Extension operators and Korn inequality for variable coefficients in perforated domains with applications to homogenization of viscoelastic non-simple materials

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Markus Gahn
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Abstract

In this paper we present the homogenization for nonlinear viscoelastic second-grade non-simple perforated materials at large strain in the quasistatic setting. The reference domain \(\Omega _{\varepsilon }\) is periodically perforated and is depending on the scaling parameter \(\varepsilon \) which describes the ratio between the size of the whole domain and the small periodic perforations. The mechanical energy depends on the gradient and also the second gradient of the deformation, and also respects positivity of the determinant of the deformation gradient. For the viscous stress we assume dynamic frame indifference and it is therefore depending on the rate of the Cauchy-stress tensor. For the derivation of the homogenized model for \(\varepsilon \rightarrow 0\) we use the method of two-scale convergence. For this uniform a priori estimates with respect to \(\varepsilon \) are necessary. The most crucial part is to estimate the rate of the deformation gradient. Due to the time-dependent frame indifference of the viscous term, we only get coercivity with respect to the rate of the Cauchy-stress tensor. To overcome this problem we derive a Korn inequality for non-constant coefficients on the perforated domain. The crucial point is to verify that the constant in this inequality, which is usually depending on the domain, can be chosen independently of the parameter \(\varepsilon \). Further, we construct an extension operator for second order Sobolev spaces on perforated domains with operator norm independent of \(\varepsilon \).

穿孔域中可变系数的扩展算子和科恩不等式及其在粘弹性非简单材料均质化中的应用
在本文中,我们介绍了准静态设置下大应变非线性粘弹性二级非简单穿孔材料的均质化。参考域\(\Omega _{\varepsilon }\) 是周期性穿孔的,并且取决于比例参数\(\varepsilon \),该参数描述了整个域的大小与小周期性穿孔之间的比率。机械能取决于变形的梯度和第二梯度,同时也尊重变形梯度行列式的正向性。对于粘性应力,我们假设动态框架无差别,因此它取决于考奇应力张量的速率。对于 \(\varepsilon \rightarrow 0\) 均质模型的推导,我们使用了双尺度收敛法。为此,关于 \(\varepsilon\) 的统一的先验估计是必要的。最关键的部分是估计变形梯度的速率。由于粘性项与时间相关的框架无关性,我们只能得到与考奇应力张量速率相关的矫顽力。为了克服这个问题,我们推导出了穿孔域上非常数系数的科恩不等式。关键是要验证这个不等式中的常数(通常取决于域)可以独立于参数 \(\varepsilon \)而选择。此外,我们还为穿孔域上的二阶索波列夫空间构造了一个扩展算子,其算子规范与 \(\varepsilon \) 无关。
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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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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