A continuum model for void nucleation by inclusion debonding

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Needleman, A.¹

A continuum model for void nucleation by inclusion debonding

J Appl Mech. September 1987;54(3):525-531

©1987 ASME

Affiliations

¹Division of Engineering, Brown University, Providence, RI 02912
Abstract

A cohesive zone model, taking full account of finite geometry changes, is used to provide a unified framework for describing the process of void nucleation from initial debonding through complete decohesion. A boundary value problem simulating a periodic array of rigid spherical inclusions in an isotropically hardening elastic-viscoplastic matrix is analyzed. Dimensional considerations introduce a characteristic length into the formulation and, depending on the ratio of this characteristic length to the inclusion radius, decohesion occurs either in a “ductile” or “brittle” manner. The effect of the triaxiality of the imposed stress state on nucleation is studied and the numerical results are related to the description of void nucleation within a phenomenological constitutive framework for progressively cavitating solids.
Links

DOI: 10.1115/1.3173064

WoS: A1987K190200007
History

Received: 1986-10-28

Revised: 1987-02-17

Cited Works (8)

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1982	Saje M, Pan J, Needleman A. Void nucleation effects on shear localization in porous plastic solids. Int J Fract. 1982;19(3):163-182.

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2006	Gao H. Application of fracture mechanics concepts to hierarchical biomechanics of bone and bone-like materials. Int J Fract. March–April 2006;138(1-4):101-137.
2006	Butcher C, Chen Z, Worswick M. A lower bound damage-based finite element simulation of stretch flange forming of Al–Mg alloys. Int J Fract. December 2006;142(3-4):289-298.
2011	Mischinski S, Ural A. Finite element modeling of microcrack growth in cortical bone. J Appl Mech. July 2011;78(4):041016.
2006	Ural A, Vashishth D. Cohesive finite element modeling of age-related toughness loss in human cortical bone. J Biomech. 2006;39(16):2974-2982.
2007	Ural A, Vashishth D. Anisotropy of age-related toughness loss in human cortical bone: a finite element study. J Biomech. 2007;40(7):1606-1614.
2011	Tang SY, Vashishth D. The relative contributions of non-enzymatic glycation and cortical porosity on the fracture toughness of aging bone. J Biomech. January 11, 2011;44(2):330-336.
2003	Thomson CIA, Worswick MJ, Pilkey AK, Lloyd DJ. Void coalescence within periodic clusters of particles. J Mech Phys Solids. 2003;51(1):127-146.
2011	Butcher C, Chen ZT. Characterizing void nucleation in a damage-based constitutive model using notched tensile sheet specimens. Theor Appl Fract Mech. April 2011;55(2):140-147.
2001	Thomson CIA. Modeling the Effects of Particle Clustering on Ductile Failure [PhD thesis]. Carleton University; May 2001.
2011	Donaldson FE. On Incorporating Bone Microstructure in Macro-Finite-Element Models [PhD thesis]. Edinburgh, UK: University of Edinburgh; March 2011.
2011	El Sabagh WMM. The Effect of Compacted Graphite Iron Microstructure on Fracture and Machining [PhD thesis]. Hamilton, ON: McMaster University; 2011.
1995	Socrate S. Mechanics of Microvoid Nucleation and Growth in High-Strength Metastable Austenitic Steels [PhD thesis]. Cambridge, MA: Massachusetts Institute of Technology; June 1995.
2011	Butcher C. A Multi-Scale Damage Percolation Model of Ductile Fracture [PhD thesis]. Fredricton, NB: The University of New Brunswick; August 2011.
2015	Ghandehariun A. Mechanics of Machining Metal Matrix Composites: Analytical Modeling and Finite Element Simulation [PhD thesis]. University of Ontario Institute of Technology; January 2015.
1998	Swadener JG. Primary Fracture Toughness Mechanisms of a Glass/epoxy Interface [PhD thesis]. University of Texas at Austin; 1998.
2004	Chen Z. The Role of Heterogeneous Particle Distribution in the Prediction of Ductile Fracture [PhD thesis]. University of Waterloo; 2004.
2005	Baradari JG. Damage in Hydroforming of Pre-Bent Aluminum Alloy Tubes [PhD thesis]. University of Waterloo; 2005.
2021	Samadian P. Constitutive and Fracture Characterization and Modelling of Monolithic and Tailor-Welded Blanks of Press-Hardening Steels [PhD thesis]. University of Waterloo; 2021.