Abstract
Zirconium alloys are widely used as the cladding material in pressurized-water-reactors. The oxide formed is subjected to compressive stresses, which relax over time. This may affect the protectiveness of the oxide layer by allowing crack formation. We present a mechanistic model to predict these stresses as a function of temperature and oxidation kinetics. Material parameters for elastic deformation, creep, and thermal expansion are taken from appropriate experimental studies and the resulting predictions for the evolution of the stress distributions are compared with other experimental data. Dislocation glide in the oxide is found to be the dominant mechanism of stress relaxation for temperatures below 900 K.
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