Influence of Magnetic Field Intensity on the Shape of the μ-T Curves for Fe73.5Cu1Nb3Si13.5B9 Alloy

Under different magnetic field intensities, the dependence of the permeability μ on temperature T(μ-T curve) for the Fe7.3Cu1Nb3Si13.5B9 alloy annealed at 350-620℃ was investigated. The results showed that the magnetic field intensity had a remarkable influence on the shape of μ-T curves. For amorphous alloy, the sharp Hopkinson peak of μ-T curve disappeared gradually with the increase of magnetic field intensity.

基于Fe73.5Cu1Nb3Si13.5B9非晶/纳米晶粉的压磁复合材料研究

研究了基于Fe73.5Cu1Nb3Si13.5B9非晶/纳米晶粉的柔性压磁复合材料制备技术及其性能,讨论了橡胶种类,磁粉粒径、含量及工艺因素等对Fe73.5Cu1Nb3Si13.5B9/橡胶复合材料压磁性能的影响。结果表明:采用粒径为45μm,用量约15%的Fe73.5Cu1Nb3Si13.5B9非晶/纳米晶粉与高温硫化有规共聚硅氧烷在171℃,15MPa条件下,硫化45min制备的、厚度约150μm的压磁复合材料薄膜具有较好的应力敏感特性和压磁稳定性能,有望作为新一代柔性、薄型接触应力传感器的敏感元件材料。

Ordering of the α-Fe(Si) Crystallization Phase in Annealed Fe_(73.5)Cu_1Mo_3Si_(13.5)B_9 Alloy

The ordering of the α-Fe(Si) crystallization phase in annealed Fe73.5Cu1Mo3Si13.5B9 alloy has been studied using XRD method. The α-Fe(Si) phase in Fe73.5Cu1Mo3Si13.5B9 alloy annealed at 460℃ for 1 h consists of the DO3-type ordered region with spherical shape and disordered region. The size of DO3 ordered region increases with the annealing temperature. When the annealing temperature is 560℃, the size of the ordered region in the α-Fe(Si) grain is 14.0nm,which is nearly as large as that of the α-Fe(Si) grain (14.2 nm) and the degree of order of the α-Fe(Si) phase is about 0.78. When Fe73.5Cu1 Mo3Si13.5B9 amorphous alloy is annealed at 520℃， with the increment of the annealing time, the shape of the DO3 ordered region in the α-Fe(Si) phase is spheroidal at the beginning of the annealing and becomes spherical and has asize of 12.8 nm when the annealing time is 60 min. In addition, the DO3 superlattice lines of the α-Fe(Si) phase will vanish if Fe73.5Cu1Mo3Si13.5 B9 amorphous alloy is annealed for 1 h at 750℃.

Relations among High-frequency Magnetic Properties and Frequency in Nanocrystalline Fe_(72.5)Cu_1Nb_2V_2Si_(13.5)B_9 Alloy

High-frequency magnetic properties, such as core loss, coercivity and amplitude permeabilityof a newly-developed nanocrystalline Fe72.5Cu1Nb2V2Si13.5B9 alloy in the wide ranges of f =20-103 kHz, Bm = 0.01~0.6 T and Bmf = 10~40 (T.kHz) have been measured. A largeamount of experimental data have been fitted by a computer, thus obtaining several expressionsrepresenting the influence of frequency on high-frequency magnetic properties, that are useful inpractical applications.

Microstructure and Stability of Fe_(73.5) Cu_1Nb_3Si_(13.5)B_9 Alloy at Different Stages of Phase Transformation

The microstructure and the stability of Fe_73.5Cu_1Nb_3Si_13.5B_9 alloy at different stages of phase transformation were investigated through the observation of X-ray difraction and transmission electron microscopy and the measurement of magnetic aftereffect (MAE). It was found that the dependence of the volume fraction of amorphous phase and the MAE in the samples annealed from 450 to 700℃ on the annealing temperature is similar.

Magnetic Properties and Applications of Newly-developed Fe_(73.5)Cu_1Nb_(1.5)V_(1.5)Si_(13.5)B_9 Alloy

The synthetical soft magnetic properties including d.c. and a.c. magnetic properties and pulse magnetic property are reported for a newly-developed nanocrystalline Fe73.5Cu1 Nb1.5V1.5Si13.5B9 alloy The new alloy possesses high d.c. relative initial permeability of 12.5×104 and low coerciv ity of 0.54 A/m. Under the conditions of Bm=0.3 T, f=100 kHz and Bm=0.2 T, f=200 kHz the core losses of the new alloy are 543 kW·m-3 and 834 kW.m-3, respectively which can be compa rable with those of nanocrystalline Fe73.5Cu1Nb3Si13.5B9 alloy. The analyses of core losses have been carried out in the wider range of f=20～104 kHz and Bm=0.0025～0.8 T and the approxi mate expression P(kW·m-3)=1.803 B:f1.77 has been obtained. The analyses of core losses in the range of f=20～104 kHz and Bmf=(10～40)×103(T.Hz) have shown that the core loss and the corresponding amplitude permeability roughly vary as P = 2.347×10-6(Bmf)1.97f-0.2231 and μa = 9.56× 105f-0.7464, respectively for the given product B.f. Some practical applica tions have also been mentioned.

Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9非晶粉/硅橡胶压磁复合材料的制备与性能研究

采用机械共混法制备Fe73.5Cu1Nb3Si13.5B9非晶粉/硅橡胶压磁复合材料,并对其压磁性能进行研究。结果表明,Fe73.5Cu1Nb3Si13.5B9非晶粉/硅橡胶复合材料具有良好的压磁性能,且压磁性能稳定性和阻抗蠕变性能优异,可用于新型压力传感器用力敏元件。

Fe_(73)Cu_(1.5)Nb_3Si_(13.5)B_9淬态薄带中的巨磁阻抗效应研究

通过调高Cu在合金薄带的含量 ,并采用合适的甩带速度V ,在FeCuNbSiB淬态薄带材料中观察到了较大的巨磁阻抗效应。甩速V =30m/s的Fe73 Cu1 5Nb3 Si13 5B9淬态薄带在外加直流磁场H =716 2A/m下 ,在 f =30 0kHz时磁阻抗ΔZ/Z0 为 - 2 2 6 %。另外发现Fe73 Cu1 5Nb3 Si13 5B9淬态薄带中横向磁各向异性很微弱。Fe73Cu1 5Nb3 Si13 5B9淬态薄带中ΔZ/Z0 随磁场变化的峰值基本来源于ΔX/X0 项的变化。在 f≤ 16MHz的频率范围内 。

(FeCo)_(73.5)Cu_1Nb_3Si_(13.5)B_9的晶化处理及微结构

采用熔体快淬+晶化处理方法制备宽度为4 mm、厚度为30μm的Fe73.5Cu1Nb3Si13.5B9纳米晶软磁合金,并用XRD和TEM对其微结构进行表征。研究结果表明:(FeCo)73.5Cu1Nb3Si13.5B9于600℃晶化处理15 min后具有较高的饱和磁化强度(1.30 T)和较小的矫顽力(4.61 A/m);提高晶化温度至700℃,合金的软磁性能迅速降低,饱和磁化强度为1.02 T,矫顽力增大至1.95 kA/m;于600℃晶化处理5 min时,合金主要由非晶构成,同时有少量α-Fe(Si)相;于600℃晶化处理15 min后合金由α-Fe(Si)主相和少量残余非晶相构成,α-Fe(Si)相的晶粒粒径约为15 nm;于700℃晶化处理15 min后,合金由α-Fe(Si)相、残余非晶相和少量Fe3B相构成,α-Fe(Si)相的晶粒粒径约为27.9 nm。Fe3B相的形成、α-Fe(Si)相晶粒粒径的长大和晶格常数的增大直接导致合金软磁性能下降。

环氧树脂基磁性复合材料的起始磁导率研究

以环氧树脂为基体,以经退火的Fe73.5Cu1Nb3Si13.5B9非晶粉体为增强材料,制备了树脂基磁性复合材料,并研究了磁粉种类、非晶粉体粒径、非晶粉体退火条件、纳米晶粉体含量以及复合材料去应力退火条件对复合材料的起始磁导率的影响。结果表明,以经550℃×0.5 h退火的Fe73.5Cu1Nb3Si13.5B9纳米晶粉体为磁性增强体的复合材料的起始磁导率最大;随着纳米晶粉体含量的增加,复合材料的起始磁导率增大;对复合材料进行去应力退火可以提高其起始磁导率。

纳米晶FeCuNbSiB多层膜的巨磁阻抗效应研究

研究了纳米晶态下Fe73.5Cu1Nb3Si13.5B9多层膜的巨磁阻抗(GMI)效应。研究结果表明纵向巨磁阻抗(LMI)效应在3MHz时取得最大值为44%,横向巨磁阻抗(TMI)效应在6MHz时取得最大值为46%。LMI与TMI随外磁场有不同的变化行为,TMI曲线具有阈值行为,超过阈值磁场后出现明显的磁阻抗效应。晶化后出现最大值阻抗效应所对应的频率下降,由非晶态下的13MHz下降为晶化后的3MHz。薄膜样品的磁阻抗效应与样品中磁矩的空间分布密切相关,磁矩垂直面向分布时,磁阻抗效应下降为5%

铁基纳米微晶薄膜巨磁阻抗效应的Mossbauer研究

本文采用 M?ssbauer 谱学方法以及其它手段对 FeCuNbSiB 薄膜样品在退火过程中出现的巨磁阻抗效应发生显著变化的原因进行了探讨。研究表明,样品在退火过程中除了生长纳米晶粒α ? FeSi相对提高材料的软磁性能有利外,同时随退火温度变化样品中磁矩分布方向会发生重取向。由制备态到 570 ℃退火温度期间,薄膜样品磁矩取向发生由平行于平面为主变为垂直为主,而后再转变为平行为主。这些因素对多层膜巨磁阻抗效应的变化会产生重要影响,尤其当磁矩在垂直于平面方向分布占优势时,磁阻抗效应会显著下降。

预退火对Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9纳米晶合金巨磁阻抗效应的影响

用HP4294A型阻抗分析仪测量了经不同温度预退火后再540℃退火的Fe73.5Cu1Nb3S i13.5B9纳米晶合金薄带的巨磁阻抗,并结合XRD衍射图谱和AFM图谱,研究了预退火对纳米晶介观结构的影响.结果发现,200℃、300℃和400℃预退火处理40 m in对随后540℃退火的Fe73.5Cu1Nb3S i13.5B9薄带-αFe(S i)纳米晶介观结构产生了影响,颗粒团聚优势明显减弱,横向各向异性场减小,巨磁阻抗比得到了显著的提高.

纳米晶软磁材料Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9中子衍射研究

用中子衍射技术研究了 3种不同热处理温度下形成的纳米晶软磁材料Fe73 .5Cu1Nb3Si13 .5B9的内部微观结构及其随热处理温度的变化。实验结果表明 :Fe73 .5Cu1Nb3Si13 .5B9非晶经等温热处理 1h后 ,生成的是高度有序的DO3结构的固溶体Fe3Si(Fe)。首次确定了Si主要占据 4a位 ,Fe除少量占据 4a位外 ,主要占 4b和 8c位 ,并定量地给出了上述 3种样品的Si的占位数和平均晶粒尺寸。另外 ,热处理温度为 853K时 ,样品晶胞变大 ,有部分B原子进入 4 8h位。热处理温度为82 3K时 ,样品具有最高的Si含量 (原子百分比 19 8% )和最小的晶粒尺寸 ( 8 9nm) ,这可能是样品有最佳软磁性能的原因。

微波场作用下非晶合金Fe_(73．5)Cu_1Nb_3Si_(13．5)B_9的纳米晶化

研究了微波场对晶化的影响.结果表明,将非晶合金Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9在微波场作用下在480℃短时间(5 min)晶化处理,形成体积分数为80%、尺寸约15nm的α-Fe(Si)相;适当延长晶化时间(30 min)使非晶合金完全晶化,α-Fe(Si)相的晶粒不再长大,原子层之间的距离降低至0.2461 nm,磁体具有最大M_s为1.79 T.与激光、激波、脉冲电场和脉冲磁场晶化处理相比,微波场晶化处理可同时获得单一的、更小晶粒尺寸和更高体积分数的α-Fe(Si)晶化相,使合金具有高的饱和磁化强度和优良的软磁性能.微波场有利于非晶合金中的硼原子向空位跃迁,使基体金属相α-Fe(Si)相的形核率增大,促进非晶合金的纳米晶化.

Fe(73.5)Cu_1Nb_3Si_(13.5)B_9非晶合金的激光晶化

用CO2 连续激光在不同功率、相同的速度条件下辐照Fe73 5Cu1Nb3 Si13 5B9非晶带 ,然后用穆斯堡尔谱详细研究材料的微观结构 .研究发现当扫描速度和散光斑直径一定的情况下 ,适当选择激光功率 ,Fe73 5Cu1Nb3 Si13

环氧树脂封装对Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9纳米晶磁芯软磁性能的影响

用宽为20 mm、厚为25μm的Fe73.5Cu1Nb3Si13.5B9非晶带材绕制成环型磁芯,将其经550℃×100 min晶化退火处理制成纳米晶磁芯,研究环氧树脂封装对纳米晶磁芯软磁性能的影响。结果表明:与环氧树脂封装前相比,起始磁导率μ0、最大磁导率μm、幅值磁导率μa、饱和磁感应强度Bs、直流损耗Pu和交流损耗Ps减小,矫顽力Hc增大;当测试频率不变时,电感Ls和品质因数Q减小。

Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9非晶薄带的磁电感效应

研究了输入交流电波形和非晶薄带片数等对Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9非晶薄带磁电感效应和磁电感效应变化幅度的影响,以及当输入电压为正弦交流电压时,非晶薄带的磁电感效应变化幅度的重复性和温度、湿度的稳定性。结果表明:磁电感效应随着非晶薄带片数的增多而增强,随着磁场强度的增大而减弱,正弦交流电压比三角交流电压的强;磁电感效应变化幅度随着非晶薄带片数的增多而减小,在不同频率下正弦交电压和三角交流电压的强弱发生变化;当输入电压为正弦交流电压时,磁电感效应变化幅度的不重复性误差很小,且受温度和湿度的影响很小。

退火条件对树脂基复合材料起始磁导率的影响研究

以环氧树脂为基体,以经退火的Fe73.5Cu1Nb3Si13.5B9非晶粉体为增强材料,制备了树脂基复合材料。研究了非晶粉体退火条件、纳米晶粉体含量及去应力退火条件对树脂基磁性复合材料的起始磁导率μi的影响。结果表明,以经550℃×0.5h退火的Fe73.5Cu1Nb3Si13.5B9纳米晶粉体为组元的树脂基复合材料的起始磁导率μi最大,为2.528;随着纳米晶粉体含量的增加,树脂基复合材料的起始磁导率μi增大;去应力退火可以提高树脂基复合材料的起始磁导率μi。

脉冲电流处理对Fe_(73.5)Cu_1Nb_3Si_(13.5)B_9合金薄带GMI效应的影响

本文研究了脉冲电流处理对Fe73 5Cu1Nb3 Si13 5B9合金薄带巨磁阻抗效应和脆性的影响 ,并与等温退火样品的巨磁阻抗效应和脆性进行对比。结果表明 ,经过应力脉冲电流处理后的样品 ,其阻抗变化率和灵敏度都显著高于无应力脉冲处理后的样品。淬态样品在 9 34MPa拉应力下 ,经电流密度为 930A/mm2 的脉冲电流处理后 ,阻抗变化率可达到 2 2 0 % ,灵敏度达到 0 35 % /A·m-1。用应力脉冲电流处理不仅可以显著提高巨磁阻抗效应 ,而且可以有效抑制样品长时间的等温退火带来的脆性问题。