Abstract
The effect of material parameters on the statistics of fracture surfaces is analyzed under small scale yielding conditions. Three dimensional calculations of ductile crack growth under mode I plane strain, small scale yielding conditions are carried out using an elastic-viscoplastic constitutive relation for a progressively cavitating plastic solid with two populations of void nucleating second phase particles represented. Large particles that result in void nucleation at an early stage are modeled discretely while small particles that require large strains to nucleate are homogeneously distributed. The three dimensional analysis permits modeling of a three dimensional material microstructure and of the resulting three dimensional stress and deformation states that develop in the fracture process region. Material parameters characterizing void nucleation are varied and the statistics of the resulting fracture surfaces is investigated. All the fracture surfaces are found to be self-affine over a size range of about two orders of magnitude with a very similar roughness exponent of 0.56 ± 0.03 In contrast, the full statistics of the fracture surfaces is found to be more sensitive to the material microscopic fracture properties: height fluctuations are shown to crossover from a Student’s distribution with power law tails at small scales to a Gaussian behavior at large scales, but this transition occurs at a material dependent length scale. Using the family of Student’s distributions, this transition can be described introducing an additional exponent μ = 0.15 ± 0.02, the value of which compares well with recent experimental findings. The description of the roughness distribution used here gives a more complete quantitative characterization of the fracture surface morphology which allows a better comparison with experimental data and an easier interpretation of the roughness properties in terms of microscopic failure mechanisms.
This is a preview of subscription content, log in via an institution.
Buying options
Tax calculation will be finalised at checkout
Purchases are for personal use only
Learn about institutional subscriptionsPreview
Unable to display preview. Download preview PDF.
References
Alava MJ, Nukala PKVV, Zapperi S (2006) Statististical models of fracture. Adv Phys 55:349–476
Belytschko T, Chiapetta RL, Bartel HD (1976) Efficient large scale non-linear transient analysis by finite elements. Int J Numer Methods Eng 10:579–596
Bonamy D, Ponson L, Prades S, Bouchaud E, Guillot C (2006) Scaling exponents for fracture surfaces in homogeneous glass and glassy ceramics. Phys Rev Lett 97:135504
Bonamy D, Bouchaud E (2011) Failure of heterogeneous materials: a dynamic phase transition? Phys Rep 498:1–44
Bouchaud E, Lapasset G, Planès J (1990) Fractal dimension of fractured surfaces: a universal value? Europhys Lett 13:73–79
Bouchaud E (2003) The morphology of fracture surfaces: a tool for understanding crack propagation in complex materials. Surf Rev Lett 10:797–814
Bouchbinder E, Mathiesen J, Procaccia I (2004) Roughening of fracture surfaces: the role of plastic deformation. Phys Rev Lett 92:245505
Cherepanov GP, Balankin AS, Ivanova VS (1995) Fractal fracture mechanics–a review. Eng Fract Mech 51:997–1033
Chu CC, Needleman A (1980) Void nucleation effects in biaxially stretched sheets. J Eng Mater Technol 102:249–256
Gurson AL (1975) Plastic flow and fracture behavior of ductile materials incorporating void nucleation, growth and interaction. Ph.D. Thesis, Brown University
Måløy KJ, Hansen A, Hinrichsen EL, Roux S (1992) Experimental measurements of the roughness of brittle cracks. Phys Rev Lett 68:213–215
Mandelbrot BB, Passoja DE, Paullay AJ (1984) Fractal character of fracture surfaces of metals. Nature 308:721–722
Morel S, Bonamy D, Ponson L, Bouchaud E (2008) Transient damage spreading and anomalous scaling inmortar crack surfaces. Phys Rev E 78:016112
Nakano A, Kalia RK, Vashista P (1995) Dynamics and morphology of brittle cracks: a molecular-dynamics study of silicon nitride. Phys Rev Lett 75:3138–3141
Needleman A, Tvergaard V, Bouchaud E (2012) Prediction of ductile fracture surface roughness scaling. J Appl Mech 79:031015
Peirce D, Shih CF, Needleman A (1984) A tangent modulus method for rate dependent solids. Comput Struct 18:875–887
Ponson L, Auradou H, Vié P, Hulin JP (2006) Low self-affine exponents of fractured glass ceramics surfaces. Phys Rev Lett 97:125501
Ponson L, Bonamy D, Bouchaud E (2006) Two dimensional scaling properties of experimental fracture surfaces. Phys Rev Lett 96:035506
Ponson L, Bonamy D, Auradou H, Mourot G, Morel S, Bouchaud E, Guillot C, Hulin J-P (2006) Anisotropic self-affine properties of experimental fracture surfaces. Int Fract 140:27–36
Ponson L (2007) Crack propagation in disordered materials: how to decipher fracture surfaces. Ann Phys 32:1–120
Ponson L, Auradou H, Pessel M, Lazarus V, Hulin J-P (2007) Failure mechanisms and surface roughness statistics of fractured Fontainebleau sandstone. Phys Rev E 76:036108
Ramanathan S, Ertas D, Fisher DS (1997) Quasistatic crack propagation in heterogeneous media. Phys Rev Lett 79:873–876
Santucci S, Måløy KJ, Delaplace A, Mathiesen J, Hansen A, Bakke J, Schmittbuhl J, Vanel L, Ray P (2007) Statistics of fracture surfaces. Phys Rev E 75:016104
Tvergaard V (1981) Influence of voids on shear band instabilities under plane strain conditions. Int J Fract 17:389–407
Tvergaard V (1982a) On localization in ductile materials containing spherical voids. Int J Fract 18:237–252
Tvergaard V (1982b) Influence of void nucleation on ductile shear fracture at a free surface. J Mech Phys Solids 30:399–425
Tvergaard V, Needleman A (1984) Analysis of the cup-cone fracture in a round tensile bar. Acta Metall 32:157–169
Vernède S, Cao Y, Bouchaud JP, Ponson L (2013) Extreme events and non-Gaussian statistics of experimental fracture surfaces (submitted for publication)
Acknowledgments
The financial support provided by the U.S. National Science Foundation through GrantCMMI-1200203 and by the European Union through the ToughBridge Marie Curie Grant (LP) is gratefully acknowledged. We also thank Jean-Philippe Bouchaud and StéphaneVernède for fruitful discussions.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer International Publishing Switzerland
About this paper
Cite this paper
Ponson, L., Cao, Y., Bouchaud, E., Tvergaard, V., Needleman, A. (2014). Statistics of ductile fracture surfaces: the effect of material parameters. In: Bigoni, D., Carini, A., Gei, M., Salvadori, A. (eds) Fracture Phenomena in Nature and Technology. Springer, Cham. https://doi.org/10.1007/978-3-319-04397-5_11
Download citation
DOI: https://doi.org/10.1007/978-3-319-04397-5_11
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-04396-8
Online ISBN: 978-3-319-04397-5
eBook Packages: EngineeringEngineering (R0)