Micropillar compression using discrete dislocation dynamics and machine learning

IF 3.2 3区 工程技术 Q2 MECHANICS
Jin Tao , Dean Wei , Junshi Yu , Qianhua Kan , Guozheng Kang , Xu Zhang
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Abstract

Discrete dislocation dynamics (DDD) simulations reveal the evolution of dislocation structures and the interaction of dislocations. This study investigated the compression behavior of single-crystal copper micropillars using few-shot machine learning with data provided by DDD simulations. Two types of features are considered: external features comprising specimen size and loading orientation and internal features involving dislocation source length, Schmid factor, the orientation of the most easily activated dislocations and their distance from the free boundary. The yielding stress and stress-strain curves of single-crystal copper micropillar are predicted well by incorporating both external and internal features of the sample as separate or combined inputs. It is found that the Machine learning accuracy predictions for single-crystal micropillar compression can be improved by incorporating easily activated dislocation features with external features. However, the effect of easily activated dislocation on yielding is less important compared to the effects of specimen size and Schmid factor which includes information of orientation but becomes more evident in small-sized micropillars. Overall, incorporating internal features, especially the information of most easily activated dislocations, improves predictive capabilities across diverse sample sizes and orientations.

Abstract Image

利用离散位错动力学和机器学习实现微柱压缩
离散位错动力学(DDD)模拟揭示了位错结构的演变和位错之间的相互作用。本研究利用离散位错动力学模拟提供的数据,通过少镜头机器学习研究了单晶微柱铜的压缩行为。研究考虑了两类特征:外部特征包括试样尺寸和加载方向,内部特征包括位错源长度、Schmid 因子、最易激活位错的方向及其与自由边界的距离。通过将样品的外部和内部特征作为单独或组合输入,可以很好地预测单晶微柱铜的屈服应力和应力应变曲线。研究发现,通过将易激活的位错特征与外部特征相结合,可以提高机器学习对单晶微柱压缩的预测精度。然而,与试样尺寸和施密德因子的影响相比,易激活位错对屈服的影响并不那么重要,因为施密德因子包括取向信息,但在小尺寸微晶柱中更为明显。总之,结合内部特征,特别是最易激活的位错信息,可提高不同试样尺寸和取向的预测能力。
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来源期刊
CiteScore
6.20
自引率
2.90%
发文量
545
审稿时长
12 weeks
期刊介绍: An international journal devoted to rapid communications on novel and original research in the field of mechanics. TAML aims at publishing novel, cutting edge researches in theoretical, computational, and experimental mechanics. The journal provides fast publication of letter-sized articles and invited reviews within 3 months. We emphasize highlighting advances in science, engineering, and technology with originality and rapidity. Contributions include, but are not limited to, a variety of topics such as: • Aerospace and Aeronautical Engineering • Coastal and Ocean Engineering • Environment and Energy Engineering • Material and Structure Engineering • Biomedical Engineering • Mechanical and Transportation Engineering • Civil and Hydraulic Engineering Theoretical and Applied Mechanics Letters (TAML) was launched in 2011 and sponsored by Institute of Mechanics, Chinese Academy of Sciences (IMCAS) and The Chinese Society of Theoretical and Applied Mechanics (CSTAM). It is the official publication the Beijing International Center for Theoretical and Applied Mechanics (BICTAM).
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