Microbiologically influenced corrosion behavior of 70/30 Cu-Ni alloy exposed to carbon starvation environments with different aggressiveness: Pitting mechanism induced by Desulfovibrio vulgaris

[1]  D. Lovley,et al.  Microbially mediated metal corrosion , 2023, Nature Reviews Microbiology.

[2]  Yuan Tian,et al.  Carbon starvation considerably accelerated nickel corrosion by Desulfovibrio vulgaris. , 2023, Bioelectrochemistry.

[3]  V. Sokol,et al.  The effect of Artemisia annua L. extract on microbiologically influenced corrosion of A36 steel caused by Pseudomonas aeruginosa. , 2023, Bioelectrochemistry.

[4]  Towards understanding Shewanella algae-induced degradation of passive film of stainless steel based on electrochemical, XPS and multi-mode AFM analyses , 2023, Corrosion Science.

[5]  Guoan Zhang,et al.  Effect of sulfate reducing bacteria on the galvanic corrosion behavior of X52 carbon steel and 2205 stainless steel bimetallic couple , 2023, Corrosion Science.

[6]  Zhengyun Wang,et al.  “Electrons-siphoning” of sulfate reducing bacteria biofilm induced sharp depletion of Al­Zn­In­Mg­Si sacrificial anode in the galvanic corrosion coupled with carbon steel , 2023, Corrosion Science.

[7]  Y. F. Cheng,et al.  Biogenic H2S and extracellular electron transfer resulted in two-coexisting mechanisms in 90/10 Cu-Ni alloy corrosion by a sulfate-reducing bacteria , 2023, Corrosion Science.

[8]  Yuan Tian,et al.  Enhancement of exogenous riboflavin on microbiologically influenced corrosion of nickel by electroactive Desulfovibrio vulgaris biofilm , 2023, npj Materials Degradation.

[9]  T. Gu,et al.  Effect of alloying element content on anaerobic microbiologically influenced corrosion sensitivity of stainless steels in enriched artificial seawater. , 2023, Bioelectrochemistry.

[10]  D. Macdonald,et al.  Effect of micro-alloying element P on the pitting behavior of copper , 2022, Corrosion Science.

[11]  Yuting Hu,et al.  Microbiologically influenced corrosion of stainless steels by Bacillus subtilis via bidirectional extracellular electron transfer , 2022, Corrosion Science.

[12]  Longjun Xu,et al.  Structural characteristics and chloride intrusion mechanism of passive film , 2022, Corrosion Science.

[13]  W. Wang,et al.  Preparation of dynamic polyurethane networks with UV-triggered photothermal self-healing properties based on hydrogen and ion bonds for antibacterial applications , 2022, Journal of Materials Science & Technology.

[14]  D. Lovley,et al.  Direct microbial electron uptake as a mechanism for stainless steel corrosion in aerobic environments. , 2022, Water research.

[15]  Martín A. Rodríguez,et al.  Pitting corrosion of Ni-Cr-Fe alloys at open circuit potential in chloride plus thiosulfate solutions , 2022, Corrosion Science.

[16]  Tangqing Wu,et al.  Accelerating role of microbial film on soil corrosion of pipeline steel , 2021 .

[17]  W. Ke,et al.  Effect of sulfate-reducing bacteria on corrosion of X80 pipeline steel under disbonded coating in a red soil solution , 2021 .

[18]  Xin Gao Corrosion Behavior of High Strength C71500 Cu-Ni Alloy Pipe in Simulated High Sulfide Polluted Seawater at Different Temperatures , 2021, International Journal of Electrochemical Science.

[19]  T. Gu,et al.  Biocorrosion caused by microbial biofilms is ubiquitous around us , 2020, Microbial biotechnology.

[20]  T. Gu,et al.  Distinguishing two different microbiologically influenced corrosion (MIC) mechanisms using an electron mediator and hydrogen evolution detection , 2020 .

[21]  Dawei Zhang,et al.  Stress-assisted microbiologically influenced corrosion mechanism of 2205 duplex stainless steel caused by sulfate-reducing bacteria , 2020 .

[22]  Dake Xu,et al.  The study of microbiologically influenced corrosion of 2205 duplex stainless steel based on high-resolution characterization , 2020 .

[23]  Dawei Zhang,et al.  Microbiologically influenced corrosion of 304 stainless steel by halophilic archaea Natronorubrum tibetense , 2020, Journal of Materials Science & Technology.

[24]  T. Gu,et al.  Microbiologically influenced corrosion of Cu by nitrate reducing marine bacterium Pseudomonas aeruginosa , 2020, Journal of Materials Science & Technology.

[25]  D. Kong,et al.  Pitting behavior of SLM 316L stainless steel exposed to chloride environments with different aggressiveness: Pitting mechanism induced by gas pores , 2020 .

[26]  T. Gu,et al.  Corrosion of Cu by a sulfate reducing bacterium in anaerobic vials with different headspace volumes. , 2020, Bioelectrochemistry.

[27]  R. A. Antunes,et al.  Galvanic and asymmetry effects on the local electrochemical behavior of the 2098-T351 alloy welded by friction stir welding , 2020 .

[28]  Sviatlana V. Lamaka,et al.  Galvanic corrosion of Ti6Al4V -AA2024 joints in aircraft environment: Modelling and experimental validation , 2019, Corrosion Science.

[29]  E. Han,et al.  Effect of corrosive media on galvanic corrosion of complicated tri-metallic couples of 2024 Al alloy/Q235 mild steel/304 stainless steel , 2019, Journal of Materials Science & Technology.

[30]  T. Gu,et al.  Electrochemical investigation of increased carbon steel corrosion via extracellular electron transfer by a sulfate reducing bacterium under carbon source starvation , 2019, Corrosion Science.

[31]  T. Gu,et al.  Microbiologically influenced corrosion and current mitigation strategies: A state of the art review , 2019, International Biodeterioration & Biodegradation.

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

[33]  T. Gu,et al.  Investigation of the mechanism and characteristics of copper corrosion by sulfate reducing bacteria , 2018, Corrosion Science.

[34]  Fu-hui Wang,et al.  Laboratory investigation of microbiologically influenced corrosion of 2205 duplex stainless steel by marine Pseudomonas aeruginosa biofilm using electrochemical noise , 2018, Corrosion Science.

[35]  Meng Zheng,et al.  The cost of corrosion in China , 2017, npj Materials Degradation.

[36]  C. Man,et al.  Influence of temperature on the electrochemical and passivation behavior of 2507 super duplex stainless steel in simulated desulfurized flue gas condensates , 2017 .

[37]  D. Kong,et al.  Electrochemical investigation and ab initio computation of passive film properties on copper in anaerobic sulphide solutions , 2017 .

[38]  L. Carpén,et al.  Corrosion behaviour of copper under biotic and abiotic conditions in anoxic ground water: electrochemical study , 2016 .

[39]  Cuiwei Du,et al.  Materials science: Share corrosion data , 2015, Nature.

[40]  Song-mei Li,et al.  Effects of applied potential on stable pitting of 304 stainless steel , 2015 .

[41]  W. Ke,et al.  Corrosion product film formed on the 90/10 copper–nickel tube in natural seawater: Composition/structure and formation mechanism , 2015 .

[42]  T. Gu,et al.  Carbon source starvation triggered more aggressive corrosion against carbon steel by the Desulfovibrio vulgaris biofilm , 2014 .

[43]  P. Cristiani,et al.  Effect of protein adsorption on the corrosion behavior of 70Cu-30Ni alloy in artificial seawater. , 2014, Bioelectrochemistry.

[44]  T. Gu,et al.  Laboratory investigation of microbiologically influenced corrosion of C1018 carbon steel by nitrate reducing bacterium Bacillus licheniformis , 2013 .

[45]  A. Heyn,et al.  Environmental factors affecting pitting corrosion of type 304 stainless steel investigated by electrochemical noise measurements under potentiostatic control , 2013 .

[46]  F. Mücklich,et al.  Contact Killing of Bacteria on Copper Is Suppressed if Bacterial-Metal Contact Is Prevented and Is Induced on Iron by Copper Ions , 2013, Applied and Environmental Microbiology.

[47]  Digby D. Macdonald,et al.  The history of the Point Defect Model for the passive state: A brief review of film growth aspects , 2011 .

[48]  Vincent Vivier,et al.  Constant-Phase-Element Behavior Caused by Resistivity Distributions in Films II. Applications , 2010 .

[49]  P. Marcus,et al.  Localized corrosion (pitting): A model of passivity breakdown including the role of the oxide layer nanostructure , 2008 .

[50]  S. Yuan,et al.  Surface characterization and corrosion behavior of 70/30 Cu-Ni alloy in pristine and sulfide-containing simulated seawater , 2007 .

[51]  S. Yuan,et al.  The Influence of the Marine Aerobic Pseudomonas Strain on the Corrosion of 70/30 Cu-Ni Alloy , 2007, ECS Transactions.

[52]  J. Tomasi,et al.  Quantum mechanical continuum solvation models. , 2005, Chemical reviews.

[53]  Norio Yamamoto,et al.  Effect of pitting corrosion on local strength of hold frames of bulk carriers (2nd Report)—Lateral-distortional buckling and local face buckling , 2004 .

[54]  Kwong‐Yu Chan,et al.  Microbiologically Induced Corrosion of 70Cu-30Ni Alloy in Anaerobic Seawater , 2004 .

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

[56]  Kwong‐Yu Chan,et al.  Effects of toxic metals and chemicals on biofilm and biocorrosion. , 2002, Water research.

[57]  J. Wit,et al.  Electrochemical impedance study on the formation of biological iron phosphate layers , 2002 .

[58]  H. Fang,et al.  Phylogenetic diversity of a SRB-rich marine biofilm , 2001, Applied Microbiology and Biotechnology.

[59]  G. Frankel Pitting Corrosion of Metals A Review of the Critical Factors , 1998 .

[60]  Zbigniew Lewandowski,et al.  Role of sulfate‐reducing bacteria in corrosion of mild steel: A review , 1995 .

[61]  B. Little,et al.  The corrosion behavior of copper alloys, stainless steels and titanium in seawater , 1994 .

[62]  P. Marcus,et al.  The role of molybdenum in the dissolution and the passivation of stainless steels with adsorbed sulphur , 1992 .

[63]  D. Westlake,et al.  Distribution of Hydrogenase Genes in Desulfovibrio spp. and Their Use in Identification of Species from the Oil Field Environment , 1990, Applied and environmental microbiology.

[64]  D. Shea,et al.  The solubility of copper in sulfidic waters: Sulfide and polysulfide complexes in equilibrium with covellite , 1988 .

[65]  K. Uosaki,et al.  Effects of the Helmholtz Layer Capacitance on the Potential Distribution at Semiconductor/Electrolyte Interface and the Linearity of the Mott‐Schottky Plot , 1983 .

[66]  J. Miller,et al.  Corrosion by the Sulphate-reducing Bacteria , 1971, Nature.

[67]  T. Gu,et al.  Effects of biogenic H2S on the microbiologically influenced corrosion of C1018 carbon steel by sulfate reducing Desulfovibrio vulgaris biofilm , 2018 .

[68]  J. Scully,et al.  Perspective—Localized Corrosion: Passive Film Breakdown vs Pit Growth Stability , 2017 .

[69]  Tiedo Tinga,et al.  Novel time–frequency characterization of electrochemical noise data in corrosion studies using Hilbert spectra , 2013 .

[70]  M. Zhu,et al.  Corrosion behaviour of nanocrystalline 304 stainless steel prepared by equal channel angular pressing , 2012 .

[71]  Xiaolong Zhu,et al.  Characteristics and formation of corrosion product films of 70Cu–30Ni alloy in seawater , 2002 .

[72]  H. Videla Microbially induced corrosion: an updated overview , 2001 .