Thermal conductivity in one-dimensional nonlinear disordered lattices: two kinds of scattering effects of hard-type and soft-type anharmonicities

IF 2.2 3区物理与天体物理 Q2 MECHANICS

Journal of Statistical Mechanics: Theory and Experiment Pub Date : 2024-05-27 DOI:10.1088/1742-5468/ad4025

Jianjin Wang, Chi Xiong and Daxing Xiong

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引用次数: 0

Abstract

Amorphous solids can be theoretically modeled by anharmonic disordered lattices, but most of the theoretical studies on thermal conductivity in such lattices only consider hard-type (HT) anharmonicity. In this study, we investigate the thermal conductivity κ of one-dimensional disordered lattices with both HT and soft-type (ST) anharmonic on-site potentials. Our results from molecular dynamics simulations and the quasi-harmonic Green–Kubo (QHGK) method show that while the HT model exhibits non-monotonic dependence of κ on anharmonicity, the ST model shows a monotonically increasing trend. This trend provides a novel approach to enhancing thermal conductivity in disordered systems. Additionally, the QHGK predictions for κ in the HT model are consistent with simulation results over a wide range of anharmonicity values; however, for the ST model, deviations appear as the anharmonicity becomes softer. This peculiar feature may be attributed to delocalization effects being dominant in contrast to the competing roles played by both delocalization and localization effects observed in the HT model.

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一维非线性无序晶格中的导热性：硬型和软型非谐波的两种散射效应

无定形固体可以通过非谐波无序晶格进行理论建模，但有关此类晶格导热性的理论研究大多只考虑了硬型（HT）非谐波性。在本研究中，我们研究了同时具有 HT 和软型（ST）非谐现场势的一维无序晶格的热导率 κ。我们通过分子动力学模拟和准谐波格林-库勃（QHGK）方法得出的结果表明，HT 模型的κ与非谐波性呈现非单调依赖关系，而 ST 模型则呈现单调上升趋势。这种趋势为提高无序系统的热导率提供了一种新方法。此外，HT 模型中 QHGK 对 κ 的预测在很大的非谐波值范围内与模拟结果一致；然而，对于 ST 模型，当非谐波变得更柔和时就会出现偏差。这一奇特的特征可能是由于脱局域效应占主导地位，而在 HT 模型中则观察到脱局域效应和局域效应同时发挥作用。

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

Journal of Statistical Mechanics: Theory and Experiment 物理-力学

CiteScore

4.50

自引率

12.50%

发文量

210

审稿时长

1.0 months

期刊介绍： JSTAT is targeted to a broad community interested in different aspects of statistical physics, which are roughly defined by the fields represented in the conferences called ''Statistical Physics''. Submissions from experimentalists working on all the topics which have some ''connection to statistical physics are also strongly encouraged. The journal covers different topics which correspond to the following keyword sections. 1. Quantum statistical physics, condensed matter, integrable systems Scientific Directors: Eduardo Fradkin and Giuseppe Mussardo 2. Classical statistical mechanics, equilibrium and non-equilibrium Scientific Directors: David Mukamel, Matteo Marsili and Giuseppe Mussardo 3. Disordered systems, classical and quantum Scientific Directors: Eduardo Fradkin and Riccardo Zecchina 4. Interdisciplinary statistical mechanics Scientific Directors: Matteo Marsili and Riccardo Zecchina 5. Biological modelling and information Scientific Directors: Matteo Marsili, William Bialek and Riccardo Zecchina