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H. Jasarevic et alii, Frattura ed Integrità Strutturale, 20 (2012) 32-35; DOI: 10.3221/IGF-ESIS.20.04                                                                    
 

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Case studies in numerical simulation of crack  
trajectories in brittle materials 

 
 

H. Jasarevic  
Faculty of Civil Engineering, University of Sarajevo, Sarajevo (Bosnia and Herzegovina) 
haris.jasarevic@gf.unsa.ba 
 
S. Gagula 
Faculty of Engineering and Natural Sciences, International University of Sarajevo, Sarajevo (Bosnia and Herzegovina)  
sadina@ius.edu.ba 
 

 
ABSTRACT. Statistical Fracture Mechanics, formalism of few natural ideas is applied to simulation of crack 
trajectories in brittle material. The “diffusion approximation” of the crack diffusion model represents crack 
trajectories as a one-dimensional Wiener process with advantage of  well-developed mathematical formalism 
and simplicity of creating computer generated realizations (fractal dimension d = 1.5).  However, the most of 
reported d values are in the range 1.1-1.3.  As a result, fractional integration of Wiener processes is applied for 
lowering d and to generate computer simulated trajectories. Case studies on numerical simulation of 
experimentally observed crack trajectories in sandstone (discs tested in indirect tensile strength test) and 
concrete (compact tension specimens tested in the quasi-static splitting tensile test) are presented here.  
 
KEYWORDS. Statistical Fracture Mechanics; Brittle materials; Crack trajectories; Fractal dimension; Sandstone; 
Concrete. 
 
 
 
INTRODUCTION 
 

pproach to describe the physics of fracture for cases when failure of single element does not equal to failure of 
whole body was proposed first by Chudnovsky [1]. It evolved afterwards in crack diffusion model [2] and 
Statistical Fracture Mechanics (SFM) [3, 4], which both describe crack propagation in brittle materials. SFM 

formalizes following natural ideas [4]:  
i) crack advance consists of a sequence local fail ures in front of a crack tip,  
ii) the local failures are random events due to fluctuations of local strength of the material,  
iii) the crack trajectory is random, i.e. crack can follow any path from a set Ω of all admissible crack paths.  
For each of those paths conditional probability of failure along that path exists. The probability of crack advancing from 
point A to point B is an average of those conditional probabilities over all admissible crack paths leading from A to B. 
 
 
SIMULATION PROCEDURE 
 

he “diffusion approximation” of the crack diffusion model (see Chudnovsky and Gorelik, 1994), represents crack 
trajectories as a one-dimensional Wiener process (Brownian motion) w(t). This approach has advantage due to 
well-developed mathematical formalism and simplicity of creating computer generated realizations with known 

fractal dimension d = 1.5. However, often it cannot be directly applied to simulate actually observed fracture profiles, 

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                                                                 H. Jasarevic et alii, Frattura ed Integrità Strutturale, 20 (2012) 32-35; DOI: 10.3221/IGF-ESIS.20.04 
 

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since the most of reported d values are in the range 1.1-1.3 [5]. As a result, it is necessary to modify w(t) to lower its d. The 
simulation procedure by applying the operation of fractional integration to realization of w(x) in order to decrease d to 
desired value is described by Kunin and Gorelik [5] in detail.  
The realization w(x) with d = 1.5 is first generated as integral of a white noise e(x) written in discrete form as: 
 

( )
( ) ( )   i i

i
w x D e           (1) 

 

where ei is Gaussian random variable with zero mean and unit variance and D is crack diffusion coefficient determined 
from experimental data. D is statistical parameter reflecting the tendency of crack trajectories to deviate from central axis 
[5].  
Once the realization is generated, it is necessary to modify fractal dimension by applying the fractional integration 
operation to it as follows: 
    

 
   1

0

1
( )

x

w x w x d


   


 
                                       (2) 

 

Where (…) is the Gamma-function, and fractal dimension of w(x) is d = 1.5-. A numerical implementation of above 
described procedure has been coded into the software MatLab® for case study simulations presented later in this text.  
The algorithm requires 3 input parameters, namely d, D and n (number of trajectories to be generated). Each realization of 
w(x) with d = 1.5 incorporating parameter D is generated with 1000 time steps (intervals) and fractional integration 
operation is performed to create final realization w(x) with d = 1.5-. The process is repeated in DO loop till n trajectories 
are created. Due to the above described formalism simplicity and computational performance of modern computers, this 
whole process is completed in the matter of couple of seconds. However, the major issue is obtaining input parameters (d, 
D) for simulation from experiments (sufficient number of repeated experimental tests is needed). It should be noted that 
both parameters are strongly scale dependent. Issa at al [6] stated that groups of identically sized concrete specimens 
prepared with different aggregate sizes have different values of D (one with smaller size aggregate have smaller value of 
D). In addition, larger  sized specimens with identical mix have lower values of d. Also, Zavarise at al [7] pointed that 
statistical parameters used in stochastic contact models are scale dependent (being function of profilometer resolution).   
 

  
 

Figure 1: Experimentally observed crack trajectories in sandstone 
discs. 

Figure 2: Simulated sandstone crack trajectories with d=1.2 and 
D=0.01 

 

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H. Jasarevic et alii, Frattura ed Integrità Strutturale, 20 (2012) 32-35; DOI: 10.3221/IGF-ESIS.20.04                                                                    
 

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CRACK TRAJECTORIES SIMULATION CASE STUDIES 
 
Sandstone  

he test results on macroscopically identical sandstone discs tested in indirect tensile strength test (ASTM [8] and 
ISRM [9]) were reported by Jasarevic at al [10, 11]. 50.8 mm diameter and 25.4 mm thickness (t/D = 0.5) discs cut 
from a block of Torry Buff sandstone are used for the tests. The Torry Buff material tested is a very fine-grained 

porous, consolidated sandstone, porosity ~19%, permeability ~3-millidarcy, Young’s modulus 10.5 MPa (measured on 
three 44.5-mm diameter, 92.4-mm length cylinders) and dry unconfined compressive strength ~40 MPa. Total of ten discs 
were tested and observed crack trajectories are shown in Fig. 1 (Jasarevic, 2009a). Results clearly show that crack 
trajectories are random (i.e. no two coincide) satisfying SFM formalism described before. Result of computer simulated 
crack trajectories for fractal dimension d=1.2 and D=0.01 (see Jasarevic [10] for calculation details) is shown in Fig. 2 for 
comparison. 
 
Concrete 
The test results for study of size effects in concrete fracture on multiple sizes of macroscopically identical compact tension 
specimens tested in the quasi-static splitting tensile test (ramp test) were reported by Issa at al [6, 12]. The specimens were 
positioned so that the notch was at the top and the actuator applied the load downward through a wedge at an angle of 
8.7.  A wedge applied the load on the rollers that passed through rectangular cylinders.  The rectangular cylinders had the 
same dimensions as the rectangular part of the notch.  The downward force applied through a wedge was translated into a 
splitting tensile force through the rollers.  The test was conducted in the displacement control mode at a rate of loading of 
0.125 mm/min.  Some of conclusions of this work are that concrete fracture surfaces with the larger aggregate sizes 
appear to have a higher roughness than those with smaller aggregate sizes. The crack path is less tortuous for 
geometrically identical specimens with smaller size aggregates. Similarly, the crack path deviates from the centerline of the 
specimen to a less degree for the smaller size aggregates than that for the larger ones. Crack trajectories for 6 
macroscopically identical specimens with maximum aggregate size of ¾ in. (19mm) are shown in Fig. 3. Same as for 
sandstone, experimentally observed crack path appears to be random, i.e., no two macroscopically identical specimens 
exhibit the same fracture path. Result of computer simulated crack trajectories for fractal dimension d=1.1 and D=0.05 
(see Issa at al [12] and Hammad and Issa [13] for calculation details) is shown in Fig. 4 for comparison. 
 

 

Figure 3: Experimentally observed crack trajectories in concrete 
specimens.   

Figure 4: Simulated concrete crack trajectories for d=1.1 and 
D=0.05.

 
 

CONCLUSION 
 

andstone and concrete as brittle materials satisfy the SFM formalism in which no two fracture paths for 
macroscopically identical specimens coincide. The “diffusion approximation” of the crack diffusion model cannot 
be applied to crack trajectories experimentally observed in sandstone and concrete, since their fractal dimension is 

less then 1.5. Instead fractional integration of Wiener processes together with parameters extracted from experiments was 

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                                                                 H. Jasarevic et alii, Frattura ed Integrità Strutturale, 20 (2012) 32-35; DOI: 10.3221/IGF-ESIS.20.04 
 

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used to simulate fracture profiles. Computer realizations of crack trajectories for two case studies presented here seem to 
be in good agreement with experimentally observed ones. Procedure for simulation is relatively simple and straightforward 
once the input parameters (fractal dimension d and diffusion coefficient D) are known. However, sufficient number of 
repeated experimental tests is needed to extract these parameters.      
 
 
REFERENCES 
   
[1] A. Chudnovsky, In: Studies on Elasticity and Plasticity, ed. L. Kachanov, Leningrad, Leningrad University Press 

(1973) 3. 
[2] A. Chudnovsky, B. Kunin, J. Appl. Phys., 62 (1987) 4124. 
[3] A. Chudnovsky, B. Kunin, In: Microscopic Simulation of Complex Hydrodynamic Phenomena, eds. M. Mareschal 

and B.L. Holian, Plenum Press, New York (1992) 345. 
[4] A. Chudnovsky, M. Gorelik, In: Probabilities and Materials, ed. D. Breysse,. Netherlands, Kluwer Academic 

Publishers (1994) 321. 
[5] B. Kunin, M. Gorelik, J. Appl. Phys. 70, (1991) 7651. 
[6] M. A. Issa, M. A. Issa, H. Abdalla, M. S. Islam, A. Chudnovsky, Int. J. of Fract., 102 (2000) 25. 
[7] G. Zavarise, M. Borri-Brunetto, M. Paggi, Wear, 262 (2007) 42. 
[8] ASTM. Annual Book of Standards: Standard test method for splitting tensile strength of intact rock                  

core specimens (designation D 4645-87). American Society for Testing and Materials, 4 (1989) 851.  
[9] ISRM, Int. J. Rock Mech. Min, Sci. & Geomech. Abstr., 15 (1978) 99. 
[10] H. Jasarevic,. Observation, Characterization and Modeling of Fracture Initiation Phenomena, Ph.D thesis, Dept. of 

Engineering, Univ, Ill. at Chicago (2009). 
[11] H. Jasarevic, A. Chudnovsky, J. W. Dudley, G. K. Wong, Int. J. Fract. , 158 (2009) 73. 
[12] M. A. Issa, M. A. Issa, H. Abdalla, M. S. Islam, A.Chudnovsky, Int. J. of Fract., 102 (2000) 1. 
[13] A. M. Hammad, M. A. Issa, Adv. Cem. Based Mater. 1 (1994) 169. 

 
 
 
 

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