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V. Oborin et alii, Frattura ed Integrità Strutturale, 34 (2015) 422-426; DOI: 10.3221/IGF-ESIS.34.47                                                                  
 

422 
 

Focussed on Crack Paths 

 
 
 
  
Multiscale study of fracture in aluminum-magnesium  
alloy under fatigue and dynamic loading 
 
 
Vladimir Oborin, Mikhail Bannikov, Oleg Naimark, Mikhail Sokovikov, Dmitry Bilalov 
Institute of Continuous Media Mechanics of Ural branch of RAS, 614013, Perm, Russia 
oborin@icmm.ru, mbannikov@icmm.ru, naimark@icmm.ru, sokovikov@icmm.ru, ledon@icmm.ru  
 
 

 
ABSTRACT. In this paper we investigated the influence of consecutive dynamic and gigacycle fatigue loads on 
the lifetime of aluminum-magnesium alloy AlMg6. Preloading of samples was achieved during dynamic tensile 
tests in the split-Hopkinson bar device. Fatigue tests were conducted on Shimadzu USF-2000 ultrasonic fatigue 
testing machine. This machine provides 109-1010 loading cycles with the amplitude from 1 to several dozens of 
microns and frequency of 20 kHz, which reduces dramatically the testing time in the comparison to the classical 
fatigue testing machines. The New-View 5010 interferometer–profiler of high structural resolution (resolution 
of 0.1 nm) was used for qualitative fracture surface analysis, which provided the data allowing us to find 
correlation between mechanical properties and scale-invariant characteristics of damage induced roughness 
formed under dynamic and gigacycle fatigue loading conditions.  
Original form of the kinetic equation was proposed, which links the rate of the fatigue crack growth and the 
stress intensity factor using the scale invariant parameters of fracture surface roughness. The scale invariance 
characterizes the correlated behavior of multiscale damage provides the link of crack growth kinetics and the 
power exponent of the modified Paris law.  
 
KEYWORDS. Fracture; Gigacycle fatigue; Scaling; Surface morphology; Fractal analysis; Paris law. 
 
 
 
 
INTRODUCTION  
 

he assessment of the lifetime of critical engineering structures, in particular those for aircraft engines, poses 
qualitatively new fundamental problems related to evaluation of the reliability of materials under cyclic loading in 
excess of 109–1010 cycles corresponding to the so-called gigacycle fatigue range. This interest is caused by the fact 

that the fatigue lifetime of critical structures operating under cyclic loading conditions exceeds a gigacycle fatigue range. 
The gigacycle fatigue range can be characterized by some features, where of special interest is the range pertaining to the 
number of cycles N≈109. The behavior of materials in this range reveals some qualitative changes in the mechanisms 
governing both the nucleation of cracks and their propagation.  
The influence of random statistic and dynamic loads on the lifetime of materials under gigacycle fatigue regime is a subject 
of much current interest for aircraft motor companies in the context of solving the problem of reliability (longevity) of 
materials under real operating conditions [1]. For instance, that concerns to the lifetime estimation of gas turbine engine 
blades during their collision with solid particles usually called foreign object damage. The solution to this problem needs 

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                                                               V. Oborin et alii, Frattura ed Integrità Strutturale, 34 (2015) 422-426; DOI: 10.3221/IGF-ESIS.34.47 
 

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the understanding of fundamental aspects of multi-scale damage evolution in large range of load intensity for the 
prediction of the kinetics of nucleation and propagation of cracks in the damaged material with the purpose to optimize 
the material structure and finding the materials with low sensitivity to random dynamic loads under high- and gigacycle 
fatigue conditions.  In this paper, aluminum-magnesium alloy (AlMg6) samples (Fig. 1) are tested. 
 
 
KINETIC EQUATION FOR FATIGUE-CRACK GROWTH 
 

he universal character of kinetic law establishing a relationship between the growth rate dl/dN of a fatigue cracks 
and a change in the stress intensity coefficient ΔK has been extensively studied both experimentally and 
theoretically. The power laws originally established by Paris [2] (and presently referred to as the Paris law) reflect 

the self-similar nature of fatigue crack kinetics. This law is related to a nonlinear character of damage evolution in the 
vicinity of the crack tip (called the “process zone”): 
 

  mdl A K
dN

              (1) 

 
where A and m are the experimentally determined constants. For a broad class of materials and wide range of crack 
propagation velocities under high cycle fatigue conditions, the exponent is typically close to m = 2–4. 
The self-similar aspects of the fatigue crack growth were studied by Barenblatt, Ritchie [3,4] using the assumption 
concerning intermediate self-similarity of fatigue crack kinetics to introduce the following variables for the representation 
of the crack growth rate a = dl/dN (where l is the crack length and N is the number of cycles):  a1 = ΔK  is  the stress 
intensity factor; a2 = E is the Young modulus; a3 = lsc is the scale related to the correlated behavior in the ensemble of 
defects on the scale  a4 = Lpz  associated with the process zone. 3D New View roughness data within the crack process 
zone (Fig.2) supported the existence of mentioned characteristic scales: the scale of process zone Lpz and correlation 
length lsc that is the scale when correlated behavior of defect induced roughness has started.  
Using the Π-theorem and taking into account the dimensions of variables [dl/dN] = L, [ΔK]=FL–3/2, [lsc]=[Lpz] = L, and 
[E] = FL–2, the kinetic equation for the crack growth: 
 

Ф( , , , )sc pzdl dN K E l L  ,             (2) 
 
can be written as: 
 

1
,

pz

sc scsc

Ldl K

dN l lE l

 
   

 
.             (3) 

 

Estimation of the values ( ) 1scK E l   and / 1pz scL l   allowed one to suggest an intermediate-asymptotic character 
of the crack growth kinetics for Eq. (3) in the following form: 
 

sc

pz

sc

Ld l K

dN lE l


  

   
   

,         (4) 

 

where / scl l l

 . Introducing the parameter  /pz scC L l


 , we can reduce the scaling relation (4) to the following form 

analogous to the Paris law: 
 

C
sc

d l K

dN E l


 

  
 

,          (5) 

 

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V. Oborin et alii, Frattura ed Integrità Strutturale, 34 (2015) 422-426; DOI: 10.3221/IGF-ESIS.34.47                                                                  
 

424 
 

where is a universal exponent. This form is similar to the equation proposed by Hertzberg for scl b , where b is the 
Burgers vector.  
 
 
MATERIALS AND EXPERIMENTAL CONDITIONS 
 

ynamic preloading of aluminum-magnesium alloy (AlMg6) samples (Fig. 1) was realized using the split 
Hopkinson pressure bar set-up at the strain rates of ~103 s-1, after which the samples were subject to cyclic 
loading at room temperature. Then the fractography of fracture surface pattern was studied using the roughness 

data by interferometer–profiler New-View 5010. 
Fatigue tests were carried out using the resonance type of testing machine of (Shimadzu USF-2000) that provides the 
cyclic loading using the generator transforming the frequency of 50 Hz into ultrasonic electrical sinusoidal signal of 
frequency 20 kHz by piezoelectric transducer, generating longitudinal ultrasonic waves at a frequency 20 kHz and the 
mechanical stress with maximum amplitude in the gauge length (mid-section) of the sample. Deviation of the frequency 
by 0.5 kHz was associated with the damage critical stage and considered as failure precursor related to the initiation of a 
crack with characteristic size of ~2 mm. The level of applied stresses allowed us to investigate fatigue life up to the values 
associated with 1010 cycles. The fatigue scenario was studied for the stress amplitude 105, 120, 130 MPa corresponding to 
a critical number of cycles of about ~1010 estimated for initially unstressed materials subject to gigacycle fatigue tests.   

 

 
 

Figure 1: Sample geometry (sizes are given in millimeters). 
 
The roughness of fracture surfaces was measured by the high-resolution New-View 5010 interferometer-profiler 
(providing x2000 magnification) and then was analyzed using the assumption concerning fractal geometry of fracture 
surface profile associated with correlated behavior of multiscale defect structures on the scale of process zone pzL  that 

preceded to the crack growth. 
The fatigue tests provided the fractured samples of two types. The samples of the first type were broken during the 
fatigue test. The samples of the second type revealed pronounced variations in the resonance frequency associated with 
fatigue crack origin. The fracture surfaces of the samples of the first and second type were uncovered by cooling the 
samples with liquid nitrogen and breaking them in the minimal cross-section of samples. It is assumed that the fatigue 
fracture surface of the samples subjected to gigacycle loading has already been formed during fatigue tests and occupies 
the largest part of the fracture surface, which is determined by a change in the resonance frequency. 
The crack origin in cylindrical samples undergoing high cycle loading in the range 106-107 is started from the surface (Fig. 
2a). For the samples subject to cyclic loads in the range exceeding 108 cycles the crack formation is started in the bulk of 
the sample. The fracture surface in this case exhibits a fatigue zone known as a “fish-eye” which is a particular feature of 
such fatigue regimes. The central part of this region comprises a fracture nucleus surrounded by the region of refined 
(submicrocrystalline) structure (region 2 in Fig. 2b). 
The New-View scanning was realized over the zones of fatigue crack growth (Fig. 2a) and one-dimensional profiles of the 
surface relief were made in the radial direction starting from zone 1 to zone. Within each “window” about 12 one-
dimensional profiles were analyzed to ensure representativeness of the data along the defect-induced relief with vertical 
resolution of 0.1 nm and horizontal resolution of ~ 0.5 µm. 
A minimum (critical) scale lsc that corresponds to beginning of multiscale long-range correlation in defect ensembles is 
determined by the computing of the Hurst exponent. The function K(r) is calculated for one-dimensional profiles of 
fracture surface relief according to the formula [5,6]: 

 

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                                                               V. Oborin et alii, Frattura ed Integrità Strutturale, 34 (2015) 422-426; DOI: 10.3221/IGF-ESIS.34.47 
 

425 
 

 
1/22( ( ) ( )) H
x

K r z x r z x r    ,                      (6) 

 
where K(r) is the averaged difference between the values of surface relief heights z(x+r) and z(x) in the window of size r, 
and H is the Hurst exponent (surface roughness index). 
Representation of the function K(r) in logarithmic coordinates allowed one to evaluate the lower boundary of the scaling 
range lsc, and the value of upper boundary considering one as the characteristic scale of the process zone Lpz , i.e. the area 
of correlated behavior of multiscale defect structures (Fig.3). 

 
 
 
 
 
 
 
 
 
 
 
 
 
 

                 

                       (a)                                                 (b) 

Figure 2: Characteristic surface relief of a fatigue fracture zone: high cycle fatigue (a); gigacycle fatigue (b). 

 
 

          
    (a)      (b) 

Figure 3: Characteristic one-dimensional profiles for zone 1 (a), plot lnK(r) vs. ln(r) for zone 1 (b). 
 

The values of the Hurst exponent H and the scales Lpz and lsc for different loading conditions are given in Tab. 1. 
 
 
CONCLUSION 

 
he comparative analysis of the scaling characteristics of samples loaded under conditions of high - and gigacycle 
fatigue shows a significant decrease in the range of spatial scales, where the Hurst exponent remains constant for 
dynamically loaded samples in the «fish-eye» (0.5-10.9 mkm) zone. This result confirms our assumption that 

mentioned characteristic scales Lpz and lsc play an important role in the list of variables for the kinetic equation fatigue of 
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V. Oborin et alii, Frattura ed Integrità Strutturale, 34 (2015) 422-426; DOI: 10.3221/IGF-ESIS.34.47                                                                  
 

426 
 

crack growth and can be used for the identification of phenomenological parameters (power index) providing self-similar 
law for the crack path. 

 
Sample 
number 

Elongation
(mm) 

Striker velocity
 (m/s) , MPa , cycles

Zone 
number

lsc, mkm 
Lpz , 

mkm 
H 

1 0.89 28.4 130 7.33·10+6 2 1.4 20.6 0.57 

2 1.77 40.3 120 7.82·10+8
2 
3 

0.5 
0.8 

10.9 
21.4 

0.63 
0.62 

3 1.27 32.1 120 5.72·10+7 2 1.0 18.2 0.60 

4 2.21 40.3 105 5.83·10+6 2 1.0 14.2 0.46 

 
Table 1: The values of the Hurst exponent H and scales Lpz and lsc at various levels of fatigue longevity. 

 
 
ACKNOWLEDGEMENT 
 

his study was supported by the Russian Science Foundation, project № 14-19-01173. 
 
 

 
 
REFERENCES 

 
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[4] Fract. Mech., 75 (2008) 299–3052. 
[5] Barenblatt, G.I., Scaling phenomena in fatigue and fracture, Int. J. of Fracture, 138 (2006) 19–35. 
[6] Ritchie, R.O., Incomplete self-similarity and fatigue-crack growth, Int. J. of Fracture, 132 (2005) 197–203. 
[7] Bouchaud,  E., Scaling properties of cracks, J. Phys. Condens. Matter, 9 (1997) 4319– 4344. 
[8] Froustey, C., Naimark, O., Bannikov, M., Oborin, V., Microstructure scaling properties and fatigue resistance of 

[9] prestrained aluminium alloys (part 1: Al-Cu alloy), European Journal of Mechanics A/Solids, 29 (2010) 1008–1014. 
 
 
 
 
 
 
 

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