Polycrystal plasticity and grain boundary evolution: A unified dislocation-based diffuse-interface approach

arXiv: Materials Science Pub Date : 2021-02-01 DOI:10.13140/RG.2.2.28625.45923

Junyang He, N. Admal

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Abstract

Grain structure plays a key role in the mechanical properties of alloy materials. Engineering the grain structure requires a comprehensive understanding of the evolution of grain boundaries (GBs) when a material is subjected to various manufacturing processes. To this end, we present a computationally efficient framework to describe the co-evolution of bulk plasticity and GBs. We represent GBs as diffused geometrically necessary dislocations, whose evolution describes GB plasticity. Under this representation, the evolution of GBs and bulk plasticity can be described in unison using the evolution equation for the plastic deformation gradient, an equation central to classical crystal plasticity theories. In addition, we outline a method to introduce a synthetic potential to drive migration of a flat GB within our diffuse-interface framework. We validate the framework by simulating the evolution of a triple junction, and demonstrate its computational efficiency. We further leverage this framework to study the migration of a flat GB driven by a potential difference, subject to different sets of available slip systems and mechanical boundary conditions.

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多晶塑性和晶界演化:基于位错的扩散界面方法

晶粒组织对合金材料的力学性能起着关键作用。工程晶粒结构需要对晶界(GBs)的演变有全面的了解，当材料受到各种制造工艺。为此，我们提出了一个计算效率高的框架来描述体塑性和gb的共同演化。我们将GB表示为扩散的几何必要位错，其演化描述了GB塑性。在这种表示下，可以用塑性变形梯度演化方程(经典晶体塑性理论的核心方程)来统一描述GBs和体塑性的演化。此外，我们还概述了一种方法，该方法引入了一种综合潜力，以在我们的扩散接口框架内驱动平面GB的迁移。我们通过模拟三结点的演化来验证该框架，并证明了其计算效率。我们进一步利用这一框架来研究由电位差驱动的平面GB的迁移，受不同可用滑移系统和机械边界条件的影响。

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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arXiv: Materials Science

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