Design and Application of a New Cell for in Situ Infrared Reflection–Absorption Spectroscopy Investigations of Metal–Atmosphere Interfaces

Design and Application of a New Cell for in Situ Infrared Reflection–Absorption Spectroscopy Investigations of Metal–Atmosphere Interfaces

A new experimental setup for studying reactions occurring in the metal–atmosphere interface by applying in situ infrared reflection–absorption spectroscopy (IRRAS) is presented. It consists of a gas-mixing unit, where the moist air is generated with or without corrosive gases, the reaction cell for...

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Veröffentlicht in:Applied spectroscopy 2003-01, Vol.57 (1), p.88-92
Hauptverfasser: Kleber, CH, Kattner, J., Frank, J., Hoffmann, H., Kraft, M., Schreiner, M.
Format: Artikel
Sprache:eng
Schlagworte:
Atmosphere - chemistry
Atmosphere Exposure Chambers
Copper - chemistry
Corrosion
Equipment Design
Equipment Failure Analysis
Feasibility Studies
Humidity
Metals - chemistry
Microscopy, Atomic Force
Spectrophotometry, Infrared - instrumentation
Spectrophotometry, Infrared - methods
Surface Properties
Water - chemistry
Weather
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Zusammenfassung:A new experimental setup for studying reactions occurring in the metal–atmosphere interface by applying in situ infrared reflection–absorption spectroscopy (IRRAS) is presented. It consists of a gas-mixing unit, where the moist air is generated with or without corrosive gases, the reaction cell for the in situ investigations, and an optical system coupled with a Fourier transform infrared (FT-IR) spectrometer. For testing the unit, a specimen of pure copper was used, where the growth of Cu2O on the polished surface could be observed during time-resolved measurements in synthetic air containing 80% RH (relative humidity). For comparison of the experimental results obtained, a computer simulation program was developed in order to calculate the peak position, the peak height, the peak width, and the thickness of the surface layer formed during the atmospheric corrosion. The simulation software is based on the four-phase model of covered surfaces.
ISSN:0003-7028
1943-3530
DOI:10.1366/000370203321165250