Discovery of an ultra-quantum spin liquid

arXiv: Strongly Correlated Electrons Pub Date : 2021-04-02 DOI:10.21203/RS.3.RS-351743/V1

Yanxing Yang, Cheng Tan, Zihao Zhu, Jing Zhang, Z. Ding, Qiong Wu, Changshen Chen, T. Shiroka, Douglas MacLaughline, C. Varma, L. Shu

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引用次数: 1

Abstract

Quantum fluctuations are expected to lead to highly entangled spin-liquid states in some two-dimensional spin-1/2 compounds. We have synthesized and measured thermodynamic properties and muon relaxation rates in two related such compounds, one of which is the least disordered of this kind synthesized hitherto and reveals intrinsic properties of a class of spin-liquids. Its measured properties can all be simply characterized by scale invariant time-dependent fluctuations with a single parameter. The specific heat divided by temperature and muon relaxation rates are both temperature independent at low temperatures, followed by a logarithmic decrease with increasing temperature. Even more remarkably, ∼57% of the magnetic entropy is missing down to temperatures of O(10−3) the exchange energy, independent of magnetic field up to gµBH > kBT . This is evidence that quantum fluctuations lead either to a gigantic specific heat peak from topological singlet excitations below such temperatures, or to an extensively degenerate topological singlet ground state. These results reveal an ultra-quantum state of matter.

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超量子自旋液体的发现

量子涨落有望在一些二维自旋1/2化合物中导致高度纠缠的自旋-液态。我们合成并测量了两种相关化合物的热力学性质和介子弛豫率，其中一种是迄今为止合成的这类化合物中无序程度最低的，并揭示了一类自旋液体的内在性质。它的测量性质都可以用单一参数的尺度不变时变波动来简单表征。在低温下，比热除以温度和介子弛豫速率都与温度无关，然后随着温度的升高呈对数递减。更值得注意的是，~ 57%的磁熵在0(10−3)交换能的温度下丢失，与高达gµBH > kBT的磁场无关。这证明量子涨落要么导致在此温度以下的拓扑单线态激发产生巨大的比热峰，要么导致广泛简并的拓扑单线态基态。这些结果揭示了物质的超量子态。

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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arXiv: Strongly Correlated Electrons

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