Fracture toughness from the standpoint of softening hyperelasticity

Abstract Fracture toughness of brittle materials is calibrated in experiments where a sample with a preexisting crack/notch is loaded up to a critical point of the onset of static instability. Experiments with ceramics, for example, exhibit a pronounced dependence of the toughness on the sharpness of the crack/notch: the sharper is the crack the lower is the toughness. These experimental results are not entirely compatible with the original Griffith theory of brittle fracture where the crack sharpness is of minor importance. 1 To explain the experimental observations qualitatively we simulate tension of a thin plate with a small crack of a finite and varying sharpness. In simulations, we introduce the average bond energy as a limiter for the stored energy of the Hookean solid. The energy limiter induces softening, indicating material failure. Thus, elasticity with softening allows capturing the critical point of the onset of static instability of the cracked plate, which corresponds to the onset of the failure propagation at the tip of the crack. In numerical simulations we find, in agreement with experiments, that the magnitude of the fracture toughness cannot be determined uniquely because it depends on the sharpness of the crack: the sharper is the crack, the lower is the toughness. Based on the obtained results, we argue that a stable magnitude of the toughness of brittle materials can only be reached when a characteristic size of the crack tip is comparable with a characteristic length of the material microstructure, e.g. grain size, atomic distance, etc. In other words, the toughness can be calibrated only under conditions where the hypothesis of continuum fails.

[1]  Z G Wang,et al.  Adiabatic shear failure and dynamic stored energy of cold work. , 2006, Physical review letters.

[2]  D. Krajcinovic,et al.  Introduction to continuum damage mechanics , 1986 .

[3]  Huajian Gao,et al.  On the Modified Virtual Internal Bond Method , 2005 .

[4]  George A. Gogotsi,et al.  Fracture toughness of ceramics and ceramic composites , 2003 .

[5]  G. I. Barenblatt The formation of equilibrium cracks during brittle fracture. General ideas and hypotheses. Axially-symmetric cracks , 1959 .

[6]  M. Ortiz,et al.  Computational modelling of impact damage in brittle materials , 1996 .

[7]  R. Doremus Cracks and energy--criteria for brittle fracture , 1976 .

[8]  R. Bertolotti Fracture Toughness of Polycrystalline Al2O3 , 1973 .

[9]  D. S. Dugdale Yielding of steel sheets containing slits , 1960 .

[10]  K. Broberg Cracks and Fracture , 1999 .

[11]  René de Borst,et al.  Some recent issues in computational failure mechanics , 2001 .

[12]  J. H. Weiner,et al.  Statistical Mechanics of Elasticity , 1983 .

[13]  M. Ortiz,et al.  Quasicontinuum analysis of defects in solids , 1996 .

[14]  J. Hutchinson,et al.  The relation between crack growth resistance and fracture process parameters in elastic-plastic solids , 1992 .

[15]  Theo Fett,et al.  Ceramics: Mechanical Properties, Failure Behaviour, Materials Selection , 1999 .

[16]  W. M. Rainforth,et al.  The effects of notch width on the SENB toughness for oxide ceramics , 1992 .

[17]  Huajian Gao,et al.  Materials become insensitive to flaws at nanoscale: Lessons from nature , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[18]  K. T. Ramesh,et al.  An approach to multi-body interactions in a continuum-atomistic context: Application to analysis of tension instability in carbon nanotubes , 2006 .

[19]  James R. Rice,et al.  Embrittlement of interfaces by solute segregation , 1989 .

[20]  Xiaopeng Xu,et al.  Numerical simulations of fast crack growth in brittle solids , 1994 .

[21]  H. Saunders,et al.  Introduction to fracture mechanics , 1984 .

[22]  P. Geubelle,et al.  An atomistic-based continuum theory for carbon nanotubes: Analysis of fracture nucleation , 2004 .

[23]  Zohar Yosibash,et al.  Failure criteria for brittle elastic materials , 2004 .

[24]  Konstantin Y. Volokh,et al.  Softening hyperelasticity for modeling material failure: Analysis of cavitation in hydrostatic tension , 2007 .

[25]  J. Lemaître,et al.  Engineering Damage Mechanics: Ductile, Creep, Fatigue and Brittle Failures , 2005 .

[26]  Konstantin Y. Volokh,et al.  Hyperelasticity with softening for modeling materials failure , 2007 .

[27]  Ando,et al.  An investigation into the location of crack initiation sites in alumina, polycarbonate and mild steel , 1999 .

[28]  J. Knott,et al.  Fundamentals of Fracture Mechanics , 2008 .

[29]  Jacek Skrzypek,et al.  Modeling of Material Damage and Failure of Structures: Theory And Applications , 1998 .

[30]  F. G. Emmerich Tensile strength and fracture toughness of brittle materials , 2007 .

[31]  A. A. Griffith The Phenomena of Rupture and Flow in Solids , 1921 .

[32]  K. Volokh Nonlinear Elasticity for Modeling Fracture of Isotropic Brittle Solids , 2004 .

[33]  Huajian Gao,et al.  Crack nucleation and growth as strain localization in a virtual-bond continuum , 1998 .

[34]  Ted Belytschko,et al.  Arbitrary discontinuities in finite elements , 2001 .

[35]  A. Needleman A Continuum Model for Void Nucleation by Inclusion Debonding , 1987 .

[36]  Huajian Gao,et al.  Numerical simulation of crack growth in an isotropic solid with randomized internal cohesive bonds , 1998 .

[37]  D. Munz,et al.  Fracture Toughness Determination of A12O3 Using Four‐Point‐Bend Specimens with Straight‐Through and Chevron Notches , 1980 .

[38]  Huajian Gao,et al.  A study of fracture mechanisms in biological nano-composites via the virtual internal bond model , 2004 .

[39]  C. Inglis Stresses in a plate due to the presence of cracks and sharp corners , 1913 .

[40]  J. M. Alexander,et al.  Progress in applied mechanics : the Prager anniversary volume , 1963 .