Comment to 'Skeletonization-based beam finite element models for stochastic bicontinuous materials: Application to simulations of nanoporous gold' by C. Soyarslan et al. [J. Mater. Res. 33(20), 3371 (2018)]

Norbert Huber; Claudia Richert

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Comment to 'Skeletonization-based beam finite element models for stochastic bicontinuous materials: Application to simulations of nanoporous gold' by C. Soyarslan et al. [J. Mater. Res. 33(20), 3371 (2018)]

机译：对随机双周末材料的基于骨架的梁有限元模型评论：C. Soyarslan等人的应用纳米摩尔金的应用。 [J.母娘。 res。 33（20），3371（2018）]

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Soyarslan et al. [J. Mater. Res. 33(20), 3371 (2018)] proposed a beam-finite element model for the computation of effective elastic properties of nanoporous materials, where the ligament diameter along the skeleton is determined with the biggest sphere algorithm. Although this algorithm Is often used in the literature, it is known that it systematically overestimates the diameter in network structures. Thus, the need for further stiffening of the junction zones as proposed by the authors Is in contradiction to the literature. Furthermore, the factor 40 appears to be one order of magnitude too high. We show that the 3D microstructures generated from random Gaussian fields contain features that are violating the assumption of circular cross-sections and, therefore, cannot be captured by the biggest sphere algorithm. Consequently, the authors required an unphysically high value of 40 to compensate this hidden effect.

机译：Soyarslan等人。 [J.母娘。 res。 33（20），3371（2018）]提出了一种用于计算纳米多孔材料的有效弹性特性的束有限元模型，其中沿骨架的韧带直径用最大的球体算法确定。虽然该算法通常用于文献中，但是已知它系统地高估了网络结构中的直径。因此，根据作者提出的接合区进一步加强的需要与文献相矛盾。此外，因子40似乎是一个级别过高。我们表明，从随机高斯字段产生的3D微结构包含违反圆形横截面的假设的特征，因此不能通过最大的球体算法捕获。因此，作者需要一个不受神经的高值40来补偿这种隐藏效果。

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来源
《Journal of Materials Research》 |2020年第20期|2831-2834|共4页
作者
Norbert Huber; Claudia Richert;
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作者单位

Institute of Materials Research Materials Mechanics Helmholtz-Zentrum Geesthacht Max-Planck-Str. 1 21502 Geesthacht Germany Institute of Materials Physics and Technology Hamburg University of Technology Eissendorfer Str. 42 21073 Hamburg Germany;

Institute of Materials Research Materials Mechanics Helmholtz-Zentrum Geesthacht Max-Planck-Str. 1 21502 Geesthacht Germany;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);
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Comment to 'Skeletonization-based beam finite element models for stochastic bicontinuous materials: Application to simulations of nanoporous gold' by C. Soyarslan et al. [J. Mater. Res. 33(20), 3371 (2018)]

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