交换相互作用和磁力定理

I. Solovyev
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引用次数: 11

摘要

我们批判性地重新审视了原子间交换相互作用的问题,它描述了由接近某些平衡状态的自旋的无穷小旋转引起的总能量变化。对于较小的变化,这种相互作用总是与响应函数相关。然而,这种关系的形式可以依赖于额外的近似。特别是,常用的磁力定理(MFT)规定了交换相互作用与响应函数之间的线性关系,而精确的理论要求这种依赖关系是逆的。我们探讨了这些不同定义的起源和后果:铁磁性Ni,反铁磁性NiO,半金属CrO2,多铁性HoMnO3,层状磁体CrCl3和CrI3。虽然在大多数情况下,MFT产生相当合理的结果,并且可以在长波长和强耦合限制下严格证明,但确切的公式似乎更加一致,特别是在处理两个重要问题时,这两个问题通常出现在交换相互作用理论中:(i)配体状态的处理,(ii)选择合适的变量来描述自旋的无穷小旋转。采用绝热自旋动力学的思想,辅以交换相互作用的精确表达式,可以有效地解决这两个问题。特别是,我们提出了一种简单的“下折叠”方法,通过将配体自旋的影响转移到局域自旋之间的相互作用参数来消除配体自旋。此外,我们认为自旋矩的旋转更适合于描述低能激发,而整个磁化矩阵的旋转在自旋系统中引起更强的扰动。
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Exchange interactions and magnetic force theorem
We critically reexamine the problem of interatomic exchange interactions, which describe the total energy change caused by infinitesimal rotations of spins near some equilibrium state. For the small variations, such interactions can be always related to the response function. However, the form of this relation can depend on additional approximations. Particularly, the commonly used magnetic force theorem (MFT) prescribes the linear relation between the exchange interactions and the response function, while the exact theory requires this dependence to be inverse. We explore the origin and consequences of these differences in the definition for the wide class of materials: ferromagnetic Ni, antiferromagnetic NiO, half-metallic CrO2, multiferroic HoMnO3, and layered magnets CrCl3 and CrI3. While in most of these cases, MFT produces quite reasonable results and can be rigorously justifies in the long wavelength and strong-coupling limits, the exact formulation appears to be more consistent, especially in dealing with two important issues, which typically arise in the theory of exchange interactions: (i) the treatment of the ligand states, and (ii) the choice of the suitable variable for the description of infinitesimal rotations of spins. Both issues can be efficiently resolved by employing the ideas of adiabatic spin dynamics supplemented with the exact expression for the exchange interactions. Particularly, we propose a simple "downfolding" procedure for the elimination of the ligand spins by transferring their effect to the interaction parameters between the localized spins. Furthermore, we argue that the rotations of spin moments are more suitable for the description of low-energy excitations, while the rotations of the whole magnetization matrix cause much stronger perturbation in the system of spins.
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