Atomic-scale mechanisms of deformation-induced cementite decomposition in pearlite

Pearlitic steel can exhibit tensile strengths higher than 5 GPa after severe plastic deformation, where the deformation promotes a refinement of the lamellar structure and cementite decomposition. However, a convincing correlation between deformation and cementite decomposition in pearlite is still...

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Bibliographic Details
Published in:Acta materialia 2011-06, Vol.59 (10), p.3965-3977
Main Authors: Li, Y.J., Choi, P., Borchers, C., Westerkamp, S., Goto, S., Raabe, D., Kirchheim, R.
Format: Article
Language:English
Subjects:
Atom probe tomography
Carbon
Cementite
Cementite decomposition
Cold-drawn pearlitic steel wire
Correlation
Decomposition
Dislocations
Ferrite
Grain boundaries
Microstructure
Pearlite
Strain
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Summary:Pearlitic steel can exhibit tensile strengths higher than 5 GPa after severe plastic deformation, where the deformation promotes a refinement of the lamellar structure and cementite decomposition. However, a convincing correlation between deformation and cementite decomposition in pearlite is still absent. In the present work, a local electrode atom probe was used to characterize the microstructural evolution of pearlitic steel, cold-drawn with progressive strains up to 5.4. Transmission electron microscopy was also employed to perform complementary analyses of the microstructure. Both methods yielded consistent results. The overall carbon content in the detected volumes as well as the carbon concentrations in ferrite and cementite were measured by atom probe. In addition, the thickness of the cementite filaments was determined. In ferrite, we found a correlation of carbon concentration with the strain, and in cementite, we found a correlation of carbon concentration with the lamella thickness. Direct evidence for the formation of cell/subgrain boundaries in ferrite and segregation of carbon atoms at these defects was found. Based on these findings, the mechanisms of cementite decomposition are discussed in terms of carbon–dislocation interaction.
ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2011.03.022