Abstract. Microbial biofilms produce electrochemical interactions with metal surfaces by following a wide variety of different electron exchange pathways. Reviewing the mechanisms identified in the biocorrosion of steels leads us to distinguish direct and indirect mechanisms for biofilm-catalysed cathodic reactions. Indirect mechanisms are due to the production of metal oxides or hydrogen peroxide (aerobic corrosion) or metal sulphides (anaerobic corrosion), which further react with the metal surface. Direct mechanisms involve adsorbed biocompounds, generally enzymes or their active sites, which catalyse the cathodic reduction of oxygen for aerobic biocorrosion or the proton/water reduction in anaerobic processes. Recent studies dealing wit...
This review illuminates extracellular electron transfer mechanisms that may be involved in microbial...
The anaerobic corrosion of iron structures is expensive to repair and can be a safety and environmen...
A bioelectrochemical system (BES) exploits biological catalysts for anode and/or cathode reactions, ...
Microbial biofilms produce electrochemical interactions with metal surfaces by following a wide vari...
International audienceWhereas corrosion of metallic materials by bacteria is a process dreaded by me...
Geobacteraceae are the most widespread microorganisms in soils and sediments in which microbial redu...
Biocorrosion processes at metal surfaces are associated with microorganisms, or the products of thei...
In the recent years, considerable body of research has been carried out in the field of bioelectroch...
Microbiologically influenced corrosion of metals is prevalent in both natural and industrial environ...
It has recently been discovered that many microbial species have the capacity to connect their metab...
The study of electromicrobiology has grown into its own field over the last decades and involves mic...
Microbially catalyzed corrosion of metals is a substantial economic concern. Aerobic microbes primar...
Up to date a few electroactive bacteria embedded in biofilms are described to catalyze both anodic a...
The attachment and biofilm formation by bacteria on surfaces are of interest due to its potential in...
Shewanella oneidensis MR-1 is an attractive model microbe for elucidating the biofilm-metal interact...
This review illuminates extracellular electron transfer mechanisms that may be involved in microbial...
The anaerobic corrosion of iron structures is expensive to repair and can be a safety and environmen...
A bioelectrochemical system (BES) exploits biological catalysts for anode and/or cathode reactions, ...
Microbial biofilms produce electrochemical interactions with metal surfaces by following a wide vari...
International audienceWhereas corrosion of metallic materials by bacteria is a process dreaded by me...
Geobacteraceae are the most widespread microorganisms in soils and sediments in which microbial redu...
Biocorrosion processes at metal surfaces are associated with microorganisms, or the products of thei...
In the recent years, considerable body of research has been carried out in the field of bioelectroch...
Microbiologically influenced corrosion of metals is prevalent in both natural and industrial environ...
It has recently been discovered that many microbial species have the capacity to connect their metab...
The study of electromicrobiology has grown into its own field over the last decades and involves mic...
Microbially catalyzed corrosion of metals is a substantial economic concern. Aerobic microbes primar...
Up to date a few electroactive bacteria embedded in biofilms are described to catalyze both anodic a...
The attachment and biofilm formation by bacteria on surfaces are of interest due to its potential in...
Shewanella oneidensis MR-1 is an attractive model microbe for elucidating the biofilm-metal interact...
This review illuminates extracellular electron transfer mechanisms that may be involved in microbial...
The anaerobic corrosion of iron structures is expensive to repair and can be a safety and environmen...
A bioelectrochemical system (BES) exploits biological catalysts for anode and/or cathode reactions, ...