Structural, magneto-mechanical, and damping properties of slowly-cooled polycrystalline Fe81Ga19 alloy

Abstract

In this study, we discussed the structural, magneto-mechanical, and damping properties of slowly-cooled polycrystalline Fe81Ga19 alloy. From the X-ray diffraction, transmission electron microscopy, and optical microscopy studies, we conclude that the alloy contains the disordered A2 and ordered D03 phases. Due to the D03 precipitation hardening effect, the yield strength (Y) of slowly-cooled Fe81Ga19 is about 950 MPa, much higher than that (about 500 MPa) of [100] single crystal Fe81Ga19. For the first time, both Young's modulus (E) and shear modulus (G) were measured vs. magnetic field (H) up to 3 kOe by the impulse excitation of vibration method successfully: the ΔE and ΔG effects. The magneto-mechanical (flexure) coupling factor (KE) of the alloy, estimated from the ΔE effect, is 11.7%, and the (torsion) coupling factor (KG), from the ΔG effect, is 19.1%. The damping capacity, estimated by considering the magneto-elastic hysteresis mechanism alone, is 0.0076 only. The experimentally found total damping capacity is about 0.01–0.03. The latter should be larger than the former, because there are additional micro- and macro-eddy-current contributions to the total damping capacity.