Formulation and calibration of higher-order elastic localization relationships using the MKS approach

Abstract Localization (as opposed to homogenization) describes the spatial distribution of the response field of interest at the microscale for an imposed loading condition at the macroscale. A novel approach called Materials Knowledge Systems (MKS) has recently been formulated to construct accurate, bidirectional, microstructure–property–processing linkages in hierarchical material systems to facilitate computationally efficient multiscale modeling and simulation. This approach is built on the statistical continuum theories developed by Kroner that express the localization of the response field at the microscale using a series of highly complex convolution integrals, which have historically been evaluated analytically. The MKS approach dramatically improves the accuracy of these expressions by calibrating the convolution kernels in these expressions to results from previously validated physics-based models. All of the prior work in the MKS framework has thus far focused on calibration and validation of the first-order terms in the localization relationships. In this paper, we explore, for the first time, the calibration and validation of the higher-order terms in the localization relationships. In particular, it is demonstrated that the higher-order terms in the localization relationships play an increasingly important role in the spatial distribution of elastic stress or strain fields at the microscale in composite systems with relatively high contrast.

[1]  Y. W. Lee,et al.  Measurement of the Wiener Kernels of a Non-linear System by Cross-correlation† , 1965 .

[2]  S. Ahzi,et al.  Statistical continuum theory for large plastic deformation of polycrystalline materials , 2001 .

[3]  H. Garmestani,et al.  Statistical continuum theory for inelastic behavior of a two-phase medium , 1998 .

[4]  Salvatore Torquato,et al.  Effective electrical conductivity of two‐phase disordered composite media , 1985 .

[5]  Surya R. Kalidindi,et al.  A new framework for computationally efficient structure–structure evolution linkages to facilitate high-fidelity scale bridging in multi-scale materials models , 2011 .

[6]  Surya R. Kalidindi,et al.  Multi-scale modeling of elastic response of three-dimensional voxel-based microstructure datasets using novel DFT-based knowledge systems , 2010 .

[7]  N. Wiener,et al.  Nonlinear Problems in Random Theory , 1964 .

[8]  Tien C. Hsia,et al.  System identification: Least-squares methods , 1977 .

[9]  Brent L. Adams,et al.  Bounding elastic constants of an orthotropic polycrystal using measurements of the microstructure , 1996 .

[10]  S. Kalidindi,et al.  Finite approximations to the second-order properties closure in single phase polycrystals , 2005 .

[11]  Kevin Skadron,et al.  Scalable parallel programming , 2008, 2008 IEEE Hot Chips 20 Symposium (HCS).

[12]  D. Fullwood,et al.  Optimized structure based representative volume element sets reflecting the ensemble-averaged 2-point statistics , 2010 .

[13]  Salvatore Torquato,et al.  Effective stiffness tensor of composite media—I. Exact series expansions , 1997 .

[14]  John Hinde,et al.  Statistical Modelling in R , 2009 .

[15]  I. Hunter,et al.  The identification of nonlinear biological systems: Volterra kernel approaches , 1996, Annals of Biomedical Engineering.

[16]  G. Milton The Theory of Composites , 2002 .

[17]  David T. Fullwood,et al.  Spectral representation of higher-order localization relationships for elastic behavior of polycrystalline cubic materials , 2008 .

[18]  L. Tong,et al.  Multichannel blind identification: from subspace to maximum likelihood methods , 1998, Proc. IEEE.

[19]  Gary G. R. Green,et al.  Calculation of the Volterra kernels of non-linear dynamic systems using an artificial neural network , 1994, Biological Cybernetics.

[20]  E. Kröner Bounds for effective elastic moduli of disordered materials , 1977 .

[21]  J. A. Cherry,et al.  Distortion Analysis of Weakly Nonlinear Filters Using Volterra Series , 1994 .

[22]  Barry D. Van Veen,et al.  Blind equalization and identification of nonlinear and IIR systems-a least squares approach , 2000, IEEE Trans. Signal Process..

[23]  William Fuller Brown,et al.  Solid Mixture Permittivities , 1955 .

[24]  H. Garmestani,et al.  Statistical continuum mechanics analysis of an elastic two-isotropic-phase composite material , 2000 .

[25]  Joseph Zarka,et al.  Modelling small deformations of polycrystals , 1986 .

[26]  David T. Fullwood,et al.  A strong contrast homogenization formulation for multi-phase anisotropic materials , 2008 .

[27]  Mark J. Beran,et al.  Statistical Continuum Theories , 1965 .

[28]  Vito Volterra,et al.  Theory of Functionals and of Integral and Integro-Differential Equations , 2005 .

[29]  T. A. Mason,et al.  Use of microstructural statistics in predicting polycrystalline material properties , 1999 .