基于自适应高斯过程代理模型的梯度纳米孪晶金属材料设计

Haofei Zhou, Xin Chen, Yumeng Li
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引用次数: 0

摘要

受自然界梯度结构的启发,梯度纳米结构(GNS)金属已成为一类具有可调微结构的新型材料。GNS金属在超高强度、良好的拉伸延展性和增强的应变硬化、优异的疲劳和耐磨性方面表现出独特的材料性能组合。然而,充分了解梯度结构-性能的基本关系仍然是一个挑战,这阻碍了合理设计具有优化目标性能的GNS金属。在本文中,我们开发了一个基于模拟代理模型的自适应设计框架,以研究晶粒尺寸梯度和孪晶厚度梯度如何影响GNS金属的强度。采用基于高斯过程的自适应序贯抽样代理建模技术,建立了梯度结构属性关系的代理模型。提出的自适应设计集成了基于物理的仿真、代理建模、不确定性量化和优化,可以有效地探索设计空间,并利用高保真度但计算成本高昂的物理模拟产生的有限采样数据,确定具有最大强度的GNS金属的优化设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design of Gradient Nanotwinned Metal Materials Using Adaptive Gaussian Process Based Surrogate Models
Inspired by gradient structures in the nature, Gradient Nanostructured (GNS) metals have emerged as a new class of materials with tunable microstructures. GNS metals can exhibit unique combinations of material properties in terms of ultrahigh strength, good tensile ductility and enhanced strain hardening, superior fatigue and wear resistance. However, it is still challenging to fully understand the fundamental gradient structure-property relationship, which hinders the rational design of GNS metals with optimized target properties. In this paper, we developed an adaptive design framework based on simulation-based surrogate modeling to investigate how the grain size gradient and twin thickness gradient affect the strength of GNS metals. The Gaussian Process (GP) based surrogate modeling technique with adaptive sequential sampling is employed for the development of surrogate models for the gradient structure-property relationship. The proposed adaptive design integrates physics-based simulation, surrogate modeling, uncertainty quantification and optimization, which can efficiently explore the design space and identify the optimized design of GNS metals with maximum strength using limited sampling data generated from high fidelity but computational expensive physics-based simulations.
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