Top

Published in:

2017 | OriginalPaper | Chapter

8. Examples of Some Materials Vulnerable to MIC

Author : Reza Javaherdashti

Published in: Microbiologically Influenced Corrosion

Publisher: Springer International Publishing

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

While almost all engineering materials are susceptible to MIC. there are three engineering materials that in this chapter we want to study their MIC behaviour and susceptibility with more details. There are three reasons for that: either these materials have a reputation to be toxic to micro-organisms and thus MIC-proof, or that due to their alloying elements are resistant to corrosion and thus MIC or they are considered to have a rather straightforward MIC mechanism (s). In this chapter we will see why these are not true!

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Examples of Some Systems Vulnerable to MIC

next chapter How Is MIC Treated?

Yakubi A, Murakami M (2007) Critical ion concentration for pitting and general corrosion of copper . Corrosion 63(3):249–257, March 2007.

Burns RM, Bradley WW (1967) Protective coatings for metals, 3rd edn. American Chemical Society, Monograph Series.

See, for example, reviews by Schleich W, Steinkamp K (2003) Biofouling resistance of cupronickel-basics and experience. Paper No. P0379, Stainless steel world. Maastricht, The Netherlands, 2003 and also Schleich W (2004) Typical failures of CuNi 90/10 seawater tubing systems and how to avoid them. Paper No. 12-0-124, EuroCorr 2004, Nice 2004. Also, Powell C, Michels H (2004) Review of splash zone corrosion and biofouling of C70600 sheathed steel during 20 years exposure. EuroCorr 2006, Event No. 280, 24–28 September 2006, Maastricht, The Netherlands.

Parvizi MS, Aladjem A, Castle JE (1988) Behaviour of 90–10 cupronickel in sea water. Int Mater Rev 33(4):169–200.

Palanichamy S, Maruthamuthu S, Manickam ST, Rajendran A (2002) Microfouling of manganese-oxidising bacteria in tuticorin harbour waters. Curr Sci 82(7):865–869.

Critchley M, Taylor R, O^’Halloran R (2005) Microbial contribution to blue water corrosion. Mater Perform (MP) 44(6):56–59.

Webster BJ, Werner SE, Wells DB, Bremer PJ (2000) Microbiologically influenced corrosion of copper in potable water systems-pH effects. CORROSION 56(9):942–950.

Biofilms are negatively charged.

Shalaby HM, Hasan AA, Al-Sabti F (1999) Effects of inorganic sulphide and ammonia on microbial corrosion behaviour of 70Cu-30Ni alloy in sea water. British Corrosion J 34(4):292–298.

Lee JS, Ray RI, Little BJ (2003) A comparison of biotic and inorganic sulphide films on alloy 400. In: Proceedings of corrosion science in the twenty-first Century, vol 6. Paper C057, UMIST, UK.

de Romero M, Duque Z, de Rincon O, Perez O, Araujo I, Martinez A (2000) Online monitoring systems of microbiologically influenced corrosion on Cu-10 %Ni Alloy in chlorinated, brackish water. CORROSION, 56(8):867–876.

Chaves R, Costa I, de Melo HG, Wolynec S (2006) Evaluation of selective corrosion in UNS S31803 duplex stainless steel with electrochemical impedance spectroscopy. Electrochimica Acta 51:1842–1846.

Rhodes RR, Skogsberg LA, Tuttle RN (2007) Pushing the limits of metals in corrosive oil and gas well environments. CORROSION 63(1):63–100.

Archer ED, Brook R, Edyvean RGJ, Videla H (2001) Selection of steels for use in SRB environments. Paper No. 01261, CORROSION-2001, NACE International, USA.

Siow KS, Song TY, Qiu JH (2001) Pitting corrosion of duplex stainless steels. Anti-Corros Meth Mater 48(1):31–36.

Stainless Steel Selection Guide Central States Industrial Equipment & Service, Inc., http://www.al6xn.com/litreq.htm, USA.

Gunn RN (1997) Duplex stainless steels, Chap 7. Woodhead Publishing Ltd.

Danko JC, Lundin CD (1995) The effect of microstructure on microbially influenced corrosion. In: Proceedings of international conference on microbiologically influenced corrosion, New Orleans, Louisiana, NACE international, USA, May 8–10 1995.

Kovach CW, Redmond JD (1997) High-performance stainless steels and microbiologically influenced corrosion . www.avestasheffield.com, acom 1-1997.

Neville A, Hodgkiess T (1998) Comparative study of stainless steel and related alloy corrosion in natural sea water. British Corros J 33(2):111–119.

Johnsen R, Bardal E (1985) Cathodic properties of different stainless steels in natural seawater. CORROSION 41(5):296–302.

Antony PJ, Chongdar S, Kumar P, Raman R (2007) Corrosion of 2205 duplex stainless steel in chloride medium containing sulphate-reducing bacteria. Electrochimica Acta 52:3985–3994.

Rogers RD, Knight JJ, Cheeseman CR, Wolfram JH, Idachaba M, Nyavor K, Egiebor NO (2003) Development of test methods for assessing microbial influenced degradation of cement-solidified radioactive and industrial waste. Cement Concrete Res 33:2069–2076.

Corrosion, and thus MIC, is used to address degradation in metals. We will use the term “microbial influenced degradation, or briefly MID, to address degradation of non-metallics.

Scott PJB, Davies M (1992) Microbiologically influenced corrosion. Civil Eng 62:58–59.

Davies M, Scott PJB (1996) Remedial treatment of an occupied building affected by microbiologically influenced corrosion. Mater Perform (MP), 35(6):54–57.

Little BJ, Ray RI, Pope RK (2000) Relationship between corrosion and the biological sulphur cycle: a review. CORROSION 56(4):433–443.

Knight J, Cheeseman C, Rogers R (2002) Microbial influenced degradation of solidified waste binder. Waste Manag 22:187–193.

Roberts DJ, Nica D, Zuo G, Davis JL (2002) Quantifying microbially induced deterioration of concrete : initial studies. Int Biodeter Biodeg 49:227–234.

Davies JL, Nica D, Shields K, Roberts DJ (1998) Analysis of concrete from corroded sewer pipe. Int Biodeg Biodeg 42:75–84.

Monteny JE, Vincke A, Beeldens N, De Belie L, Taerwe D, Van Gemert W, Verstraete (2000) Chemical, microbiological, and in situ test methods for biogenic sulfuric acid corrosion of concrete . Cement Concrete Res 30:623–634.

Mori T, Nonaka T, Tazaki K, Koga M, Hikosaka Y, Noda S (1992) Interactions of nutrients, moisture and pH on microbial corroson of concrete sewer pips. Water Res 26(1):29–37.

Ribas Silva M, Pinheiro SMM (2007) Mitigation of concrete structures submitted to biodeterioration. In: MIC-An International Perspective Symposium, Extrin Corrosion Consultants-Curtin University, Perth-Australia, 14–15 February 2007.

Antony PJ, Chongdar S, Kumar P, Raman R (2007) Corrosion of 2205 duplex stainless steel in chloride medium containing sulfate-reducing bacteria. Electrochim Acta 52:3985–3994CrossRef

Archer ED, Brook R, Edyvean RGJ, Videla H (2001) Selection of steels for use in SRB environments. Paper No.01261, CORROSION-2001, NACE International, USA, 2001

Burns RM, Bradley WW (1967) Protective coatings for metals, 3rd edn. Am Chem Soc, Monograph Series

Chaves R, Costa I, de Melo HG, Wolynec S (2006) Evaluation of selective corrosion in UNS S31803 duplex stainless steel with electrochemical impedance spectroscopy. Electrochim Acta 51:1842–1846CrossRef

Critchley M, Taylor R, O’Halloran R (2005) Microbial contribution to blue water corrosion. Mater Perform (MP) 44(6):56–59

Davies M, Scott PJB (1996) Remedial treatment of an occupied building affected by microbiologically-influenced corrosion. Mater Perform (MP) 35(6):54–57

de Romero M, Duque Z, de Rincon O, Perez O, Araujo I, Martinez A (2000) Online monitoring systems of microbiologically influenced corrosion on Cu-10 %Ni alloy in chlorinated, brackish water. CORROSION 56(8):867–876CrossRef

Gunn RN (1997) Duplex stainless steels, Chap 7. Woodhead Publishing Ltd

Javaherdashti R (2004) A review of microbiologically influenced corrosion with emphasis on concrete structures. In: Proceedings of corrosion and prevention 2004 (CAP04), 21–24 November 2004, Perth, Australia

Johnsen R, Bardal E (1985) Cathodic properties of different stainless steels in natural seawater. CORROSION 41(5):296–302CrossRef

Knight J, Cheeseman C, Rogers R (2002) Microbial influenced degradation of solidified waste binder. Waste Manag 22:187–193CrossRef

Kovach CW, Redmond JD (1997) High performance stainless steels and microbiologically influenced corrosion. www.avestasheffield.com, acom 1-1997

Lee JS, Ray RI, Little BJ (2003) A comparison of biotic and inorganic sulphide films on alloy 400. In: Proceedings of corrosion science in the 21st century, vol 6. Paper C057, UMIST, UK, July 2003

Little BJ, Ray RI, Pope RK (2000) Relationship between corrosion and the biological sulfur cycle: a review. CORROSION 56(4):433–443CrossRef

Neville A, Hodgkiess T (1998) Comparative study of stainless steel in natural sea water. Br Corros J 33(2):111–119CrossRef

Palanichamy S, Maruthamuthu S, Manickam ST, Rajendran A (2002) Microfouling of manganese-oxidizing bacteria in tuticorin harbour waters. Curr Sci 82(7), 865–869

Parvizi MS, Aladjem A, Castle JE (1988) Behaviour of 90-10 cupronickel in sea water. Int Mater Rev 33(4):169–200CrossRef

Roberts DJ, Nica D, Zuo G, Davis JL (2002) Quantifying microbially induced deterioration of concrete: initial studies. Int Biodeter Biodeg 49:227–234CrossRef

Rhodes RR, Skogsberg LA, Tuttle RN (2007) Pushing the limits of metals in corrosive oil and gas well environments. CORROSION 63(1):63–100CrossRef

Ribas Silva M, Pinheiro SMM (2007) Mitigation of concrete structures submitted to biodeterioration. In: MIC-An International Perspective symposium, Extrin Corrosion Consultants-Curtin University, Perth-Australia, 14–15 Feb 2007

Scott PJB, Davies M (1992) Microbiologically-influenced corrosion. Civ Eng 62:58–59

Shalaby HM, Hasan AA, Al-Sabti F (1999) Effects of inorganic sulphide and ammonia on microbial corrosion behaviour of 70Cu-30Ni alloy in sea water. Br Corros J 34(4):292–298CrossRef

Siow KS, Song TY, Qiu JH (2001) Pitting corrosion of duplex stainless steels. Anti-Corros Meth Mater 48(1):31–36CrossRef

Webster BJ, Werner SE, Wells DB, Bremer PJ (2000) Microbiologically influenced corrosion in potable water systems-pH effects. CORROSION 56(9):942–950CrossRef

Yakubi A, Murakami M (2007) Critical Ion concentration for pitting and general corrosion. CORROSION 63(3):249–257CrossRef

Title: Examples of Some Materials Vulnerable to MIC
Author: Reza Javaherdashti
Publisher: Springer International Publishing
Book: Microbiologically Influenced Corrosion
Print ISBN: 978-3-319-44304-1

Electronic ISBN: 978-3-319-44306-5

Copyright Year: 2017
DOI: https://doi.org/10.1007/978-3-319-44306-5_8

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Premium Partners