Abstract
Vacancy diffusion is investigated as a mechanism for relaxation of the elastic strain energy caused by a misfitting inclusion. The kinetics of reduction of the total eigenstrain by the deposition or removal of an atom layer along the interface is derived. The time evolution, as well as an estimate for the characteristic time of the relaxation process, is presented. The relaxation times are compared with recent in situ measurements of stress relaxation times in aluminum with small lead-alloy inclusions after their solidification. Experimentally observed relaxation times and those theoretically predicted agree very well.
Acknowledgements
The authors are indebted to the Materials Center Leoben Forschung GmbH and the Austrian Kplus programme for financial support within the strategic project MCL SP16. Work on the project was also partly supported by the Academy of Sciences of the Czech Republic under the Grant 1QS200410502.