(320d) 20 Years of Corrosion Sensing and Microvisualization of Corrosion Processes
AIChE Annual Meeting
2017
2017 Annual Meeting
Engineering Sciences and Fundamentals
Tutorial Session on Electrochemical Methods, Systems and Applications (Invited Talks)
Tuesday, October 31, 2017 - 8:00am to 8:35am
The objectives of the experimental techniques are: (1) to measure the local corrosion rate; (2) to locate breakdown sites, and; (3) to study the fundamental properties of passive films and how they are related to the stability of the films and damaging environments. The latter is of particular interest since it will allow one to predict why a particular precursor site is more vulnerable to breakdown as compared to neighboring areas.
In locating precursor sites, entire regions of the corroding surface can be imaged concurrently or point-by-point using a scanned probe or beam. Both classes will be discussed with their capabilities. The techniques used in our laboratory are: (1) the Quartz Crystal Microbalance (QCM); (2) Optical Fiber Micromirrors (FOP); (3) Confocal Laser Scanning Microscopy (CLSM); (4) Photoelectrochemical Microscopy (PEM); (5) Scanning Electrochemical Microscopy (SECM); (6) Scanning Photoelectrochemical and Electrochemical Microscopy (SPECM); (7) Near Field Scanning Optical and Spectroscopic Microscopy (NSOSM). The experimental setup for each and their capability help to reveal the advantages that are offered by them.
Optical sensing by the QCM and optical fiber micromirrors have been used to measure corrosion rates, with sensitivity of fractions of an atomic layer. Similar to them but with the capability to image a larger reactive surface is the CLSM to determine local attack rates at various surface sites. The NSOSM is valuable to obtain both vertical and lateral super resolution images of reacting surfaces of about 60 nanometers. The techniques support the development of miniature corrosion sensors devoted to monitoring reactive surfaces in remote and occluded regions, coupled with wireless transmission. The wireless corrosion sensors must be (1) small, (2) inexpensive, (3) tailored to evaluate corrosion rates, and (4) robust.