Acta Metallurgica Sinica (English Letters) ›› 2023, Vol. 36 ›› Issue (7): 1105-1112.DOI: 10.1007/s40195-022-01426-2
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Dayong An1(), Yuhao Zhou2, Yao Xiao2, Xinxi Liu1, Xifeng Li1, Jun Chen1
Received:
2022-03-08
Revised:
2022-04-22
Accepted:
2022-04-24
Online:
2023-07-10
Published:
2023-06-06
Contact:
Dayong An
Dayong An, Yuhao Zhou, Yao Xiao, Xinxi Liu, Xifeng Li, Jun Chen. Observation of the Hydrogen-Dislocation Interactions in a High-Manganese Steel after Hydrogen Adsorption and Desorption[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(7): 1105-1112.
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Fig. 1 Illustration of experimental procedures: a1-a3 schematic of hydrogen adsorption and desorption processes, b electrochemical hydrogen charging set-up, c thermal desorption rate curves showing the diffusible hydrogen contents for samples under different conditions, d BSD and EBSD overviews of the deformation region of interest. BSD: backscattered diffraction. EBSD: electron backscattered diffraction
Fig. 2 ECC images displaying the dislocation configurations: a un-charged sample and b hydrogen-charged before deformation; c un-charged sample and d hydrogen-charged sample at a global strain amplitude of 2%. An example showing the estimation process of dislocation density from ECC images is displayed in a. The intersections of individual dislocations with the surface are marked by red dots. Dislocations density is obtained by counting the total number of the red dots divided by the area of blue rectangle. Inset in c showing the simulated electron channeling pattern. TD: tensile direction
Fig. 4 Evolution of the dislocation configurations in the deformed sample a1, b1 before vacuum aging and a2, b2 after vacuum aging (hydrogen desorption). Enlarged views of interested regions in b1, b2 displayed in rectangles with corresponding colors. a3 An example showing a typical pile-up feature in the hydrogen-free sample. GB: grain boundary
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