Spin wave excitations in low dimensional systems with large magnetic anisotropy

Fernando Delgado, Mikhail M Otrokov and Andrés Arnau
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Abstract

The low-energy excitation spectrum of a two-dimensional ferromagnetic material is dominated by single-magnon excitations that show a gapless parabolic dispersion relation with the spin wave vector. This occurs as long as magnetic anisotropy and anisotropic exchange are negligible compared to isotropic exchange. However, to maintain magnetic order at finite temperatures in extended systems, it is necessary to have sizable anisotropy to open a gap in the spin wave excitation spectrum. We consider four real two-dimensional systems for which ferromagnetic order at finite temperature has been observed or predicted. Density functional theory calculations of the total energy differences for different spin configurations permit us to extract the relevant parameters and connect them with a spin Hamiltonian. The corresponding values of the Curie temperature are estimated using a simple model and found to be mostly determined by the value of the isotropic exchange. The exchange and anisotropy parameters are used in a toy model of finite-size periodic chains to study the low-energy excitation spectrum, including single-magnon and two-magnon excitations. At low energies, we find that single-magnon excitations appear in the spectrum together with two-magnon excitations. These excitations present a gap that grows particularly for large values of the magnetic anisotropy or anisotropic exchange, relative to the isotropic exchange.
具有大磁各向异性的低维系统中的自旋波激发
二维铁磁材料的低能激发光谱以单磁子激发为主,单磁子激发与自旋波矢量呈无间隙抛物线色散关系。只要磁各向异性和各向异性交换与各向同性交换相比可以忽略不计,就会出现这种情况。然而,要在有限温度下维持扩展系统的磁秩序,就必须有相当大的各向异性,以便在自旋波激发谱中打开一个缺口。我们考虑了已观察到或预测到有限温度下铁磁秩序的四个真实二维系统。通过密度泛函理论计算不同自旋构型的总能量差,我们可以提取相关参数,并将它们与自旋哈密顿联系起来。我们使用一个简单的模型估算了居里温度的相应值,发现它主要由各向同性交换值决定。交换和各向异性参数被用于有限大小周期链的玩具模型中,以研究低能激发谱,包括单磁子激射和双磁子激射。我们发现,在低能情况下,频谱中会出现单磁子激射和双磁子激射。相对于各向同性交换,这些激发出现的间隙在磁各向异性或各向异性交换值较大时尤其明显。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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