Tailoring the Ti-C nanoprecipitate population and microstructure of titanium stabilized austenitic steels

The present work reports on the microstructural evolution of a new heat of 24% cold worked austenitic DIN 1.4970 (15-15Ti) nuclear cladding steel subjected to ageing heat treatments of varying duration between 500 and 800 °C (by steps of 100 °C). The primary aim was studying the finely dispersed Ti-...

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Bibliographic Details
Published in:Journal of nuclear materials 2018-08, Vol.507, p.177-187
Main Authors: Cautaerts, N., Delville, R., Stergar, E., Schryvers, D., Verwerft, M.
Format: Article
Language:English
Subjects:
Aging
Aging (metallurgy)
Austenitic stainless steel
Austenitic stainless steels
Chemical precipitation
Cladding
Coarsening
Cold working
Creep (materials)
Dislocations
Grain boundaries
Heat treatments
Imaging
Imaging techniques
Low temperature
Microstructure
Molybdenum
Nanoparticles
Precipitates
Recrystallization
Size distribution
Stacking faults
Titanium
X-ray diffraction
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Summary:The present work reports on the microstructural evolution of a new heat of 24% cold worked austenitic DIN 1.4970 (15-15Ti) nuclear cladding steel subjected to ageing heat treatments of varying duration between 500 and 800 °C (by steps of 100 °C). The primary aim was studying the finely dispersed Ti-C nanoprecipitate population, which are thought to be beneficial for creep and swelling resistance during service. Their size distribution and number density were estimated through dark field imaging and bright field Moiré imaging techniques in the transmission electron microscope. Nanoprecipitates formed at and above 600 °C, which is a lower temperature than previously reported. The observed nucleation, growth and coarsening behavior of the nanoprecipitates were consistent with simple diffusion arguments. The formation of nanoprecipitates coincided with significant dissociation of dislocations as evidenced by weak beam dark field imaging. Possible mechanisms, including Silcock's stacking fault growth model and Suzuki segregation, are discussed. Recrystallization observed after extended ageing at 800 °C caused the redissolution of nanoprecipitates. Large primary Ti(C,N) and (Ti,Mo)C precipitates that occur in the as-received material, and M23C6 precipitates that nucleate on grain boundaries at low temperatures were also characterized by a selective dissolution procedure involving filtration, X-ray diffraction and quantitative Rietveld refinement. The partitioning of key elements between the different phases was derived by combining these findings and was consistent with thermodynamic considerations and the processing history of the steel. •A new heat of DIN 1.4970 cladding steel was aged and characterized.•Ti-C nanoprecipitate number and size distribution evolution were studied by TEM.•They appeared at lower temperatures (≥600 °C) than previously reported.•Results were explained referring to a solubility product and a diffusion model.•Nanoprecipitate formation coincided with dislocation dissociation.
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2018.04.041