Journal
COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING
Volume 386, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cma.2021.114084
Keywords
Potential of mean force; Lattice element method; Fracture of heterogeneous materials; Energy methods; Griffith fracture criteria; Energy release rate
Funding
- United States National Science Foundation [CMMI-2047832]
- College of Engineering at the University of Massachusetts Dartmouth
- Center for Scientific Computing and Visualization Research at the University of Massachusetts Dartmouth
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Small-scale material heterogeneity plays a crucial role in determining the macroscopic properties and fracture response of materials. A hybrid energy-based approach is proposed for modeling fracture and crack propagation in heterogeneous materials, utilizing the potential of mean force formulation and Griffith fracture criteria. The study reveals insights into the behavior of fracture toughness in layered materials with fracture energy and elastic modulus heterogeneity, offering potential guidance for materials design.
Material heterogeneity at small scales is a key driver of material's effective macroscopic properties and fracture response. We present a hybrid energy-based approach based on a potential of mean force formulation of lattice element method for reliable and efficient modeling of fracture and crack propagation in heterogeneous materials. The proposed framework rests on direct application of the Griffith fracture criteria and removes material points to create fracture surfaces in energetically favorable directions. Computational efficiency is achieved through a probing of high energy bonds and quasi-static relaxation leading to near global imposition of the energy-based criteria for crack path resolution. We validate the proposed hybrid approach against results in literature and use it to examine fracture response of defective and layered materials. For layered materials with fracture energy heterogeneity, the effective toughness is shown to be the maximum of fracture energies of layers irrespective of their volume fraction and the direction of crack propagation. For layered materials with elastic modulus heterogeneity, the maximum energy release rate occurs when the crack approaches the compliant-stiff interface from within the compliant phase. We examine the scaling of fracture toughness with modulus contrast, the link to volume fraction of the layers and the relationship between toughness anisotropy and the gradient of elastic modulus heterogeneity, offering insights with potential to inform the design of materials for fracture. (C) 2021 Elsevier B.V. All rights reserved.
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