM Handbook 3.02 Corrosion of Metals, Wear and Erosion, West Conshohocken, PA, 2017.
  • [18] Campanac C, Pineau L, Payard A, Baziard-Mouysset G, Roques C. Interactions between biocide cationic agents and bacterial biofilms. Antimicrob Agents Chemother 2002; 46;1469– 1474. [CrossRef]
  • [19] Collins AG. Geochemistry Of Oilfield Waters. Amsterdam, Netherlands: Elsevier; 1975. [20] Varjani SJ, Gnansounou E. Microbial dynamics in petroleum oilfields and their relationship with physiological properties of petroleum oil reservoirs. Bioresour Technol 2017;245:1258–1265. [CrossRef]
  • [21] Hussain A, Hasan A, Javid A, Qazi JI. Exploited application of sulfate-reducing bacteria for concomitant treatment of metallic and non-metallic wastes: A mini review. 3 Biotech 2016;6:1–10. [CrossRef]
  • [22] Tian H, Gao P, Chen Z, Li Y, Li Y, Wang Y, et al. Compositions and abundances of sulfate-reducing and sulfur-oxidizing microorganisms inwater-flooded petroleum reservoirs with different temperatures in China. Front Microbiol 2017;8:143. [CrossRef]
  • [23] Berdugo-Clavijo C, Gieg LM. Conversion of crude oil to methane by a microbial consortium enriched from oil reservoir production waters. Front Microbiol 2014;5:197. [CrossRef]
  • [24] Bidzhieva SK, Sokolova DS, Tourova TP, Nazina, TN. Bacteria of the genus sphaerochaeta from low-temperature heavy oil reservoirs (Russia). Microbiol 2018;87: 757–765. [CrossRef]
  • [25] Liu JF, Sun XB, Yang GC, Mbadinga SM, Gu JD, Mu BZ. Analysis of microbial communities in the oil reservoir subjected to CO2-flooding by using functional genes as molecular biomarkers for microbial CO2 sequestration. Front Microbiol 2015;6:236. [CrossRef]
  • [26] Okoro CC, Amund OO. Microbial community structure of a lowsulfate oil producing facility indicate dominance of oil degrading/nitrate reducing bacteria and methanogens. Pet Sci Technol 2018;36:293–301. [CrossRef]
  • [27] Greene AC, Patel BK, Sheehy AJ. Deferribacter thermophilus gen. nov., sp. nov., a novel thermophilic manganese- and iron-reducing bacterium isolated from a petroleum reservoir. Int J Syst Bacteriol 1997;47:505–509. [CrossRef]
  • [28] Dong H, Zhang F, Xu T, Liu Y, Du Y, Wang C, et al. Culture-dependent and culture-independent methods reveal microbe-clay mineral interactions by dissimilatory iron-reducing bacteria in an integral oilfield. Sci Total Environ 2022;840:156577. [CrossRef]
  • [29] Hamme DJ, Singh A, Ward OP. Recent advances in petroleum microbiology. Microbiol Mol Biol Rev 2003;67:503–549. [CrossRef]
  • [30] Babaarslan C, Tekeli A, Mehmetoğlu T. Biodegradation of BTEX compounds by a mixed culture obtained from petroleum formationwater. Energy Sources 2003;25:733–742. [CrossRef]
  • [31] Tüccar T, Ilhan-Sungur E, Muyzer G. Bacterial community composition in produced water of Diyarbakır oil fields in turkey. Johns Matthey Technol Rev 2020;64:452–465. [CrossRef]
  • [32] Kaya T. Research of surface active properties of some microorganisms in various industrial wastes. Master Thesis. Ankara Turkey: Biology Department, Gazi University; 2008.
  • [33] Tüccar T, Ilhan-Sungur E, Abbas B, Muyzer G. Coexistence of sulfate reducers with the other oil bacterial groups in Diyarbakır oil fields. Anaerobe 2019;59:19–31. [CrossRef]
  • [34] Ibrahim A, Hawboldt K, Bottaro C, Khan F. Review and analysis of microbiologically influenced corrosion: the chemical environment in oil and gas facilities. Corros Eng Sci Technol 2018;53:549–563. [CrossRef] [35] Wang B, Xin T, Gao Z. Role of HCO3- and Cl- in the pitting of 20CrMo steel in simulated oil field environment. Int J Electrochem Sci 2017;12:7205–7215. [CrossRef]
  • [36] Asaduzzaman MD, Mohammad M, Islam MM. Effects of concentration of sodium chloride solution on the pitting corrosion behavior of 304L austenitic stainless steel. Chem Ind Chem Eng 2011;17:477–483. [CrossRef]
  • [37] Liu C, Gong M, Zheng X. Pitting corrosion of 2205 duplex stainless steel at high concentrations of NaCl solution. Int J Electrochem Sci 2018;13:7432–7441. [CrossRef]
  • [38] Perez TE. Corrosion in the oil and gas industry: An increasing challenge for materials. JOM 2013;65:1033–1042. [CrossRef]
  • [39] Craig B. Predicting the conductivity of water-in-oil solutions as a means to estimate corrosiveness. Corrosion 1998;54:657–662. [CrossRef]
  • [40] Gonzalez-Rodriguez JG, Casales M, Salinas-Bravo VM, Albarran JL, Martinez L. Effect of microstructure on the stress corrosion cracking of X-80 pipeline steel in diluted sodium bicarbonate solutions. Corrosion 2002;58:584–590. [CrossRef]
  • [41] Song W, Zhang J, Li X, Li B, Li F, Fu A. Sulfate Reducting Bacteria Corrosion Component Study of N80 Steel in Simulating Oilfield Produced Water, In: Han Y. editör. Advances in Materials Processing. Lecture Notes in Mechanical Engineering; 2018 Apr; Singapore: Springer; 2018. p. 1187–1194. [CrossRef]
  • [42] Elumalai P, AlSalhi MS, Mehariya S, Karthikeyan OP, Devanesan S, Parthipan P, et al. Bacterial community analysis of biofilm on API 5LX carbon steel in an oil reservoir environment. Bioprocess Biosyst Eng 2021;44:355–368. [CrossRef]
  • [43] de Oliveira ESD, Roseana F, Pereira C, Alice M, Lima GDA. Study on biofilm forming microorganisms associated with the biocorrosion of x80 pipeline steel in produced water from oilfield. Mater Res 2021;24:e20210196. [CrossRef]
  • [44] Wang K, Chen F, Li H, Luo M, He J, Liao Z. Corrosion behavior of l245 pipeline steel in shale gas fracturing produced water containing ıron bacteria. J Chin Soc Corros 2021;41:248– 254.
  • [45] Feng S, Li Y, Liu H, Liu Q, Chen X, Yu H, et al. Microbiologically influenced corrosion of carbon steel pipeline in shale gas field produced water containing CO2 and polyacrylamide inhibitor, J Nat Gas Sci Eng 2020;80:103395. [CrossRef]
  • [46] O’Toole G, Kaplan HB, Kolter R. Biofilm formation as microbial development. Annu Rev Microbiol 2000;54:49–79. [CrossRef]
  • [47] Liu L, Wu X, Wang Q, Yan Z, Wen X, Tang J, et al. An overview of microbiologically influenced corrosion: mechanisms and its control by microbes. Corros Rev 2022; 40:103–117. [CrossRef]
  • [48] Telegdi J, Shaban A, Vastag G. Biocorrosion-Steel, In: Wandelt K editor. Encyclopedia of Interfacial Chemistry: Surface Science and Electrochemistry; 2018 Feb; Amsterdam, The Netherlands: Elsevier; 2018. pp. 28–42. [CrossRef]
  • [49] Von Wolzogen Kühr CAH, Van Der Vlugt LS. The graphitization of cast iron as an electrochemical process in anaerobic soils. Water 1934;18:147–165.
  • [50] King RA, Miller JD. Corrosion by the sulphate-reducing bacteria. Nature 1971;233:491–492. [CrossRef]
  • [51] Iverson WP, Olson GJ. Anaerobic corrosion by sulfate reducing bacteria due to highly reactive volatile phosphorus compounds. Final report. Available at: https://www.osti.gov/biblio/5175515 Accessed on Mar13, 2024.
  • [52] Beech IB, Cheung, CWS. Interactions of exopolymers produced by sulphate- reducing bacteria with metal ions. Int Biodeter Biodegr 1995;35:59–72. [CrossRef]
  • [53] Enning D, Garrelfs J. Corrosion of iron by sulfate-reducing bacteria: new views of an old problem. Appl Environ Microbiol 2014;80:1226–1236. [CrossRef]
  • [54] Lv M, Du M. A review: microbiologically influenced corrosion and the effect of cathodic polarization on typical bacteria. Rev Environ Sci Biotechnol 2018;17:431–446. [CrossRef]
  • [55] Jia R, Unsal T, Xu D, Lekbach Y, Gu T. Microbiologically influenced corrosion and current mitigation strategies: a state of the art review. Int Biodeter Biodegr 2019;137:42–58. [CrossRef]
  • [56] Tüccar T, Ilhan-Sungur E. Potential Syntrophic Halophilic Partners in Sulfate-Reducing Bacterial Enrichments Derived from Oil Reservoir: Assessment by Sub-culturing Plus Diluting Strategy and Community Analysis. In: Stepec BAA, Wunch K, Skovhus TL, editors. Petroleum Microbiology: The Role of Microorganisms in the Transition to Net Zero Energy. 1st edition. CRC Press Taylor & Francis Group; 2024.
  • [57] Davey ME, Wood WA, Key R, Nakamura K, Stahl DA. Isolation of three species of Geotoga and Petrotoga: Two new genera, representing a new lineage in the bacterial line of descent distantly related to the “Thermotogales”. Syst Appl Microbiol 1993;16:191–200. [CrossRef]
  • [58] Dahle H, Birkeland NK. Thermovirga lienii gen. nov., sp. nov., a novel moderately thermophilic, anaerobic, amino-acid-degrading bacterium isolated from a North Sea oil well. Int J Syst Evol Microbiol 2006;56(Pt 7):1539–1545. [CrossRef]

Corrosion behavior of N80 tubing steel in the produced water

Year 2024, Volume: 42 Issue: 2, 414 - 424, 30.04.2024

Abstract

One of the most common problems encountered in the oil industry is the microbiologi- cally induced corrosion (MIC) of steel equipment by the produced water (PW). In this aspect, PW sample, which is known to contain microorganisms, was taken from Adıyaman oil field and used in corrosion tests of N80 tubing steel. Two different laboratory scale systems, test (with non-sterile PW) and control (with sterile PW), were set up and operated at 70°C over 720 h. For corrosion analysis, the coupons were removed from the laboratory-scale systems at certain time intervals and, gravimetric and electrochemical analyses were carried out. The surface of the coupons was examined by scanning electron microscopy (SEM). The corrosion rates of the test coupons obtained from gravimetric analyses were higher than the control ones during the experiment, and the test coupons were 1.46 times more corroded at the end of the experiment. Additionally, it was determined that the current values of the test coupons were significantly higher than those in the control system (p<0.05). The results of corrosion analyses pointed out that N80 steel was corroded microbiologically. SEM analysis showed that microorganisms were present among the corrosion products. The corrosion data obtained from the control system also indicated that the PW was aggressive for N80 steel.

References

  • [1] Ekins P, Vanner R, Firebrace J. Zero emissions of oil in water from offshore oil and gas installations: Economic and environmental implications. J Clean Prod 2007;15:1302–1315. [CrossRef]
  • [2] Lopez DA, Perez T, Simison SN. The influence of microstructure and chemical composition of carbon and low alloy steels in CO2 corrosion. A state-of-the-art appraisal. Mater Des 2003;24:561–575. [CrossRef]
  • [3] Liu X, Okafor PC, Zheng YG. The inhibition of CO2 corrosion of N80 mild steel in single liquid phase flow by aminoethyl imidazoline derivatives. Corros Sci 2009;51:744–751. [CrossRef]
  • [4] Corbin D, Willson E. New technology for real-time corrosion detection, In: Tri-Service Corrosion Conference; 2007 Jan; USA. 2007. pp. 114.
  • [5] Oxford W, Foss R. Corrosion of oil and gas well equipment. Nelson, Canada: Harropian Books; 1958.
  • [6] Brondel D, Edwards R, Hayman A, Hill D, Mehta S, Semerad T. Corrosion in the oil industry. Oilfield Rev 1994;6:4–18.
  • [7] Hadley R.F. Corrosion by micro-organisms in aqueous and soil environments. In: Uhlig HH editor. Corrosion handbook; 1948; USA: John Wiley & Sons; 1948.
  • [8] Videla HA. Microbially induced corrosion: An updated overview. Int Biodeterior Biodegr 2001;48:176–201. [CrossRef]
  • [9] Beech IB, Sunner J. Biocorrosion: Towards understanding interactions between biofilms and metals. Curr Opin Biotechnol 2004;15:181–186. [CrossRef]
  • [10] Magot M, Ollivier B, Patel BKC. Microbiology of petroleum reservoirs. Anton Leeuw 2000;77:103–116. [CrossRef]
  • [11] Videla HA, Herrera LK. Microbiologically influenced corrosion: ooking to the future. Int Microbiol 2005;8:169–180.
  • [12] Popoola LT, Grema AS, Latinwo GK, Gutti B, Balogun AS. Corrosion problems during oil and gas production and its mitigation. Int J Ind Chem 2013;4:1–15. [CrossRef]
  • [13] Okafor PC, Liu CB, Zhu YJ, Zheng YG. Corrosion and corrosion inhibition behavior of N80 and P110 carbon steels in CO2-saturated simulated formation water by rosin amide ımidazoline. Ind Eng Chem Res 2011;50:7273–7281. [CrossRef]
  • [14] Zhu SD, Fu AQ, Miao J, Yin ZF, Zhou GS, Wei JF. Corrosion of N80 carbon steel in oil field formation water containing CO2 in the absence and presence of acetic acid. Corros Sci 2011;53:3156–165. [CrossRef]
  • [15] Liu H, Fu C, Gu T, Zhang G, Lv Y, Wang H, et al. Corrosion behavior of carbon steel in the presence of sulfate reducing bacteria and iron oxidizing bacteria cultured in oilfield produced water. Corros Sci 2015;100:484–495. [CrossRef]
  • [16] Tüccar T, Sungur E. Potential syntrophic halophilic partners in sulfate-reducing bacterial enrichments obtained from an oil field, In: World Microbe Forum (Online Worldwide, An ASM & FEMS collaboration); 2021 Jun.
  • [17] ASTM-American Society for Testing And Material. Standard practice for preparing, Cleaning, and Evaluating Corrosion Test Specimens [standard G1-03], In: ASTM Int. ASTM Handbook 3.02 Corrosion of Metals, Wear and Erosion, West Conshohocken, PA, 2017.
  • [18] Campanac C, Pineau L, Payard A, Baziard-Mouysset G, Roques C. Interactions between biocide cationic agents and bacterial biofilms. Antimicrob Agents Chemother 2002; 46;1469– 1474. [CrossRef]
  • [19] Collins AG. Geochemistry Of Oilfield Waters. Amsterdam, Netherlands: Elsevier; 1975. [20] Varjani SJ, Gnansounou E. Microbial dynamics in petroleum oilfields and their relationship with physiological properties of petroleum oil reservoirs. Bioresour Technol 2017;245:1258–1265. [CrossRef]
  • [21] Hussain A, Hasan A, Javid A, Qazi JI. Exploited application of sulfate-reducing bacteria for concomitant treatment of metallic and non-metallic wastes: A mini review. 3 Biotech 2016;6:1–10. [CrossRef]
  • [22] Tian H, Gao P, Chen Z, Li Y, Li Y, Wang Y, et al. Compositions and abundances of sulfate-reducing and sulfur-oxidizing microorganisms inwater-flooded petroleum reservoirs with different temperatures in China. Front Microbiol 2017;8:143. [CrossRef]
  • [23] Berdugo-Clavijo C, Gieg LM. Conversion of crude oil to methane by a microbial consortium enriched from oil reservoir production waters. Front Microbiol 2014;5:197. [CrossRef]
  • [24] Bidzhieva SK, Sokolova DS, Tourova TP, Nazina, TN. Bacteria of the genus sphaerochaeta from low-temperature heavy oil reservoirs (Russia). Microbiol 2018;87: 757–765. [CrossRef]
  • [25] Liu JF, Sun XB, Yang GC, Mbadinga SM, Gu JD, Mu BZ. Analysis of microbial communities in the oil reservoir subjected to CO2-flooding by using functional genes as molecular biomarkers for microbial CO2 sequestration. Front Microbiol 2015;6:236. [CrossRef]
  • [26] Okoro CC, Amund OO. Microbial community structure of a lowsulfate oil producing facility indicate dominance of oil degrading/nitrate reducing bacteria and methanogens. Pet Sci Technol 2018;36:293–301. [CrossRef]
  • [27] Greene AC, Patel BK, Sheehy AJ. Deferribacter thermophilus gen. nov., sp. nov., a novel thermophilic manganese- and iron-reducing bacterium isolated from a petroleum reservoir. Int J Syst Bacteriol 1997;47:505–509. [CrossRef]
  • [28] Dong H, Zhang F, Xu T, Liu Y, Du Y, Wang C, et al. Culture-dependent and culture-independent methods reveal microbe-clay mineral interactions by dissimilatory iron-reducing bacteria in an integral oilfield. Sci Total Environ 2022;840:156577. [CrossRef]
  • [29] Hamme DJ, Singh A, Ward OP. Recent advances in petroleum microbiology. Microbiol Mol Biol Rev 2003;67:503–549. [CrossRef]
  • [30] Babaarslan C, Tekeli A, Mehmetoğlu T. Biodegradation of BTEX compounds by a mixed culture obtained from petroleum formationwater. Energy Sources 2003;25:733–742. [CrossRef]
  • [31] Tüccar T, Ilhan-Sungur E, Muyzer G. Bacterial community composition in produced water of Diyarbakır oil fields in turkey. Johns Matthey Technol Rev 2020;64:452–465. [CrossRef]
  • [32] Kaya T. Research of surface active properties of some microorganisms in various industrial wastes. Master Thesis. Ankara Turkey: Biology Department, Gazi University; 2008.
  • [33] Tüccar T, Ilhan-Sungur E, Abbas B, Muyzer G. Coexistence of sulfate reducers with the other oil bacterial groups in Diyarbakır oil fields. Anaerobe 2019;59:19–31. [CrossRef]
  • [34] Ibrahim A, Hawboldt K, Bottaro C, Khan F. Review and analysis of microbiologically influenced corrosion: the chemical environment in oil and gas facilities. Corros Eng Sci Technol 2018;53:549–563. [CrossRef] [35] Wang B, Xin T, Gao Z. Role of HCO3- and Cl- in the pitting of 20CrMo steel in simulated oil field environment. Int J Electrochem Sci 2017;12:7205–7215. [CrossRef]
  • [36] Asaduzzaman MD, Mohammad M, Islam MM. Effects of concentration of sodium chloride solution on the pitting corrosion behavior of 304L austenitic stainless steel. Chem Ind Chem Eng 2011;17:477–483. [CrossRef]
  • [37] Liu C, Gong M, Zheng X. Pitting corrosion of 2205 duplex stainless steel at high concentrations of NaCl solution. Int J Electrochem Sci 2018;13:7432–7441. [CrossRef]
  • [38] Perez TE. Corrosion in the oil and gas industry: An increasing challenge for materials. JOM 2013;65:1033–1042. [CrossRef]
  • [39] Craig B. Predicting the conductivity of water-in-oil solutions as a means to estimate corrosiveness. Corrosion 1998;54:657–662. [CrossRef]
  • [40] Gonzalez-Rodriguez JG, Casales M, Salinas-Bravo VM, Albarran JL, Martinez L. Effect of microstructure on the stress corrosion cracking of X-80 pipeline steel in diluted sodium bicarbonate solutions. Corrosion 2002;58:584–590. [CrossRef]
  • [41] Song W, Zhang J, Li X, Li B, Li F, Fu A. Sulfate Reducting Bacteria Corrosion Component Study of N80 Steel in Simulating Oilfield Produced Water, In: Han Y. editör. Advances in Materials Processing. Lecture Notes in Mechanical Engineering; 2018 Apr; Singapore: Springer; 2018. p. 1187–1194. [CrossRef]
  • [42] Elumalai P, AlSalhi MS, Mehariya S, Karthikeyan OP, Devanesan S, Parthipan P, et al. Bacterial community analysis of biofilm on API 5LX carbon steel in an oil reservoir environment. Bioprocess Biosyst Eng 2021;44:355–368. [CrossRef]
  • [43] de Oliveira ESD, Roseana F, Pereira C, Alice M, Lima GDA. Study on biofilm forming microorganisms associated with the biocorrosion of x80 pipeline steel in produced water from oilfield. Mater Res 2021;24:e20210196. [CrossRef]
  • [44] Wang K, Chen F, Li H, Luo M, He J, Liao Z. Corrosion behavior of l245 pipeline steel in shale gas fracturing produced water containing ıron bacteria. J Chin Soc Corros 2021;41:248– 254.
  • [45] Feng S, Li Y, Liu H, Liu Q, Chen X, Yu H, et al. Microbiologically influenced corrosion of carbon steel pipeline in shale gas field produced water containing CO2 and polyacrylamide inhibitor, J Nat Gas Sci Eng 2020;80:103395. [CrossRef]
  • [46] O’Toole G, Kaplan HB, Kolter R. Biofilm formation as microbial development. Annu Rev Microbiol 2000;54:49–79. [CrossRef]
  • [47] Liu L, Wu X, Wang Q, Yan Z, Wen X, Tang J, et al. An overview of microbiologically influenced corrosion: mechanisms and its control by microbes. Corros Rev 2022; 40:103–117. [CrossRef]
  • [48] Telegdi J, Shaban A, Vastag G. Biocorrosion-Steel, In: Wandelt K editor. Encyclopedia of Interfacial Chemistry: Surface Science and Electrochemistry; 2018 Feb; Amsterdam, The Netherlands: Elsevier; 2018. pp. 28–42. [CrossRef]
  • [49] Von Wolzogen Kühr CAH, Van Der Vlugt LS. The graphitization of cast iron as an electrochemical process in anaerobic soils. Water 1934;18:147–165.
  • [50] King RA, Miller JD. Corrosion by the sulphate-reducing bacteria. Nature 1971;233:491–492. [CrossRef]
  • [51] Iverson WP, Olson GJ. Anaerobic corrosion by sulfate reducing bacteria due to highly reactive volatile phosphorus compounds. Final report. Available at: https://www.osti.gov/biblio/5175515 Accessed on Mar13, 2024.
  • [52] Beech IB, Cheung, CWS. Interactions of exopolymers produced by sulphate- reducing bacteria with metal ions. Int Biodeter Biodegr 1995;35:59–72. [CrossRef]
  • [53] Enning D, Garrelfs J. Corrosion of iron by sulfate-reducing bacteria: new views of an old problem. Appl Environ Microbiol 2014;80:1226–1236. [CrossRef]
  • [54] Lv M, Du M. A review: microbiologically influenced corrosion and the effect of cathodic polarization on typical bacteria. Rev Environ Sci Biotechnol 2018;17:431–446. [CrossRef]
  • [55] Jia R, Unsal T, Xu D, Lekbach Y, Gu T. Microbiologically influenced corrosion and current mitigation strategies: a state of the art review. Int Biodeter Biodegr 2019;137:42–58. [CrossRef]
  • [56] Tüccar T, Ilhan-Sungur E. Potential Syntrophic Halophilic Partners in Sulfate-Reducing Bacterial Enrichments Derived from Oil Reservoir: Assessment by Sub-culturing Plus Diluting Strategy and Community Analysis. In: Stepec BAA, Wunch K, Skovhus TL, editors. Petroleum Microbiology: The Role of Microorganisms in the Transition to Net Zero Energy. 1st edition. CRC Press Taylor & Francis Group; 2024.
  • [57] Davey ME, Wood WA, Key R, Nakamura K, Stahl DA. Isolation of three species of Geotoga and Petrotoga: Two new genera, representing a new lineage in the bacterial line of descent distantly related to the “Thermotogales”. Syst Appl Microbiol 1993;16:191–200. [CrossRef]
  • [58] Dahle H, Birkeland NK. Thermovirga lienii gen. nov., sp. nov., a novel moderately thermophilic, anaerobic, amino-acid-degrading bacterium isolated from a North Sea oil well. Int J Syst Evol Microbiol 2006;56(Pt 7):1539–1545. [CrossRef]
There are 56 citations in total.

Details

Primary Language English
Subjects Biomaterial
Journal Section Research Articles
Authors

Duygu Arslan

Simge Arkan Özdemir

Nurhan Cansever

Esra Ilhan Sungur

Publication Date April 30, 2024
Submission Date May 29, 2022
Published in Issue Year 2024 Volume: 42 Issue: 2

Cite

Vancouver Arslan D, Arkan Özdemir S, Cansever N, Ilhan Sungur E. Corrosion behavior of N80 tubing steel in the produced water. SIGMA. 2024;42(2):414-2.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK https://eds.yildiz.edu.tr/sigma/