不同磁场退火方式FeZrBCu薄膜巨磁阻抗效应比较

用射频溅射法制备了(Fe88Zr7B5)0.97Cu0.03软磁合金薄膜,研究了不同磁场退火方式对薄膜磁导率和巨磁阻抗(GMI)效应的影响。结果表明,纵向和横向磁场退火都能有效地提高薄膜样品的巨磁阻抗效应,在13MHz频率下纵向最大GMI比分别为18.6%和17%;纵向磁场退火后薄膜样品的横向磁各向异性消失,横向磁场退火则能有效增强横向磁各向异性,提高巨磁阻抗效应的磁场响应灵敏度;磁场诱导的磁导率变化是巨磁阻抗效应变化的主要原因。

制备态(Fe_(88)Zr_7B_5)_(100-x)Cu_x非晶薄膜的磁特性和巨磁阻抗

采用射频溅射法在单晶Si衬底上制备了Fe88Zr7B5)100-xCux(x=0、1、2、3、4)非晶薄膜样品,对其软磁特性和巨磁阻抗(GMI)变化行为进行了测量和研究。测量结果显示,加入适量Cu元素(x=3)的制备态样品具有极好的软磁性能和GMI效应,此样品的矫顽力仅有56A/m,在13MHz的频率下,最大有效磁导率(μe)比和GMI比分别为42.5%和17.0%。研究发现,制备态样品的电阻R、电抗X和阻抗Z都随Cu含量的增加而下降。X=0、4两个样品的μe、R、X、Z对外加磁场响应极不敏感,只有软磁性能优异的x=3样品的μe、R、X、Z才显示出对外加磁场响应敏感,因而有显著的GMI效应。样品拥有高的磁导率、小的矫顽力和低的电阻率是获得大GMI效应的本质条件。

Giant magnetoimpedance effect in as quenched Fe_(89-x)Zr_7B_4Cu_x(x=1.0-2.5) ribbons

The giant magnetoimpedance(GMI)effect in as-quenchedFe_89-xZr_7B_4Cu_x(x=1.0-2.5)ribbons is reported. The as-quenchedFe_89-xZr_7B_4Cu_x(x=1.0-2.5)ribbons were prepared by the vacuummelt-spun processes with the quenching speed of 37 m/s. The magne-Toimpedance measurement were performance at room temperature, wherethe current flow through the length of the ribbons in the directionParallel to the dc fields. results show that values Z(impedance),R(resistance)for both H = 0 A/m and H = 5 127 A/m Increases withincreasing ac frequency. This can be explained by the skin effectmechanism.