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Microstructural and micro-mechanical analysis of 14YWT nanostructured Ferritic alloy after varying thermo-mechanical processing paths into tubing

Microstructural analyses and micro-pillar compression were conducted on 14YWT nanostructured ferritic alloy (NFA) to compare different processing pathways: hydrostatic extrusion and Pilger processing with varying annealing temperatures into thin walled tubing, and after hot extrusion and cross-rolli...

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Published in:Materials characterization 2021-01, Vol.171, p.110744, Article 110744
Main Authors: Harvey, Cayla, El Atwani, Osman, Kim, Hyosim, Lavender, Curt, McCoy, Marie, Sornin, Denis, Lewandowski, John, Maloy, Stuart A., Pathak, Siddhartha
Format: Article
Language:English
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Summary:Microstructural analyses and micro-pillar compression were conducted on 14YWT nanostructured ferritic alloy (NFA) to compare different processing pathways: hydrostatic extrusion and Pilger processing with varying annealing temperatures into thin walled tubing, and after hot extrusion and cross-rolling into a plate. Hydrostatic extrusion at 815 °C resulted in the smallest grain sizes and highest yield strength of 1.20 GPa. Pilger processing with annealing at 800 °C had fine grained regions and bands of coarse grains, leading to a large variation in yield strength of 0.9–1.40 GPa. Higher annealing temperatures of 1200 °C after pilger processing significantly increased the grain size and lowered the yield strength to 1.01 GPa. These tubes showed a stronger 〈111〉 crystallographic texture in the normal direction and elongated grains in the extrusion direction. Characterization of the nano-oxides using TEM reveals more numerous, smaller oxides present in tubing processed at lower temperatures. This work shows NFA tubing after hydrostatic extrusion and pilger processing can lead to fine grained microstructures and texturing leading to higher yield strengths at lower annealing temperatures (e.g. 800 °C). •Hydrostatic extrusion at 815 °C resulted in the smallest grain sizes and highest yield strength•Pilger processing with annealing at 800 °C has fine and coarse grain regions, creating a larger variation in yield strength•Higher annealing temperatures of 1200 °C significantly increased the grain size and lowered the yield strength•Nano-oxides are more numerous, smaller oxides present in tubing processed at lower temperatures
ISSN:1044-5803
1873-4189
DOI:10.1016/j.matchar.2020.110744