NH$_4$I、NH$_4$Br 和 NH$_4$Cl 中铵阳离子的磁有序性

arXiv - PHYS - Other Condensed Matter Pub Date : 2024-05-06 DOI:arxiv-2405.03163

Fei Yen, Lei Meng, Tian Gao, Sixia Hu

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摘要

不同类型的磁性主要源于电子如何移动和相互影响。在这项研究中，我们展示了质子（H$^+$）也如何表现出磁性。我们测量了卤化铵的磁感应强度，发现 NH$_4$I、NH$_4$Br 和 NH$_4$Cl 分别在 232 K、233 K 和 243 K 时磁感应强度明显增加，这都与铵阳离子的几何排序相吻合。大量文献证实，铵阳离子在最低温度下会出现旋转运动，我们考虑到质子的轨道运动带有磁矩，并发现其磁矩大于成对电子的磁矩。因此，结构相变是由磁力驱动的，因为系统试图通过扬-泰勒畸变来解除质子轨道的 8 倍能量退变性。我们的研究结果表明，NH$_4$$^+$ 阳离子能够产生磁性，而这种磁性在氨基分子固体中似乎无处不在。

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Magnetic Ordering of Ammonium Cations in NH$_4$I, NH$_4$Br and NH$_4$Cl

The different types of magnetism arise mainly from how electrons move and interact with each other. In this work, we show how protons (H$^+$) also exhibit magnetic behavior. We measured the magnetic susceptibility of the ammonium halides and identified pronounced increases at 232 K, 233 K and 243 K for NH$_4$I, NH$_4$Br and NH$_4$Cl, respectively, which all coincide to the geometric ordering of its ammonium cations. With extensive literature establishing the fact that the ammonium cations exhibit rotational motion even towards the lowest temperatures, we take into account that the orbital motion of the protons carries a magnetic moment and find it to be larger than that of the paired electrons. Consequently, the structural phase transitions are magnetically-driven as the system attempts to lift 8-fold energy degeneracies of the proton orbitals via Jahn-Teller distortions. Our findings identify that NH$_4$$^+$ cations are capable of comprising magnetism which appears to be ubiquitous in ammonia-based molecular solids.

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arXiv - PHYS - Other Condensed Matter

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