Preparation and magnetic properties of Co2-based Heusler alloy glass-coated microwires with high Curie temperature

In this article, we studied the effect of annealing (600 ? for 1 h) and the applied magnetic field from 50 Oe to 20 kOe of Co2FeSi glass-coated microwires with ordered L2(1) structure prepared by Taylor-Ulitovsky technique on the magnetic behavior. The as-prepared and annealed samples show a ferromagnetic behavior at the range of measuring temperature (5 to 400 K) and magnetic field (50 Oe to 20 kOe). M-H loops of as prepared sample do not show a squared shape. Meanwhile, perfectly squared hysteresis loops have detected for the annealed sample. In addition, annealed sample shows high magnetization M/M-5K ratio, coercivity, and anisotropy field, as-compared to the as-prepared one. The annealed sample shows considerable irreversibility when the magnetic behavior changes with temperature upon the applied magnetic field at 50 and 200 Oe. Such irreversibility does not found in the as-prepared sample measured at the same magnetic field due to mixed amorphous and crystalline structure. By increasing the external magnetic field higher than 200 Oe and up to 20 kOe a gradual changing in the magnetic behavior has been detected where the irreversibility disappeared at applying magnetic field about 1 kOe and the magnetic behavior is totally change by increasing the external magnetic field up to the maximum 20 kOe. The difference in the magnetic behavior of the annealed glass-coated Co2FeSi glass-coated microwires indicates the effect of internal stresses induced by the presence of the glass-coating and the annealing-induced recrystallization.

Automated summary

In this article, the effect of annealing and the applied magnetic field on the magnetic behavior of Co2FeSi glass-coated microwires with ordered L2(1) structure prepared by Taylor-Ulitovsky technique was studied. The as-prepared and annealed samples exhibited ferromagnetic behavior in the measured temperature and magnetic field range. The annealed sample showed higher magnetization ratio, coercivity, and anisotropy field compared to the as-prepared sample. Irreversibility was observed in the annealed sample at lower magnetic fields, while it was absent in the as-prepared sample due to the mixed amorphous and crystalline structure. Increasing the magnetic field resulted in a gradual change in the magnetic behavior, with the irreversibility disappearing at a magnetic field of about 1 kOe.