Structure, control, and dynamics of altermagnetic textures

npj Spintronics Pub Date : 2024-07-25 DOI:10.1038/s44306-024-00042-3

O. Gomonay, V. P. Kravchuk, R. Jaeschke-Ubiergo, K. V. Yershov, T. Jungwirth, L. Šmejkal, J. van den Brink, J. Sinova

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Abstract

We present a phenomenological theory of altermagnets, that captures their unique magnetization dynamics and allows modeling magnetic textures in this new magnetic phase. Focusing on the prototypical d-wave altermagnets, e.g., RuO2, we can explain intuitively the characteristic lifted degeneracy of their magnon spectra, by the emergence of an effective sublattice-dependent anisotropic spin stiffness arising naturally from the phenomenological theory. We show that as a consequence the altermagnetic domain walls, in contrast to antiferromagnets, have a finite gradient of the magnetization, with its strength and gradient direction connected to the altermagnetic anisotropy, even for 180° domain walls. This gradient generates a ponderomotive force in the domain wall in the presence of a strongly inhomogeneous external magnetic field, which may be achieved through magnetic force microscopy techniques. The motion of these altermagentic domain walls is also characterized by an anisotropic Walker breakdown, with much higher speed limits of propagation than ferromagnets but lower than antiferromagnets.

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改磁纹理的结构、控制和动态变化

我们提出了一种关于变磁体的现象学理论，它捕捉到了变磁体独特的磁化动态，并能对这种新磁相的磁纹理进行建模。通过现象学理论中自然产生的依赖于亚晶格的有效各向异性自旋刚度的出现，我们可以直观地解释典型的 d 波变磁体（如 RuO2）磁子谱的提升变性特征。我们的研究表明，与反铁磁体相反，改磁畴壁具有有限的磁化梯度，其强度和梯度方向与改磁各向异性相关，即使是 180° 的畴壁也是如此。在强不均匀外磁场的作用下，这种梯度会在畴壁中产生思动力，这可以通过磁力显微镜技术来实现。这些变磁性畴壁的运动特征也是各向异性的沃克击穿，其传播速度极限远高于铁磁体，但低于反铁磁体。

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npj Spintronics

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