Influence of Structure Evolution on Magnetic Properties of Fe–Ni–Nb–B System

摘要

The effect of combined presence of iron and nickel has been studied in rapidly quenched amorphous (Fe–Ni) $_{81}{hbox {Nb}}_{7}{hbox {B}}_{12}$ system with the ratio of ${hbox {Fe/Ni}}=2/1$ and 1/2 in as-quenched state and after annealing. Field dependencies of magnetostriction as well as the values of saturation magnetostriction were correlated with the evolution of nanocrystalline structure in amorphous matrix in the temperature range from $sim$700 to 800 K and after complete crystallization above 900 K. Intervals of stability and transformation regions were determined from temperature dependencies of electrical resistivity. The structure after annealing at selected temperatures was identified by X-ray diffraction (XRD), transmission electron microscopy (TEM), and electron diffraction. MÖssbauer spectroscopy was used only as a complementary method to demonstrate the behaviour and development of the paramagnetic (FeNi) $_{23}{hbox {B}}_{6}$ phase from the original as-quenched structure. MÖssbauer and magnetostriction measurements were performed at room temperature. The observed field dependencies of magnetostriction are a combination of magnetostrictions of ferromagnetic and paramagnetic phases formed during the transformation process, namely, the nanocrystalline cubic Fe–Ni phases and face-centered cubic (fcc)-type structure (FeNi)$_{23}{hbox {B}}_{6}$, as identified from the structure analyses. The transition from purely ferromagnetic to partially paramagnetic state is well observed in the evolution of MÖssbauer spectra evolution. Different ratios of both ferromagnetic components Fe and-n Ni lead to a change of the structure of the nanocrystalline phases and thus also to a change in the magnetic behavior of the system.