Title:
Holographical Microwave Imaging of Corroded Steel Bars in Concrete
Author(s):
Mohammad T. Ghasr, Yann Le Pape, David B. Scott, and Reza Zoughi
Publication:
Materials Journal
Volume:
112
Issue:
1
Appears on pages(s):
115-124
Keywords:
concrete; corrosion; nondestructive evaluation; reinforcing steel; three-dimensional microwave imaging
DOI:
10.14359/51686981
Date:
1/1/2015
Abstract:
Corrosion assessment of embedded steel in concrete structures is generally performed by electrochemical methods that are not fully nondestructive because the device requires connection to the steel. For practical applications, the development of a truly nondestructive technique for the detection of corrosion is desirable. This paper presents an experimental study of a wideband microwave three-dimensional synthetic aperture radar imaging technique applied to reinforced concrete specimens subjected to corrosion. Two orthogonal wave polarization directions were used for this purpose. Two-dimensional microwave image slices were analyzed and compared with the actual loss of steel measured during the destructive testing. As expected, the results indicated that higher-frequency images have higher spatial resolution, while the signal penetration became more limited at these frequencies.
Though the relatively high moisture content significantly increased the dissipative properties against electromagnetic propagation, the technique was capable of differentiating between corroded and non-corroded steel bars.
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