A theoretical modelling of strengthening mechanism in graphene-metal nanolayered composites

IF 5.7 1区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY International Journal of Engineering Science Pub Date : 2023-12-21 DOI:10.1016/j.ijengsci.2023.103988
Xing-wei Chen, Kun-kun Fu, Yan Li
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Abstract

Graphene-metal nanolayered composites (GMNCs) are a new generation of nano-structural composites characterized by a very high density of graphene reinforced interfaces (GRI) between metal nanolayers. Compared to traditional graphene flake reinforced composites, GMNCs have much higher strength, toughness and ductility due to the excellent ability of GRI on constraining dislocation motion and crack propagation. Despite numerous experimental and numerical studies on the mechanical behavior of GMNCs, the underlying strengthening mechanism is still not fully understood due to the absence of appropriate theoretical model. This paper proposes a continuum mechanics based theoretical model to explain the strengthening mechanism in GMNCs. In this model, the metal matrix and the GRI are simulated as homogenous elastic medium of infinite extend and inextensible thin membrane of zero thickness, respectively. Using the theoretical model, two boundary value problems namely (i) A circular prismatic dislocation loop approaching to the GRI and (ii) A mixed mode I/II penny-shaped crack near the GRI are formulated to reveal the two key strengthening mechanism: dislocation blocking and crack shielding, respectively. The two problems are solved analytically by the Generalized Kelvin's Solution (GKS) based method for 3D elasticity and Fredholm integral integration technique. Exact closed form solution for the Peach-Koehler (P-K) force on the dislocation loop is obtained. An efficient numerical scheme is developed to solve the Fredholm integral integration for the crack problem with very high accuracy. It is shown that our theoretical model can well capture and explain the strengthening mechanism observed in experiments. Moreover, the dominant role of Poisson's ratio on the strengthening efficiency is also revealed by our model. This finding implies the exciting possibility that the strength of GMNCs can be tailored by controlling the Poisson's ratio of the metal matrix. The present theoretical modeling can provide valuable insights into the mechanics-based design of GMNCs.

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石墨烯-金属纳米层复合材料强化机理的理论建模
石墨烯-金属纳米层复合材料(GMNCs)是新一代纳米结构复合材料,其特点是金属纳米层之间的石墨烯增强界面(GRI)密度非常高。与传统的片状石墨烯增强复合材料相比,GMNCs 具有更高的强度、韧性和延展性,这得益于 GRI 在限制位错运动和裂纹扩展方面的卓越能力。尽管对 GMNCs 的力学行为进行了大量实验和数值研究,但由于缺乏适当的理论模型,人们对其潜在的强化机制仍未完全了解。本文提出了一种基于连续介质力学的理论模型来解释 GMNCs 的强化机制。在该模型中,金属基体和 GRI 分别被模拟为无限延伸的均质弹性介质和厚度为零的不可拉伸薄膜。利用该理论模型,提出了两个边界值问题:(i) 接近 GRI 的圆形棱柱位错环;(ii) GRI 附近的 I/II 模式混合便士形裂纹,分别揭示了两个关键的强化机制:位错阻挡和裂纹屏蔽。这两个问题采用基于广义开尔文解法(GKS)的三维弹性方法和弗雷德霍姆积分技术进行分析求解。得到了位错环上 Peach-Koehler (P-K) 力的精确闭式解。开发了一种高效的数值方案,可以非常精确地求解裂缝问题的弗雷德霍姆积分。结果表明,我们的理论模型可以很好地捕捉和解释实验中观察到的强化机制。此外,我们的模型还揭示了泊松比对强化效率的主导作用。这一发现意味着一种令人兴奋的可能性,即可以通过控制金属基体的泊松比来定制 GMNC 的强度。本理论模型可为基于力学的 GMNC 设计提供有价值的见解。
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来源期刊
International Journal of Engineering Science
International Journal of Engineering Science 工程技术-工程:综合
CiteScore
11.80
自引率
16.70%
发文量
86
审稿时长
45 days
期刊介绍: The International Journal of Engineering Science is not limited to a specific aspect of science and engineering but is instead devoted to a wide range of subfields in the engineering sciences. While it encourages a broad spectrum of contribution in the engineering sciences, its core interest lies in issues concerning material modeling and response. Articles of interdisciplinary nature are particularly welcome. The primary goal of the new editors is to maintain high quality of publications. There will be a commitment to expediting the time taken for the publication of the papers. The articles that are sent for reviews will have names of the authors deleted with a view towards enhancing the objectivity and fairness of the review process. Articles that are devoted to the purely mathematical aspects without a discussion of the physical implications of the results or the consideration of specific examples are discouraged. Articles concerning material science should not be limited merely to a description and recording of observations but should contain theoretical or quantitative discussion of the results.
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