Skubic B, Holmström E, Iuşan D, Bengone O, Eriksson O, Brucas R, Hjörvarsson B, Stanciu V, Nordblad P
Department of Physics, Uppsala University, Box 530, SE-751 21 Uppsala, Sweden.
Phys Rev Lett. 2006 Feb 10;96(5):057205. doi: 10.1103/PhysRevLett.96.057205. Epub 2006 Feb 6.
We have studied alloying of the nonmagnetic spacer layer with a magnetic material as a method of tuning the interlayer coupling in magnetic multilayers. We have specifically studied the Fe/V(100) system by alloying the spacer V with various amounts of Fe. For some Fe concentrations in the spacer, it is possible to create a competition between antiferromagnetic Ruderman-Kittel-Kasuya-Yoshida exchange and direct ferromagnetic exchange coupling. The exchange coupling and transport properties for a large span of systems with different spacer concentrations and thicknesses were calculated and measured experimentally and good agreement between observations and theory was observed. A reduction in magnetoresistance of about 50% was observed close to the switchover from antiferromagnetic to ferromagnetic coupling.
我们研究了将非磁性间隔层与磁性材料合金化,以此作为调节磁性多层膜中层间耦合的一种方法。我们特别通过将间隔层V与不同含量的Fe合金化,对Fe/V(100)体系进行了研究。对于间隔层中某些Fe浓度而言,有可能在反铁磁的Ruderman-Kittel-Kasuya-Yoshida交换作用与直接铁磁交换耦合之间产生竞争。对具有不同间隔层浓度和厚度的一系列体系的交换耦合和输运性质进行了计算,并通过实验测量,观测结果与理论之间呈现出良好的一致性。在从反铁磁耦合转变为铁磁耦合的转变点附近,观察到磁电阻降低了约50%。