Molecular dynamics prediction of phonon-mediated thermal conductivity of f.c.c. Cu

IF 1.5 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Philosophical Magazine Pub Date : 2014-02-21 DOI:10.1080/14786435.2013.861090

A. Evteev, Leila Momenzadeh, E. Levchenko, I. Belova, G. Murch

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引用次数: 20

Abstract

The phonon-mediated thermal conductivity of f.c.c. Cu is investigated in detail in the temperature range 40–1300 K. The calculations are performed in the framework of equilibrium molecular dynamics making use of the Green–Kubo formalism and one of the most reliable embedded-atom method potentials for Cu. It is found that the temporal decay of the heat current autocorrelation function (HCACF) of the Cu model at low and intermediate temperatures demonstrate a more complex behaviour than the two-stage decay observed previously for the f.c.c. Ar model. After the first stage of decay, it demonstrates a peak in the temperature range 40–800 K. A decomposition model of the HCACF is introduced. In the framework of that model we demonstrate that a classical description of the phonon thermal transport in the Cu model can be used down to around one quarter of the Debye temperature (about 90 K). Also, we find that above 300 K the thermal conductivity of the Cu model varies with temperature more rapidly than , following an exponent close to −1.4 in agreement with previous calculations on the Ar model. Phonon thermal conductivity of Cu is found to be about one order of magnitude higher than Ar. The phonon contribution to the total thermal conductivity of Cu can be estimated to be about 0.5% at 1300 K and about 10% at 90 K.

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声子介导的氟氯化铜热导率的分子动力学预测

在40 ~ 1300 K的温度范围内，详细研究了氟化铜的声子介导热导率。计算是在平衡分子动力学的框架下进行的，利用Green-Kubo形式和Cu最可靠的嵌入原子方法势之一。发现Cu模型的热流自相关函数(HCACF)在低温和中温下的时间衰减比之前在fcc . Ar模型中观察到的两阶段衰减表现出更复杂的行为。经过第一阶段的衰变后，在40-800 K的温度范围内出现峰值。介绍了HCACF的分解模型。在该模型的框架内，我们证明了Cu模型中声子热输运的经典描述可以低至德拜温度(约90 K)的四分之一左右。此外，我们发现，在300 K以上，Cu模型的导热系数随温度变化的速度比接近- 1.4的指数更快，这与之前在Ar模型上的计算一致。Cu的声子热导率比Ar高一个数量级。在1300 K时，声子对Cu总热导率的贡献约为0.5%，在90 K时约为10%。

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

Philosophical Magazine 工程技术-材料科学：综合

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0.00%

发文量

审稿时长

4.7 months

期刊介绍： The Editors of Philosophical Magazine consider for publication contributions describing original experimental and theoretical results, computational simulations and concepts relating to the structure and properties of condensed matter. The submission of papers on novel measurements, phases, phenomena, and new types of material is encouraged.