The effects of Methanococcus maripaludis on the corrosion behavior of EH40 steel in seawater.

[1]  R. Conrad Importance of hydrogenotrophic, aceticlastic and methylotrophic methanogenesis for methane production in terrestrial, aquatic and other anoxic environments: A mini review , 2020 .

[2]  Haiya Zhang Electrochemical mechanism of 317L stainless steel under biofilms with coexistence of iron-oxidizing bacteria and sulfate- reducing bacteria , 2019, International Journal of Electrochemical Science.

[3]  L. Carpén,et al.  Corrosion and biofouling tendency of carbon steel in anoxic groundwater containing sulphate reducing bacteria and methanogenic archaea , 2019, Corrosion Science.

[4]  L. Procópio The role of biofilms in the corrosion of steel in marine environments , 2019, World Journal of Microbiology and Biotechnology.

[5]  T. Gu,et al.  Toward a better understanding of microbiologically influenced corrosion caused by sulfate reducing bacteria , 2019, Journal of Materials Science & Technology.

[6]  Jihui Wang,et al.  Effect of Deep Sea Pressures on the Corrosion Behavior of X65 Steel in the Artificial Seawater , 2018, Acta Metallurgica Sinica (English Letters).

[7]  T. Uchiyama,et al.  An extracellular [NiFe] hydrogenase mediating iron corrosion is encoded in a genetically unstable genomic island in Methanococcus maripaludis , 2018, Scientific Reports.

[8]  W. Sand,et al.  Anaerobic microbiologically influenced corrosion mechanisms interpreted using bioenergetics and bioelectrochemistry: A review , 2018, Journal of Materials Science & Technology.

[9]  T. Gu,et al.  Severe microbiologically influenced corrosion of S32654 super austenitic stainless steel by acid producing bacterium Acidithiobacillus caldus SM-1. , 2018, Bioelectrochemistry.

[10]  Yuanyuan Shen The Influence of Low Temperature on the Corrosion of EH40 Steel in a NaCl Solution , 2018, International Journal of Electrochemical Science.

[11]  Y. F. Cheng,et al.  Corrosion of X80 pipeline steel under sulfate-reducing bacterium biofilms in simulated CO2-saturated oilfield produced water with carbon source starvation , 2018 .

[12]  R. Bagheri,et al.  Simulation of the marine environment using bioreactor for investigation of 2507 duplex stainless steel corrosion in the presence of marine isolated Bacillus Vietnamensis bacterium , 2018 .

[13]  O. C. Conlette,et al.  Factors that influence methanogenic activities in a low sulfate oil-producing facility , 2018 .

[14]  N. Tsesmetzis,et al.  Damage to offshore production facilities by corrosive microbial biofilms , 2018, Applied Microbiology and Biotechnology.

[15]  O. Amund,et al.  Microbial community structure of a low sulfate oil producing facility indicate dominance of oil degrading/nitrate reducing bacteria and Methanogens , 2018 .

[16]  Dawei Zhang,et al.  Enhanced resistance of 2205 Cu-bearing duplex stainless steel towards microbiologically influenced corrosion by marine aerobic Pseudomonas aeruginosa biofilms , 2017, Journal of Materials Science & Technology.

[17]  Y. F. Cheng,et al.  The influence of cathodic protection potential on the biofilm formation and corrosion behaviour of an X70 steel pipeline in sulfate reducing bacteria media , 2017 .

[18]  T. Gu,et al.  Electron transfer mediators accelerated the microbiologically influence corrosion against carbon steel by nitrate reducing Pseudomonas aeruginosa biofilm. , 2017, Bioelectrochemistry.

[19]  E. Kuramae,et al.  Methanogens predominate in natural corrosion protective layers on metal sheet piles , 2017, Scientific Reports.

[20]  Y. F. Cheng,et al.  Effect of fluid flow on biofilm formation and microbiologically influenced corrosion of pipelines in oilfield produced water , 2017 .

[21]  P. C. Goh,et al.  Influence of H2S-producing chemical species in culture medium and energy source starvation on carbon steel corrosion caused by methanogens , 2017 .

[22]  O. Samuel,et al.  Substrate Availability, pH, and Temperature Influence Methanogenesis and Mild Steel Corrosion , 2017 .

[23]  Dawei Zhang,et al.  Accelerated corrosion of 2205 duplex stainless steel caused by marine aerobic Pseudomonas aeruginosa biofilm. , 2017, Bioelectrochemistry.

[24]  O. Samuel,et al.  The effects of Tetrakis-hydroxymethyl phosphonium sulfate (THPS), nitrite and sodium chloride on methanogenesis and corrosion rates by methanogen populations of corroded pipelines , 2016 .

[25]  W. Ke,et al.  Effects of Cl− Ions on the Corrosion Behaviour of Low Alloy Steel in Deaerated Bicarbonate Solutions , 2016 .

[26]  S. Maruthamuthu,et al.  Corrosion characteristics of sulfate-reducing bacteria (SRB) and the role of molecular biology in SRB studies: an overview , 2016 .

[27]  Souichiro Kato Microbial extracellular electron transfer and its relevance to iron corrosion , 2016, Microbial biotechnology.

[28]  C. Okoro,et al.  Souring and Corrosion Potentials of Onshore and Offshore Oil-producing Facilities in the Nigerian Oil-rich Niger Delta , 2015 .

[29]  Q. Qu,et al.  Effect of the fungus, Aspergillus niger, on the corrosion behaviour of AZ31B magnesium alloy in artificial seawater , 2015 .

[30]  T. Gu,et al.  Laboratory investigation of the microbiologically influenced corrosion (MIC) resistance of a novel Cu-bearing 2205 duplex stainless steel in the presence of an aerobic marine Pseudomonas aeruginosa biofilm , 2015, Biofouling.

[31]  Dawei Zhang,et al.  Microbially Influenced Corrosion of 304 Stainless Steel and Titanium by P. variotii and A. niger in Humid Atmosphere , 2015, Journal of Materials Engineering and Performance.

[32]  A. Kaksonen,et al.  Marine rust tubercles harbour iron corroding archaea and sulphate reducing bacteria , 2014 .

[33]  D. Enning,et al.  Corrosion of Iron by Sulfate-Reducing Bacteria: New Views of an Old Problem , 2013, Applied and Environmental Microbiology.

[34]  H. Antony,et al.  Electrochemical formation and transformation of corrosion products on carbon steel under cathodic protection in seawater , 2013 .

[35]  Yu Zhang,et al.  Facile synthesis of ultrathin magnetic iron oxide nanoplates by Schikorr reaction , 2013, Nanoscale Research Letters.

[36]  Farzad Mohammadi,et al.  An electrochemical investigation on the effect of the chloride content on CO2 corrosion of API-X100 steel , 2012 .

[37]  S. Harayama,et al.  Iron corrosion activity of anaerobic hydrogen-consuming microorganisms isolated from oil facilities. , 2010, Journal of bioscience and bioengineering.

[38]  T. Uchiyama,et al.  Iron-Corroding Methanogen Isolated from a Crude-Oil Storage Tank , 2010, Applied and Environmental Microbiology.

[39]  Xiaogang Li,et al.  Characterization of corrosion products formed on the surface of carbon steel by Raman spectroscopy , 2009 .

[40]  Martin Stratmann,et al.  Iron corrosion by novel anaerobic microorganisms , 2004, Nature.

[41]  H. Unno,et al.  Structural analysis of a biofilm which enhances carbon steel corrosion in nutritionally poor aquatic environments. , 1999, Journal of bioscience and bioengineering.

[42]  L. Daniels,et al.  Bacterial Methanogenesis and Growth from CO2 with Elemental Iron as the Sole Source of Electrons , 1987, Science.