Enhanced damping capacity of ferromagnetic Fe-Ga alloys by introducing structural defects

doi:10.1016/j.jmst.2020.12.061

Abstract

Abstract:

The irreversible motion of magnetic domain walls in ferromagnets can dissipate a large portion of the elastic energy, and the associated damping capacity is proportional to the magnetostriction constant. In contrast, here we found that the damping capacity of the large magnetostriction Fe-Ga alloys can be enhanced by 2-3 times through introducing structural defects including interfacial dislocations and stacking faults, despite that these defects deteriorate the magnetostriction. These structural defects were introduced by aging the BCC (body-centered-cubic) solution-treated precursor, for which the formation of mechanically harder FCT (face-centered-tetragonal) and /or FCC (face-centered-cubic) phases can result in high-density partial dislocations at the semi-coherent phase interfaces and quasi-periodically stacked nano-layer substructure inside the FCC variants. The structural defects act as extra damping sources besides the magnetic domain walls because the structural accommodation of the semi-coherent phase interfaces between BCC and FCT/FCC nanoprecipitates with different elastic moduli and the nano-layer substructure towards long-range ordered periodical stacking can dissipate a large portion of mechanical energy. These findings suggest that introducing structural defects provides fresh freedom to design high damping ferromagnetic materials.

Key words: Ferromagnets, Damping capacity, Defects, Magnetostriction, Fe-Ga alloy

Ruihua Qiao, Junming Gou, Tianzi Yang, Yiqun Zhang, Feng Liu, Shanshan Hu, Tianyu Ma. Enhanced damping capacity of ferromagnetic Fe-Ga alloys by introducing structural defects[J]. J. Mater. Sci. Technol., 2021, 84: 173-181.

Figures/Tables 8

Fig. 1. Damping capacity (a), magnetostriction (b), and XRD profiles (c) for the Fe74Ga26 sheet samples with different heat-treatments. The inset of (b) shows the magnetization hysteresis loops.

Fig. 2. Quasistatic compressive stress?strain curves for the Fe73Ga27 cylinder rod samples with different heat-treatments：(a) solution-treated at 1373 K, (b) aged for 72 h at 803 K, (c) aged for 720 h at 803 K.

Fig. 3. Bright field images and SAED patterns for the Fe74Ga26 sheet samples: (a) solution-treated at 1373 K and (b) aged for 2 h at 803 K.

Fig. 4. TEM characterizations of the Fe74Ga26 sheet sample aged for 2 h at 803 K: (a) Bright-field image, (b), (c), and (d) HR-TEM images for the regions I, II, and III in (a).

Fig. 5. TEM characterizations of the Fe73Ga27 cylinder rod sample aged for 72 h at 803 K: (a) bright-field image taken with [001]-BCC incidence, (b) SAED pattern of the BCC phase, (c) dark-field image taken using one FCC reflection (red arrow in (d)) for the Fe73Ga27. (d) SAED pattern taken from the region contain both BCC and FCC phases.

Fig. 6. HR-TEM image (a) and the corresponding FFT pattern (b) of the heavily-faulted FCC variant in the Fe73Ga27 cylinder rod sample aged for 72 h at 803 K.

Fig. 7. Schematic image of the interface between BCC and FCC Fe-Ga: (a) projection of phase interface, (b) two kinds of possible metastable interfacial structures.

Fig. 8. In-focus (a), over-focus (b), and de-focus (c) L-TEM Fresnel images of the Fe73Ga27 cylinder rod sample aged for 72 h at 803 K.

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