Bruit electrique dans les electrolytes 1.1 aqueux - 2. Cas des fortes concentrations - bruit d'interface
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Cited by 6 publications
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The sections in this article are Introduction Experimental Investigation of Corrosion Reactions by Analysis of the Corrosion Products Experimental Investigation of Corrosion Reactions by Following the Chemical Reaction Rate Experimental Investigation of Corrosion Reactions by Following the Rate of the Electrochemical Corrosion Reaction Electrochemical Impedance Spectroscopy and Noise Analysis Introduction The Principle of Dynamic System Analysis Measurement of the Electrochemical Impedance Presentation of Impedance Data Interpretation of Impedance Data The Polarization Resistance Frequency Dispersion Surface Inhomogeneities Single Layer Impedance Model Sandwich Layer Impedance Model Equivalent Circuit Versus Transfer Function The Transport Impedance Iron Corrosion in Neutral Solution Impedance Model of Passive Films Metal Dissolution and Active‐to‐Passive Transition Electrochemical Noise Noise Sources in Electrochemical Systems Noise Measurement Techniques Data Processing Noise Resistance and Polarization Resistance The Scanning Vibrating Electrode Technique Introduction History of Scanning Reference Electrodes Basic Principles of Localized Potential Mapping Localized Electrochemical Impedance Spectroscopy ( LEIS ) Applications of Modern Scanning Electrode Techniques Local Breakdown of Passivity Galvanic Corrosion Inhibition Microbiologically Influenced Corrosion Protective Polymeric Coatings Concluding Remarks Scanning Kelvinprobe Introduction Theory of the Vibrating Condenser Method The Relation between the Volta Potential Difference and Corrosion‐Relevant Properties Electrolyte Covered Metal Surfaces Metals in Humid Air Polymer‐Coated Metals Calibration of the Kelvinprobe Application of the Kelvinprobe: Atmospheric Corrosion Experimental Results Application of the Kelvinprobe: Corrosion Protection by Organic Coatings Experimental Polymer‐Coated Steel Polymer Coated Galvanized Steel Polymer Coated Aluminum Alloys Industrial Coatings Application of the Kelvinprobe: Corrosion Protection by Modified Metal Surfaces Metal Surfaces Modified by Monolayers of Organic Molecules Metal Surfaces Modified by Ultra‐Thin Plasma Polymers Metal Surfaces Modified by Inorganic and Organic Layers
The sections in this article are Introduction Experimental Investigation of Corrosion Reactions by Analysis of the Corrosion Products Experimental Investigation of Corrosion Reactions by Following the Chemical Reaction Rate Experimental Investigation of Corrosion Reactions by Following the Rate of the Electrochemical Corrosion Reaction Electrochemical Impedance Spectroscopy and Noise Analysis Introduction The Principle of Dynamic System Analysis Measurement of the Electrochemical Impedance Presentation of Impedance Data Interpretation of Impedance Data The Polarization Resistance Frequency Dispersion Surface Inhomogeneities Single Layer Impedance Model Sandwich Layer Impedance Model Equivalent Circuit Versus Transfer Function The Transport Impedance Iron Corrosion in Neutral Solution Impedance Model of Passive Films Metal Dissolution and Active‐to‐Passive Transition Electrochemical Noise Noise Sources in Electrochemical Systems Noise Measurement Techniques Data Processing Noise Resistance and Polarization Resistance The Scanning Vibrating Electrode Technique Introduction History of Scanning Reference Electrodes Basic Principles of Localized Potential Mapping Localized Electrochemical Impedance Spectroscopy ( LEIS ) Applications of Modern Scanning Electrode Techniques Local Breakdown of Passivity Galvanic Corrosion Inhibition Microbiologically Influenced Corrosion Protective Polymeric Coatings Concluding Remarks Scanning Kelvinprobe Introduction Theory of the Vibrating Condenser Method The Relation between the Volta Potential Difference and Corrosion‐Relevant Properties Electrolyte Covered Metal Surfaces Metals in Humid Air Polymer‐Coated Metals Calibration of the Kelvinprobe Application of the Kelvinprobe: Atmospheric Corrosion Experimental Results Application of the Kelvinprobe: Corrosion Protection by Organic Coatings Experimental Polymer‐Coated Steel Polymer Coated Galvanized Steel Polymer Coated Aluminum Alloys Industrial Coatings Application of the Kelvinprobe: Corrosion Protection by Modified Metal Surfaces Metal Surfaces Modified by Monolayers of Organic Molecules Metal Surfaces Modified by Ultra‐Thin Plasma Polymers Metal Surfaces Modified by Inorganic and Organic Layers
Voraussetzung fur einen optimalen Werkstoffeinsatz in der Technik ist die Kenntnis des dynamischen Korrosionsverhaltens des Systems. Im ersten Teil dieser Arbeit werden die Grundlagen der dynamischen Systemanalyse und ihre charakteristischen KenngroRen dargestellt. Die verschiedenen Mefirnethoden und prinzipielle Probleme bei der Interpretation der McBergcbnissc werden diskutiert. Im zweitcn Teil werden fur einfache Korrosionssysteme verschiedene Auswerteverfahren behandelt. Im dritten Ted werden charakteristische experimentelle Ergebnisse fur verschiedene Korrosionsinhibitoren und beschichtete Metalle, die von Bedeutung fur Korrosionsuntersuchungen in Forschung und Praxis sind, vorgestellt.For an optimal selection of structural materials in practical applications it is important to obtain a detailed knowledge of the dynamic corrosion behaviour of the system. The background of the dynamic system analysis and its parameters are derived in the first part of this paper. The different experimental procedures and principal problems in thc intcrpreta'tion of experimental results are discussed. In the second part different methods of analysis of impedance data are described for simple corrosion systems. Characteristic results for various corrosion inhibitors and coated metals during exposure to corrosive environments which are of importance for basic research as well as for practical applications are discussed in the third part.
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