Switching the Magnetization in Quantum Antiferromagnets

IF 11 Q1 PHYSICS, APPLIED

PRX quantum : a Physical Review journal Pub Date : 2023-03-27 DOI:10.1103/prxquantum.4.030332

K. Bolsmann, Asliddin Khudoyberdiev, G. Uhrig

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Abstract

The orientation of the order parameter of quantum magnets can be used to store information in a dense and efficient way. Switching this order parameter corresponds to writing data. To understand how this can be done, we study a precessional reorientation of the sublattice magnetization in an (an)isotropic quantum antiferromagnet induced by an applied magnetic field. We use a description including the leading quantum and thermal fluctuations, namely Schwinger boson mean-field theory, because this theory allows us to describe both ordered phases and the phases in between them, as is crucial for switching. An activation energy has to be overcome requiring a minimum applied field $h_\text{t}$ which is given essentially by the spin gap. It can be reduced significantly for temperatures approaching the N\'eel temperature facilitating switching. The time required for switching diverges when the field approaches $h_\text{t}$ which is the signature of an inertia in the magnetization dynamics. The temporal evolution of the magnetization and of the energy reveals signs of dephasing. The switched state has lost a part of its coherence because the magnetic modes do not evolve in phase.

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量子反铁磁体的磁化开关

利用量子磁体序参量的取向，可以高密度、高效地存储信息。切换该顺序参数对应写数据。为了理解这是如何做到的，我们研究了由外加磁场诱导的各向同性量子反铁磁体中亚晶格磁化的进动重定向。我们使用的描述包括领先的量子和热涨落，即施温格玻色子平均场理论，因为这个理论允许我们描述有序相和它们之间的相，这对开关是至关重要的。要克服活化能需要一个最小的作用场，这个最小的作用场基本上是由自旋间隙给出的。当温度接近于N\ eel温度时，可以显著降低开关温度。当磁场接近$h_\text{t}$时，开关所需的时间发散，这是磁化动力学中惯性的标志。磁化强度和能量的时间演化显示出消相的迹象。开关态失去了一部分相干性，因为磁模不同步演化。

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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来源期刊

PRX quantum : a Physical Review journal

CiteScore

14.60

自引率

0.00%

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