Multiscale modelling of precipitation hardening: a review

Aiya Cui, Xiaoming Wang, Yinan Cui
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Abstract

Precipitation hardening, a cornerstone of alloy strengthening, finds widespread application in engineering materials. Comprehending the underlying mechanisms and formulating models bear crucial significance for engineering applications. While classical macroscopic theoretical models based on the line tension model have historically guided research efforts, their reliance on simplifications, assumptions, and parameter adjustments limits their predictability and expansibility. Moreover, the challenge of understanding the intricate coupling effects among various hardening mechanisms persists. One fundamental question to achieve the transition of material design paradigms from empirical trial-and-error methods to predictive-and-design approaches is to develop more physics-based multiscale modelling methods. This review aims to elucidate the physical mechanisms governing precipitation hardening and establish a tailored bottom-up multiscale modelling framework to steer the design of new alloys. The physical scenarios of precipitation hardening are firstly summarized, including particle shearing, Orowan bypass, and dislocation cross-slip and climb. Afterwards, an in-depth discussion is given regarding the application of macroscopic models and their correlation with the mechanisms and precipitation characteristics. As for the multiscale modelling methods, we categorize them into three main types: slip resistance based approaches, misfit stress field based approaches, and energy based approaches. By integrating multiscale modelling with the physical scenarios, we systematically addressed the key idea of the multiscale coupling framework, and their scale transfer procedure, applicability, advantages, and limitations. Some examples of coupling different types of multiscale methods and considering precipitates with complicated shapes are also presented. This study not only furnishes insightful comprehension of precipitation hardening, but also guides the development of multiscale modelling methodologies for other types of hardening effects in alloys.

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沉淀硬化的多尺度建模:综述
沉淀硬化是合金强化的基石,在工程材料中得到广泛应用。了解其基本机理并建立模型对工程应用至关重要。虽然基于线拉伸模型的经典宏观理论模型历来指导着研究工作,但它们对简化、假设和参数调整的依赖限制了其可预测性和扩展性。此外,如何理解各种硬化机制之间错综复杂的耦合效应仍然是一项挑战。要实现材料设计范式从经验性试错方法向预测性设计方法的转变,一个基本问题是开发更多基于物理学的多尺度建模方法。本综述旨在阐明沉淀硬化的物理机制,并建立一个量身定制的自下而上的多尺度建模框架,以指导新型合金的设计。首先概述了沉淀硬化的物理情景,包括颗粒剪切、奥罗凡旁路、位错交叉滑移和攀升。随后,深入讨论了宏观模型的应用及其与机理和析出特征的相关性。至于多尺度建模方法,我们将其分为三大类:基于滑移阻力的方法、基于错配应力场的方法和基于能量的方法。通过将多尺度建模与物理情景相结合,我们系统地探讨了多尺度耦合框架的主要思想,以及它们的尺度转移程序、适用性、优势和局限性。此外,还介绍了耦合不同类型多尺度方法和考虑复杂形状沉淀物的一些实例。这项研究不仅能深入理解沉淀硬化,还能指导针对合金中其他类型硬化效应的多尺度建模方法的开发。
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期刊介绍: Journal of Materials Science: Materials Theory publishes all areas of theoretical materials science and related computational methods. The scope covers mechanical, physical and chemical problems in metals and alloys, ceramics, polymers, functional and biological materials at all scales and addresses the structure, synthesis and properties of materials. Proposing novel theoretical concepts, models, and/or mathematical and computational formalisms to advance state-of-the-art technology is critical for submission to the Journal of Materials Science: Materials Theory. The journal highly encourages contributions focusing on data-driven research, materials informatics, and the integration of theory and data analysis as new ways to predict, design, and conceptualize materials behavior.
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