When the thickness of metal film approaches the nanoscale, itinerant carriers resonate between its boundaries and form quantum well states (QWSs), which are crucial to account for the film’s electrical, transport and magnetic properties. Besides the classic origin of particle-in-a-box, the QWSs are also susceptible to the crystal structures that affect the quantum resonance. Here we investigate the QWSs and the magnetic interlayer exchange coupling (IEC) in the Fe/Ag/Fe (001) trilayer from first-principles calculations. We find that the carriers at the Brillouin-zone center (belly) and edge (neck) separately form electron- and hole-like QWSs that give rise to an oscillatory feature for the IEC as a function of the Ag-layer thickness with long and short periods. Since the QWS formation sensitively depends on boundary conditions, one can switch between these two IEC periods by changing the Fe-layer thickness. These features, which also occur in the magnetic trilayers with other noble-metal spacers, open a new degree of freedom to engineer the IEC in magnetoresistance devices.
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机译:当金属膜的厚度接近纳米级时,流动剂载流子在其边界之间发生共振并形成量子阱态(QWS),这对于解释膜的电,输运和磁性能至关重要。除了盒中粒子的经典起源外,QWS还易受影响量子共振的晶体结构的影响。在这里,我们根据第一性原理研究了Fe / Ag / Fe(001)三层中的QWS和磁性层间交换耦合(IEC)。我们发现,布里渊区中心(腹部)和边缘(颈部)的载流子分别形成电子和空穴状的量子态,这些量子态对IEC的振荡特性随银层厚度的增加而变长。短期。由于QWS的形成敏感地取决于边界条件,因此可以通过更改Fe层的厚度在这两个IEC周期之间切换。这些特征(也与其他贵金属间隔层一起出现在磁性三层中)为在磁阻器件中设计IEC开辟了新的自由度。
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