Formation mechanism of partial stacking faults by incomplete mixed-mode phase transformation: A case study of Fe-Ga alloys

doi:10.1016/j.jmst.2021.12.009

Abstract

Abstract:

Partial stacking faults (PSFs) formed by incomplete mixed-mode phase transformation have been found to exhibit unfixed slip distance of closely-packed planes unlike those of the deformation-induced stacking faults (SFs) with fixed distance. Though engineering PSFs can yield appealing properties, such as the enhanced damping capacity, understanding of the interaction between lattice distortion and atomic diffusion and their influences on forming PSFs is still far from being clear. Herein we performed a case study on aged Fe-Ga alloy that undergoes a mixed-mode phase transformation from body-centered cubic (BCC) to ordered face-centered cubic (FCC). The TEM investigations showed that the faulted {111}-FCC distance of the PSFs is shorter than a/6<112> of the typical {111}-<112> SFs in deformed FCC materials and the PSFs have disordered Fe and Ga arrangements. Further studies revealed that such PSFs will not be completely dissociated at FCC twin boundaries (TBs) even after long term isothermal aging. Consequently, the formation of PSFs can be ascribed to the transformation-dependent atomic ordering and lattice shear strain of the parent BCC lattice, where the diffusion-controlled glides of the PSFs-associated dislocations will accelerate atomic diffusions due to the dislocation-pipe effect along <112>-FCC direction, but may hinder the atomic diffusions across the {111}-FCC TBs due to the retarding effect. This study may add important insight into the defects process during mixed-mode phase transformation and broaden the knowledge of the interaction between concurrently-happened lattice distortion and atomic diffusion.

Key words: Stacking faults, Mixed-mode phase transformation, Diffusion, Lattice distortion, Fe-Ga alloy

Tianzi Yang, Tianyu Ma, Feng Liu, Xiaobing Ren. Formation mechanism of partial stacking faults by incomplete mixed-mode phase transformation: A case study of Fe-Ga alloys[J]. J. Mater. Sci. Technol., 2022, 117: 59-64.

Figures/Tables 6

Fig. 1. TEM characterization of 8h-aged Fe73Ga27 along [110]FCC ZA. (a) Bright-field image, (b, c) SAED patterns of the homogeneous and heterogeneous regions in (a), (d)-(f) dark-field images taken using the spots marked by I, II, and III in (c), respectively. (c, d) Were firstly shown in Ref. [41].

Fig. 2. (a) HRTEM image with partial stacking faults at the twin boundary (TB) of L12 phase. (b) HRTEM image of BCC lattice of the solution-treated sample. Derived disorder model (c) and order model (d) of forming partial stacking faults on the projections of [010]BCC // [110]FCT/FCC.

Fig. 3. Unit cell, projection and simulated electron diffraction pattern for the (a) rhombohedral lattice containing two disordered layers, (b) rhombohedral lattice containing two ordered layers, and (c) cubic-closely packed (CCP) L12 Fe3Ga.

Fig. 4. TEM characterization of the 8h-aged Fe73Ga27 sample along [112]FCC ZA. (a) Bright-field image, (b) SAED pattern and (c) intensity profile along the white arrow in (b). Red arrows indicate the reflections of disordered FCT phase.

Fig. 5. (a) HRTEM image of the region containing stacking faults and local R phase in the 8 h -aged sample. (b) FFT pattern of the white square in (a).

Fig. 6. TEM characterization of the Fe73Ga27 sample aged for 720 h at 530 °C. (a, b) SAED patterns taken from the regions circled by dashed blue and black lines in (c), respectively. (c) STEM image of the region containing transformed L12 variants and untransformed BCC matrix. Elemental mapping images (d) and elemental distributions (e) along the white arrow in (c).

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