A model to estimate moisture distribution in porous oxides as a function of atmospheric conditions
Author(s)
Sherwood, D
Reddy, Mekala V
Cole, Ivan
Emmanuel, Bosco
Griffith University Author(s)
Year published
2014
Metadata
Show full item recordAbstract
An approach is presented for estimating the retention of moisture and its distribution within porous bodies or layers. Corrosion will only occur if moisture above the oxide layer can be connected to the metal/oxide surface. Such local levels of connected moisture and global levels of connected moisture were computed using Monte Carlo simulation as a function of depth in the porous body for several values of percolation parameter P which in turn depends on relative humidity (RH) and temperature (T). The time that an oxide on a metal surface holds connected moisture paths is compared to times that a smooth surface will retain ...
View more >An approach is presented for estimating the retention of moisture and its distribution within porous bodies or layers. Corrosion will only occur if moisture above the oxide layer can be connected to the metal/oxide surface. Such local levels of connected moisture and global levels of connected moisture were computed using Monte Carlo simulation as a function of depth in the porous body for several values of percolation parameter P which in turn depends on relative humidity (RH) and temperature (T). The time that an oxide on a metal surface holds connected moisture paths is compared to times that a smooth surface will retain moisture films. The implications for corrosion are discussed.
View less >
View more >An approach is presented for estimating the retention of moisture and its distribution within porous bodies or layers. Corrosion will only occur if moisture above the oxide layer can be connected to the metal/oxide surface. Such local levels of connected moisture and global levels of connected moisture were computed using Monte Carlo simulation as a function of depth in the porous body for several values of percolation parameter P which in turn depends on relative humidity (RH) and temperature (T). The time that an oxide on a metal surface holds connected moisture paths is compared to times that a smooth surface will retain moisture films. The implications for corrosion are discussed.
View less >
Journal Title
Journal of Electroanalytical Chemistry
Volume
725
Subject
Analytical chemistry
Analytical chemistry not elsewhere classified
Macromolecular and materials chemistry
Theoretical and computational chemistry