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Abstract
An ultra-low carbon austenitic stainless steel was successfully pressed from one to eight passes by equal channel angular pressing (ECAP) at room temperature. By using X-ray diffraction, optical microscopy and transmission electron microscopy, the microstructural evolution during ECAP was investigated to reveal the formation mechanism of strain-induced nanostructures. The refinement mechanism involved the formation of shear bands and deformation twins, followed by the fragmentation of twin lamellae, as well as successive martensite transformation from parent austenitic grains with sizes ranging from microns to nanometres through the processes γ(fcc) → ε(hcp) → α′(bcc). After pressing for eight passes, two types of nanocrystalline grains were achieved: (a) nanocrystalline austenite with a mean grain size of ∼31 nm and (b) strain-induced nanocrystalline α′-martensite with a size of ∼74 nm. The formation mechanisms are discussed in terms of microstructural subdivision via deformation twinning and martensite transformation.
Acknowledgements
This research was financially supported by the National Natural Sciences Foundation of China (NSFC) under grant Nos. 50701047, 50371090 and 50471082. Zhang ZF would like to thank the financial support of “Hundred of Talents Project” by the Chinese Academy of Sciences, and the National Outstanding Young Scientist Foundation under grant No. 50625103.
