Glass Forming Ability, Thermal Stability, and Magnetic Properties of FeCoNiBSi Alloys with Different B Contents

*e dependence on the glass forming ability, magnetic property, and thermal stability of the (Fe0.39Co0.15Ni0.46)82−xB12+xSi6 (x� 0, 2, 4, and 6) alloys was investigated.*e results show that the as-quenched alloy ribbons exhibit a completely amorphous structure with B content in the range of 12∼18 at.%. *e initial crystallization onset temperature of the as-quenched ribbon increases with the increase of B content.When the B content is up to 14 at.%, the temperature interval between the two crystallization peaks will sharply reduce, which narrows the effective annealing range that is detrimental to improving the soft magnetic properties. Both of theMs and Hc of the as-quenched ribbons increase first and then decrease with the increase of B content. Here, the maximumMs of 0.90 Tand low Hc of 10.2A/m can be obtained at the B content of 14 at.%. Additionally, the (Fe0.39Co0.15Ni0.46)80B14Si6 alloy exhibits the minimum Hc of 5.9A/m and Ms of 0.934T at the proposed annealing temperature of 698K for 10min in the vacuum condition.


Introduction
Soft magnetic amorphous alloys have been well known in the various electromagnetic applications, such as sensors, transformers, and electronic and power devices [1][2][3] because of their excellent magnetic properties including the high saturation magnetization, ultrahigh magnetic permeability, and low coercive force [3][4][5].Fe 40 Ni 38 Mo 4 B 18 (Metglas2826MB) amorphous alloy was the earliest magnetic material [6,7] applied to the acoustomagnetic antitheft label and received a lot of attentions and debates.Srivastava et al. [8] investigated the microstructure and magnetic properties of Fe 40 Ni 38 Mo 4 B 18 at the various degrees of crystallization from the amorphous state and found that the (Fe,Ni,Mo) 23 B 6 phase and FCC (Fe,Ni) solid solution can be formed after the crystallization at the annealing temperatures around 414 °C and 522 °C.Szewczyk et al. [9] studied the initial curve and major and minor magnetostriction hysteresis butterfly loops of the as-quenched Fe 40 Ni 38 Mo 4 B 18 amorphous alloy as a function of quasistatic magnetic field.Liang et al. [10] pointed out that the additive of B can remarkably reduce the remanence of the amorphous FeNi-MoB thin films.However, application of the amorphous Fe 40 Ni 38 Mo 4 B 18 alloy labels may cause false alarms in the electronic article surveillance (EAS) system [11] owing to that the internal stress distribution of the FeNiMoB alloy is associated with a nonlinear hysteresis loop [12].us, the amorphous FeCoNiBSi alloy [13] proposed by Hezer is popularly used for the magnetic EAS labels at present because of its properties of moderate magnetostriction (<5 ppm) and corrosion resistance [14].
Considering the further development of this FeCoNiBSi alloy as an engineering material, it is extremely important to find the balance between the low cost and high magnetic property.e metalloid element of boron (B) is beneficial to the glass formation ability improvement, amorphous structure stabilization, and grain refinement for the Fe-based amorphous alloys [15].It is well known that Fe-B amorphous alloys can be formed in the composition with B content in the range of 12-28% at.% [16] by melt-spinning process.Wang et al. [17] indicated that amorphous phases can be formed in a wide B-content range of 11∼31 at.% for (Fe,Co,Ni,Cr,Mo)-B amorphous alloys.Moreover, Yao et al. [18] investigated the effect of B content on crystallization, forming ability, and magnetic properties of FeZrBNb amorphous alloy and showed that only one exothermic peak can be observed in the DSC curves when B content exceeds 20 at.%.Based on the discussions, the e ect of B content on the glass formation ability and magnetic properties of (Fe 0.39 Co 0.15 Ni 0.46 ) 82−x B 12+x Si 6 (x 0, 2, 4, and 6) was studied in this work with industrial raw materials.

Alloy
ingots with nominal compositions of (Fe 0.39 Co 0.15 Ni 0.46 ) 82−x B 12+x Si 6 (x 0, 2, 4, and 6) were prepared by melting the mixtures of industrial raw materials Fe (99.9 wt.%), Co (99.9 wt.%), Ni (99.9 wt.%), Si (99.9 wt.%), and commercial prealloyed Fe-B ingot (17.4 wt.% B) in a high puri ed argon (Ar) atmosphere.e ingots were reversely remelted at least three times to enhance homogeneity.Melt-spun ribbons within width and thickness of about 0.002 m (2 mm) and 0.00003 m (30 μm), respectively, were prepared by a single roller melt-spinning technique at a wheel rotating speed of 50 m/s in the Ar atmosphere as shown in Figure 1. e as-quenched ribbons were annealed at various temperatures with a heat rating of 20 K/min to the speci ed temperature by using a tubular furnace in the vacuum atmosphere and heated for 10 min and then cooled to room temperature in the furnace.e phase structures of the asquenched and annealed ribbons were identi ed by X-ray di raction (XRD) with Cu Kα radiation.ermal properties including crystallization onset temperature (T x ) and peak temperature (T p ) were evaluated by using di erential scanning calorimeter (DSC) at a heating rate of 20 K/min.Saturation magnetization intensity (Ms) and coercive force (Hc) were measured with a vibrating sample magnetometer (VSM) under the maximum applied eld of 1,200,000 A/m and a DC B-H loop tracer under a eld of 800 A/m, respectively.e density of the ribbons is about 7.40 g/cm 3 , which was obtained by the Archimedes method.e broad peaks at around 2θ 45 °without any other distinct di raction peaks exhibiting amorphous structures can be detected for all asquenched ribbons with B content in the range of 12-18 at.%. Figure 3 displays the DSC curves of the corresponding asquenched ribbons with di erent B contents.It is observed that the crystallization processes of these ribbons proceed in two stages: the initial crystallization onset temperature (T x1 ) indicates the precipitation of c-FeNi phase, and the second one (T x2 ) corresponds to complete crystallization of the remaining amorphous phase.Detailed results of DSC curves are summarized in Table 1.It is seen that the T x1 of the asquenched ribbon increases from 707.45 K to 778.35 K with the increase of B content from 12 at.% to 18 at.%,which indicates that the increase of B content is bene cial to the  Advances in Materials Science and Engineering thermal stability improvement for the given amorphous ribbons.However, the T x2 of the as-quenched ribbon gradually decreases as the B content is greater than 14 at.%.Under this situation, the temperature interval (ΔT x ) between the T x1 and T x2 sharply reduces from 68.7 K to 24 K when the B content increases from 14 at.% to 18 at.%. at is to say, the magnitude of e ective annealing temperature range will rapidly decrease as the B content exceeds the critical value (14 at.%), which is detrimental to obtaining good soft magnetic properties [19].Figure 4 indicates the B-content dependence of the magnetic hysteresis loop, Ms, and Hc for the as-quenched   e value of Ms rst increases gradually from 0.89 T to 0.90 T with the increase of B content from 12 at.% to 14 at.% and then sharply decreases to 0.72 T as the B content is up to 18 at.%because of the reduction in the amount of ferromagnetic elements (Fe, Co, and Ni) [15].Meanwhile, the Hc changes in the same manner with the increase of B content and exhibits the minimum of 10.15 A/m at the B content of 12 at.%.It is also shown that a small increment of 0.05 A/m for the Hc is observed when the B content increases from 12 at.% to 14 at.%. erefore, the alloy within compositions of (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 is proposed to be the coste ective material because of its higher Ms and lower Hc and cost than the other alloys.5 presents the XRD patterns of the as-quenched (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 alloy ribbons annealed at various temperatures for 10 min [20] in the vacuum condition.Here, the annealing temperature range of  4

Annealing Process. Figure
Advances in Materials Science and Engineering 678∼738 K was employed to control the nanostructure without precipitation of the secondary phase, which deteriorates the soft magnetic properties of ribbon, such as Fe-Ni phase, as per the initial crystallization onset temperature (T x1 ) shown in Figure 3. e amorphous structures with the broad peaks at around 2θ � 45 °can be found at the annealing temperatures of 678 K and 698 K.However, as the annealing temperature is up to 718 K, a diffraction peak at 2θ � 44 °corresponding to c- [Fe,Ni] is observed in the XRD patterns.Moreover, two obvious diffraction peaks at 2θ � 44 °and 46 °corresponding to c- [Fe,Ni] and Ni 2 B [21], respectively, can be detected within the annealing temperature of 738 K.
Figure 6 displays the dependence of magnetic hysteresis loop, Ms, and Hc for the as-quenched (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 ribbon on the annealing temperature ranging from 678 K to 738 K.It is observed that all the as-annealed ribbons exhibit the typical soft magnetic hysteresis loops.e Ms of the asquenched (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 ribbon gradually increases from 0.90 T to 0.95 T with the increase of the annealing temperature from 678 K to 738 K.After a series heat treatments, the Hc of the as-quenched ribbon decreases significantly from 10.2 A/m to 5.9 A/m in the temperature range of 678∼698 K, and the Hc exhibits the minimum value of 5.9 A/m at 698 K. Combined with the results of Figure 3, the decrease of the Hc can be attributed to the relief of internal residual stress and the reduction of magnetocrystalline anisotropy [12,17].When the ribbons are annealed at higher temperature, the Hc increases rapidly because of the excessive growth of precipitations of c-[Fe,Ni] or/and Ni 2 B as per the results shown in Figure 5. Based on the above discussions, it is shown that the (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 alloy exhibits the minimum Hc of 5.9 A/m and Ms of 0.934 T at the annealing temperature of 698 K.As the annealing temperature is up to 718 K, the Hc and Ms of the alloy are 8.5 A/m and 0.944 T, respectively.In view of the sensitivity of Hc on annealing temperature, the reasonable annealing temperature for (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 alloy is no more than 718 K, and the proposed annealing temperature is 698 K.

Conclusions
Dependence on the glass forming ability, magnetic property, and thermal stability of as-quenched (Fe 0.39 Co 0.15 Ni 0.46 ) 82−x B 12+x Si 6 (x � 0, 2, 4, and 6) alloy ribbons have been systemically investigated.e following conclusions can be drawn: (1) e amorphous structure can be detected for all asquenched (Fe 0.39 Co 0.15 Ni 0.46 ) 82−x B 12+x Si 6 ribbons with the B content ranging from 12 at.% to 18 at.%. (2) e T x1 of the as-quenched ribbon increases with the increase of B content, whereas the T x2 gradually decreases as the B content is greater than 14 at.%. e temperature interval (ΔT x ) between T x1 and T x2 reduces sharply from 68.7 K to 24 K with the increase of B content ranging from 14 at.% to 18 at.%,which narrows the effective annealing range that is detrimental to improving the soft magnetic properties. (

Figure 6 :
Figure 6: Dependence of magnetic hysteresis loop (a) and Ms and Hc (b) for the as-quenched (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 ribbon on the annealing temperature ranging from 678 K to 738 K.
3) Both of the Ms and Hc of as-quenched (Fe 0.39 Co 0.15 Ni 0.46 ) 82−x B 12+x Si 6 (x � 0, 2, 4, and 6) alloy ribbons increase first and then decrease with the increase of B content. e (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 alloy within the maximum Ms of 0.90 T and low Hc of 10.2 A/m is chosen as the cost-effective material for the EAS labels as compared to the other alloys.(4) e (Fe 0.39 Co 0.15 Ni 0.46 ) 80 B 14 Si 6 alloy exhibits the minimum Hc of 5.9 A/m and Ms of 0.934 T at the proposed annealing temperature of 698 K for 10 min under the vacuum condition.