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研究生: 譚登瑞
Tan, Deng-Ruei
論文名稱: 三維二聚體化自旋二分之一量子反鐵磁之倪耳溫度與交錯磁化密度的普適性比尺關係
Universal scaling of Néel temperature and staggered magnetization density of three dimensional dimerized spin-1/2 quantum antiferromagnets
指導教授: 江府峻
Jiang, Fu-Jiun
學位類別: 博士
Doctor
系所名稱: 物理學系
Department of Physics
論文出版年: 2019
畢業學年度: 108
語文別: 中文
論文頁數: 49
中文關鍵詞: 量子蒙地卡羅反鐵磁海森堡模型
英文關鍵詞: quantum Monte Carlo, antiferromagnet, Heisenberg model
DOI URL: http://doi.org/10.6345/NTNU201901151
論文種類: 學術論文
相關次數: 點閱:192下載:0
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  • 本論文使用蒙地卡羅模擬對三維二聚體化自旋 1/2 反鐵磁海森堡模型做研究計算,其中使用非常有效率的隨機數列展開演算法,並且從適當的物理量和分析方法來計算倪耳溫度 $T_N$、交錯磁化密度 $M_s$ 和 $T^{\star}$。在不同的非無序的三維二聚體化自旋 1/2 海森堡模型中,先前文獻上的理論計算發現了 $T_N$ 和基態的 $M_s$ 存在著 3 個普適性比尺關係,有些也和 $\textrm{TlCuCl}_3$ 的實驗結果相符。這篇論文研究已發現的普適性比尺關係在無序模型上是否成立,並且考慮其他不同的非無序二聚體化海森堡模型。我們的計算結果不但確認普適性比尺關係在無序系統依然成立,還發現其中 2 個普適性比尺關係可以根據晶格點上的自旋與周圍自旋有較強自旋耦合的總數來做分類。

    In this thesis, we use quantum Monte Carlo method to study three-dimensional (3D) spin-1/2 antiferromagnetic Heisenberg models. By employing every efficient algorithm, namely the stochastic series expansion (SSE), we calculate the Néel temperature $T_N$, the staggered magnetization density $M_s$, the spinwave velocity $c$, and $T^{\star}$ of these systems. It is established theoretically that there are three universal scaling relations between $T_N$ and $M_s$ for 3D clean spin models. Particularly, some of the predictions are consistent with the experimental results. Motivated by this, we have simulated 3D quantum spin models with certain kinds of quenched disorder and have found that these three universal scaling relations are valid for disordered systems. Finally, by simulating several clean 3D models, we also show that two of these scaling relations can be classified by the number of strong antiferromagnetic couplings touching a spin.

    章節 1 緒論 1 章節 2 研究方法及模型 4 章節 3 無序模型 8 3.1 第一類模型 9 3.1.1 $\overline{M_s}$ 量測 9 3.1.2 $\overline{T_N}$ 量測 12 3.1.3 $\overline{T^\star}$ 量測 16 3.1.4 $\overline{T_N}$ 和 $\overline{M_s}$ 的比尺關係 16 3.2 組態無序模型 17 3.2.1 $\overline{M_s}$ 量測 19 3.2.2 $\overline{T_N}$ 量測 22 3.2.3 $\overline{c}$ 量測 25 3.2.4 $\overline{T_N}$ 和 $\overline{M_s}$ 的比尺關係 27 章節 4 $T_N$ 和 $M_s$ 的普適性比尺關係分類 31 4.1 晶格的微觀結構 13 4.2 $M_s$ 量測 33 4.3 $T_N$ 量測 35 4.4 $T^\star$ 量測 37 4.5 $T_N$ 和 $M_s$ 的比尺關係 38 章節 5 結論 41 參考文獻 43

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