Effect of solute concentration on microstructure evolution during static recrystallization in Mg-0.2%Ce alloy using cellular automata

Effect of solute concentration on microstructure evolution during static recrystallization in Mg-0.2%Ce alloy using cellular automata

A new cellular automata model has been developed to evaluate the effect of solute drag on the microstructure and texture evolution during static recrystallization of Mg and its alloys in the temperature range of 200 – 400 °C. In the present model, the site saturation nucleation was assumed and all t...

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Bibliographic Details
Published in:Materials today communications Vol. 37; p. 107503
Main Authors: Kushwaha, Rajan, Muhammad, W., Ali, U., Sahoo, S.K., Sabat, Rama K.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-12-2023
Subjects:
Dislocation density
Ex-situ EBSD
Mobility
Solute drag
Static recrystallization
Dislocation density
Mobility
Ex-situ EBSD
Solute drag
Static recrystallization
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Summary:A new cellular automata model has been developed to evaluate the effect of solute drag on the microstructure and texture evolution during static recrystallization of Mg and its alloys in the temperature range of 200 – 400 °C. In the present model, the site saturation nucleation was assumed and all the nuclei are present at the grain boundaries. The growth of each nucleus depends on the solute concentration and dislocation density difference between neighboring grains. The microstructural analysis of the newly developed cellular automata model showed the evolution of grain size at different temperatures compared to the equilibrium microstructure containing the equilibrium concentration of solute atoms at the grain boundaries. Further, the texture evolution showed that there is an increase in the texture strength with an increase in the annealing temperature when the solute concentration was lower than the equilibrium concentration at the boundaries, whereas the texture strength decreased with increasing the annealing temperature when the solute concentration was higher than the equilibrium solute concentration at the boundaries. The present model shows that solute drag pressure increased continuously with increasing the annealing temperature when the solute concentration was lower than the equilibrium concentration at the boundaries. However, the solute drag pressure decreased with an increase in the annealing temperature when the solute concentration was higher than the equilibrium solute concentration at the boundaries. [Display omitted] •Grain size distribution changes with respect to the solute concentration.•Change in the shape of grain size distribution.•Change in the texture strength and solute drag pressure during annealing.
ISSN:2352-4928
2352-4928
DOI:10.1016/j.mtcomm.2023.107503