Data for: Evolution of substructure in low-interstitial martensitic stainless steel during tempering

Published: 16 April 2020| Version 1 | DOI: 10.17632/b86py6xcs8.1
Frank Niessen,


The evolution of the substructure and the distribution of interstitial elements in lath martensite during tempering in soft martensitic stainless steel X4CrNiMo16-5-1 was studied with line profile analysis of diffractograms from energy dispersive synchrotron X-ray diffraction, local chemical analysis with atom probe tomography and orientation mapping with electron backscatter and transmission Kikuchi diffraction. Martensite formation occurred below 135 °C without auto-tempering and led to a dislocation density in martensite of 3.8∙10^15 m^(-2), as determined from X-ray line profile analysis. On tempering carbon and nitrogen segregated to low-angle and high-angle grain boundaries. Recovery commenced above 550 °C and led to a reduction in dislocation density to a steady value of 4∙10^14 m^(-2) at 600 to 750 °C. Further tempering led to a second increase in dislocation density at room temperature, owing to the transformation of reverted austenite, formed above 650 °C, into martensite, on cooling. It was observed that the recovery of martensite competes with the formation of reverted austenite. The interpretation of the coherently diffracting domain size obtained from X-ray line profile analysis was critically discussed in the context of the internal structure in martensite.



Danmarks Tekniske Universitet


Metallurgy, Materials Characterization, Electron Backscatter Diffraction, Synchrotron X-Ray Diffraction, Atom Probe, Martensite, Martensitic Stainless Steel