Cu2N/Cu(100) 上铁原子的电子和磁性第一性原理研究

arXiv - PHYS - Materials Science Pub Date : 2024-09-12 DOI:arxiv-2409.07739

Jiale Chen, Jun Hu

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摘要

我们通过第一性原理计算研究了单个铁原子和铁二聚体在 Cu2N/Cu(100)上的结构、电子和磁性能。在 Cu2N/Cu(100)上吸附一个铁原子后，会形成牢固的铁键，从而在表面 Cu2N 层中形成单个铁原子和铁二聚体。铁-3d 轨道的部分占据导致铁原子的自旋矩很大。有趣的是，单个铁原子和铁二聚体都表现出平面内的磁各向异性，铁二聚体的磁各向异性能（MAE）超过单个铁原子的两倍。这种磁各向异性可归因于自旋轨道耦合哈密顿的 x 方向分量的主要贡献。此外，Fe-Cu 二聚体的形成可能会进一步增强磁各向异性，因为 Fe-3d 轨道的能级受到 Cu 原子存在的显著影响。我们的研究表明，揭示磁各向异性的起源对于磁性纳米结构的磁特性工程具有重要意义。

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First-principles study of electronic and magnetic properties of Fe atoms on Cu2N/Cu(100)

First-principles calculations were conducted to investigate the structural, electronic and magnetic properties of single Fe atoms and Fe dimers on Cu2N/Cu(100). Upon adsorption of an Fe atom onto Cu2N/Cu(100), robust Fe-N bonds form, resulting in the incorporation of both single Fe atoms and Fe dimers within the surface Cu2N layer. The partial occupancy of Fe-3d orbitals lead to large spin moments on the Fe atoms. Interestingly, both single Fe atoms and Fe dimers exhibit in-plane magnetic anisotropy, with the magnetic anisotropy energy (MAE) of an Fe dimer exceeding twice that of a single Fe atom. This magnetic anisotropy can be attributed to the predominant contribution of the component along the x direction of the spin-orbital coupling Hamiltonian. Additionally, the formation of Fe-Cu dimers may further boost the magnetic anisotropy, as the energy levels of the Fe-3d orbitals are remarkably influenced by the presence of Cu atoms. Our study manifests the significance of uncovering the origin of magnetic anisotropy in engineering the magnetic properties of magnetic nanostructures.

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arXiv - PHYS - Materials Science

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