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J. Toribio et alii, Frattura ed Integrità Strutturale, 25 (2013) 124-129; DOI: 10.3221/IGF-ESIS.25.18                                                                         
 

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Special Issue: Characterization of Crack Tip Stress Field 
 
  
Plastic zone evolution near a crack tip and its role in 
environmentally assisted cracking 
 
 
Jesús Toribio, Viktor Kharin 
University of Salamanca, Spain 
 

 
ABSTRACT. This paper analyzes the effects of crack tip plastic strains and compressive residual stresses, created 
by fatigue pre-cracking, on environmentally assisted cracking of pearlitic steel subjected to localized anodic 
dissolution and hydrogen assisted fracture. In both situations, cyclic crack tip plasticity improves the behavior of 
the steel. In the respective cases, the effects are supposed to be due to accelerated local anodic dissolution of 
the cyclic plastic zone (producing chemical crack blunting) or to the delay of hydrogen entry into the metal 
caused by residual compressive stresses, thus increasing the fracture load in aggressive environment. 
 
KEYWORDS. Plastic zone; Near-tip stress-strain fields; Environmentally assisted cracking. 
 
 
 
INTRODUCTION 
 

nvironmentally assisted cracking (EAC) of metals is usually evaluated by testing of pre-cracked specimens 
prepared by fatigue (cyclic) loading in laboratory air that produces a redistribution of stresses and strains as a 
consequence of cyclic plastic deformations. Compressive residual stresses generated at fatigue load release, 

together with plastic strains, affect the stress corrosion behavior of materials [1]. 
This paper deals with the mechanical effects of pre-loading on the posterior EAC in a pearlitic high-strength steel wire 
used for prestressed concrete structures. The rising load EAC experiments are considered in combination with numerical 
modeling of the elastoplastic stress-strain field near the crack tip subjected to fatigue pre-cracking and subsequent 
monotonic loading during EAC tests. 
 
 
EXPERIMENTAL 
 

AC experiments were performed with a series of Kmax/KIC= 0.28, 0.45, 0.60 and 0.80, where KIC is the fracture 
toughness of the material and Kmax the maximum stress intensity factor during fatigue precracking. The 
experiments were rising load tests of pre-cracked specimens in aqueous solution under anodic and cathodic 

potentials to evaluate the two main mechanisms of EAC [2]: localized anodic dissolution (LAD) under the anodic regime 
and hydrogen assisted cracking (HAC) under the cathodic regime. The full experimental details are described elsewhere 
[1]. 
The tested high-strength steel has the properties given in Tab. 1. For the two regimes of environmental cracking (HAC 
and LAD), Fig. 1 plots the failure load during the EAC test (evaluated through the ratio of the failure load in aggressive 
environment FEAC to the failure load in air FC) as a function of the severity of the fatigue precracking regime (expressed in 
dimensionless terms as the maximum stress intensity factor during fatigue precracking Kmax divided by the fracture 
toughness of the material KIC). For both LAD and HAC, heavier pre-cracking is beneficial for the EAC resistance of the 
steel. This may be attributed to the cyclic plastic zones and compressive stresses near the crack tip due to fatigue. The 

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                                                                 J. Toribio et alii, Frattura ed Integrità Strutturale, 25 (2013) 124-129; DOI: 10.3221/IGF-ESIS.25.18 
 

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higher the cyclic load level, the stronger the pre-straining/stressing effect which delays environmental damage (metal 
dissolution in LAD or hydrogen entry in HAC) and improves material performance in a hostile environment.  
 

Young 
modulus 
E [GPa] 

Tensile Yield 
Strength Y 

[MPa] 

Toughness 
KIC 

[MPam] 

Ramberg-Osgood curve = /E+(/P)n 

(I) p<1.07 (II) p1.07 
PI (MPa) nI PII (MPa) nII 

195 725 53 2120 5.8 2160 17 
 

Table 1: Mechanical properties of the steel. 
 

 
Figure 1: Failure load during the EAC test as a function of the severity of the fatigue precraking regime. 

 
Fractographic analysis of the samples after HAC tests revealed the existence of a particular microscopic fracture mode 
(Fig. 2a) which is a signal of hydrogen assisted microdamage [3] in pearlitic steels as those used in the present work: the so 
called tearing topography surface (TTS) between the fatigue pre-crack and the final cleavage fracture. Measured TTS depth 
xTTS also depends on the pre-cracking regime, as plotted in Fig. 2b. Again this may be attributed to the cyclic plastic zones 
and compressive stresses near the crack tip due to fatigue. 
 

 
 

 
(a) (b) 

 

Figure 2: (a) Fractographic appearance of the Tearing Topography Surface (TTS), (b) Depth of the TTS zone in the HAC tests (cathodic 
regime of EAC) as a function of the severity of the fatigue precraking regime (Kmax/KIC). 

 
 

MODELLING OF CRACK TIP MECHANICS 
 

o ascertain the effects of pre-cracking on EAC, the evolutions of mechanical variables associated with EAC are 
desired. In previous analyses [4] the Rice model [5] was applied. In this paper, a high-resolution numerical 
modelling of the crack tip stresses and strains during fatigue pre-cracking and rising load EAC test was performed T 

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J. Toribio et alii, Frattura ed Integrità Strutturale, 25 (2013) 124-129; DOI: 10.3221/IGF-ESIS.25.18                                                                         
 

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for an elastoplastic material with von Mises yield surface and Ramberg-Osgood strain-hardening rule. Mixed isotropic-
kinematic hardening was used to capture Bauschinger-type effects. Model parameters corresponded to the steel used in 
the experiments (Tab. 1).  
Finite deformation analysis of a plane strain crack under mode I (opening) load was confined to small scale yielding, so 
that the stress intensity factor K is the only variable governing the near tip mechanics [6]. The initial crack was modeled as 
a parallel-sided round-tip slit with initial height b0 = 5 m in agreement with data for fatigue cracks in steels [7]. Simulated 
loading histories consisted of several zero-to-tension cycles with Kmax/KIC= 0.45, 0.60 and 0.80, followed by rising load 
representing the EAC tests. An updated Lagrangian formulation was used in the computations. 
Plastic zones developed fairly self-similar with a scaling factor of (K/Y)2, which is natural for the K-dominated crack-tip 
domain and coincides with the prediction by Rice [5]. At loading up to the first load reversal at Kmax, the monotonic plastic 

zone is defined by the equivalent von Mises stress eq = Y (Fig. 1, left) where Y is the tensile yield stress.  
Because of strain hardening, after load reversal the Y-stress based yield criterion must not indicate further where plastic 
flow really proceeds. The cyclic plastic zones are defined then by positive equivalent plastic strain rate, eqp > 0 (Fig. 1, right). 
They are approximately the same at cyclic load minima (reversed zones at Kmin = 0) and maxima (forward zones at Kmax), 
smaller than the monotonic zone and quite stable with the cycle number.  
 

X
Y
Z

1 

Y
XZ

1 
 

Figure 3: Monotonic (left) and cyclic (right) plastic zones at K = Kmax for Kmax/KIC = 0.6 (the grid spacing is 50 m). 
 

At rising load, plastic flow starts at K = 0.2Kmax after elastic reloading and develops identically as the cyclic zone does up 
to attaining the pre-cracking level of K = Kmax, when it bursts and advances as the monotonic plastic zone does.  
The near tip stress distributions differ substantially from estimation given by Rice [5]. They stabilize after few first cycles 
as soon as a steady state of alternating plastic flow is approached. Fig. 4 shows the evolution of the hydrostatic stress in 
the crack plane beyond the tip,  = (x), where x is the distance to the crack tip in the deformed configuration of a solid, 
during monotonic loading in the EAC test after pre-cracking. This stress component is focused since it is determinant for 
HAC controlled by stress-assisted hydrogen diffusion driven by the gradient  towards maximum stress locations [8, 9]. 
 

     
 

Figure 4: Hydrostatic stress distributions beyond the crack tip during monotonic loading at EAC test after fatigue pre-cracking at 
Kmax/KIC = 0.45 (dashed lines) and 0.80 (solid lines). 
 
 

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                                                                 J. Toribio et alii, Frattura ed Integrità Strutturale, 25 (2013) 124-129; DOI: 10.3221/IGF-ESIS.25.18 
 

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DISCUSSION 
 

o analyze the results of the EAC tests on the basis of crack tip mechanics, the critical stress intensity factor for 
EAC to proceed KQEAC is evaluated from the experimental failure loads (Fig. 1) as KQEAC= (FEAC/FC) KIC (air). 
For LAD-controlled fracture, fatigue pre-cracking may cause a strong protective effect characterized by the fracture 

loads ratio FEAC/FC (Fig. 1). Considering mechanical factors of EAC, the normal stresses at the crack tip surface (at x = 
0) and the crack tip plastic strains may influence LAD processes [2]. Evolutions of the crack tip mean normal stress (x = 
0) during EAC after different pre-cracking regimes (Fig. 5a) are practically insensitive to the cyclic load level Kmax. 
Stresses in the interior at x > 0 must be irrelevant for LAD since it is a surface dissolution reaction. Therefore, no 
difference should be expected for LAD from the residual stresses produced at different K.  
Toughening effect of the pre-cracking on LAD-driven EAC may be associated with accelerated dissolution of the cyclic 
plastic zone due to the inherently higher chemical activity of its damaged crystalline structure [2]. Due to cyclic damage 
accumulation not only ahead of the tip but also aside of the main crack path (Fig. 3), lateral strain-enhanced dissolution 
may allow chemical crack blunting to compete with dissolution-induced crack extension. Then, fracture load must increase 
together with the LAD-driven crack blunting. The LAD process may be supposed to involve a domain with a cumulative 
plastic strain above a certain level. This region must be proportional to the zone of accumulated cyclic plastic strain xY, 
or probably to the active plastic size xAPZ. Fig. 5b displays this correspondence according to the EAC tests and numerical 
data about plastic zones.  
 

                          
 

Figure 5: Mechanical factors of the crack growth by LAD: (a) evolutions of the crack tip hydrostatic stress  during EAC test after 
fatigue pre-cracking at Kmax/KIC = 0.45 (dashed line) and 0.80 (solid line); (b) sizes of the plastic zones associated with EAC tests: the 
terminal active plastic zone during the LAD test (xAPZ at KQEAC) which surpasses the cyclic and the monotonic plastic zones created 
during fatigue pre-cracking of the specimens, xY (Kmax) and xY (Kmax) respectively. 
 
For HAC-controlled fracture, hydrogen transport to prospective rupture sites ahead of the crack tip may be supplied by two 
different mechanisms [8,9]: (i) sweeping by moving dislocations within the active plastic zone during load rise; (ii) 
diffusion in metal driven by hydrostatic stress gradient towards the maximum tensile stress locations. 
With regard to the first, hydrogenation and hydrogen damage area must be about as extensive as the active plastic zone. 
However, experimental data on the TTS width xTTS as an indicator of hydrogen damage (Fig. 2) do not agree with 
calculated plasticity extent xAPZ after different pre-cracking regimes (Fig. 6a). Although TTS overpassing the plastic zone 
size at lower Kmax levels in Fig. 6a may be attributed to the subcritical crack growth and plastic (damage) zone 
displacement next to the crack tip, it cannot be at Kmax = 0.8KIC when xTTS << xAPZ even for stationary crack. This fact 
indicates that dislocational transport of hydrogen to rupture sites must not be the responsible for HAC in this case. 
Considering stress-assisted diffusion, the near tip distributions of the hydrostatic stress (x) displayed in Fig. 4 indicate 
that, during the rising load EAC tests, initially compressive stresses (x) < 0 and accompanying negative gradients d/dx 
< 0 induced by fatigue pre-cracking delay hydrogen penetration towards rupture sites, and this effect is more pronounced 
for the heaviest fatigue regimes (i.e., with the highest Kmax). This is supported by comparison of the evolutions of the 
average value of the stress gradient <> over the range 0 < x < x+(KQEAC) (Fig. 6b) which delays hydrogen 
transportation into the metal as far as the respective component of the diffusion flux is J proportional to  [8,9]. This 
scale of averaging x+(KQEAC) corresponds to the maximum tensile stress position and possible location of the stress-

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J. Toribio et alii, Frattura ed Integrità Strutturale, 25 (2013) 124-129; DOI: 10.3221/IGF-ESIS.25.18                                                                         
 

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controlled microfracture at hydrogen induced failure in experiments. For the precracking regimes compared in Fig. 6, this 
distance is fairly the same x+(KQEAC) = 8 m, so that it may be supposed to be a characteristic microstructural scale for 
HAC. Therefore, the heaviest fatigue pre-cracking regimes delay the hydrogen accumulation, and thus the progress of 
hydrogen degradation in the course of a rising load EAC test. 
 

  
 
Figure 6: Mechanical factors of the crack growth by HAC: (a) comparison of the TTS extension and the plastic zones associated with 
HAC tests: at lower Kmax-levels, the terminal active plastic zone (open square points) at the end of the HAC test (xAPZ at KQEAC) 

surpasses the cyclic and the monotonic plastic zones created during fatigue precracking (triangles), xY(Kmax) and xY (Kmax) 
respectively; (b) evolutions of the average value of the hydrostatic stress gradient during HAC tests after fatigue pre-cracking at 
Kmax/KIC = 0.45 (dashed line) and 0.80 (solid line). 
 
 
CONCLUSIONS 
 

nvironmentally assisted cracking (EAC) of high-strength steel is clearly influenced by fatigue pre-cracking, since 
cyclic loading affects plastic strains and creates compressive residual stresses in the vicinity of the crack tip.  
Cyclic accumulation of plastic strain and compressive residual stresses improve the EAC behavior through 

increase of the failure load in aggressive environment either by: 
(i) Chemical blunting of the crack tip enhanced by accumulated plastic strain in the near-tip area in the case of EAC in the 
anodic regime of localized anodic dissolution (LAD) 
(ii) Delay of hydrogen supply to the fracture process zone near the crack tip by stress-assisted diffusion in the case of 
EAC in the cathodic regime of hydrogen assisted cracking (HAC). 
 
 
ACKNOWLEDGEMENTS 
 

he authors wish to acknowledge the financial support provided by the following Spanish Institutions: Ministry for 
Science and Technology (MCYT; Grant MAT2002-01831), Ministry for Education and Science (MEC; Grant 
BIA2005-08965), Ministry for Science and Innovation (MICINN; Grants BIA2008-06810, and BIA2011-27870) 

and Junta de Castilla y León (JCyL; Grants SA067A05, SA111A07, and SA039A08). 
 
 
REFERENCES 
 
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Building Mater., 10 (1996) 501-505.  
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Treatise on Materials Science and Technology, Embrittlement of Engineering Alloys, Academic Press, New York, 25 
(1983) 235-274. 

[3] Toribio, J., Lancha, A.M., Elices, M., Characteristics of the new tearing topography surface, Scripta Metall. Mater., 25 
(1991) 2239-2244.  

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[4] Toribio, J., Lancha, A.M., Effect of cold drawing on susceptibility to hydrogen embrittlement of prestressing steel, 
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[5] Rice, J.R., Mechanics of crack tip deformation and extension by fatigue, in: Fatigue Crack Propagation, ASTM STP 
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[6] Kanninen, M.F., Popelar, C.H., Advanced Fracture Mechanics, Oxford University Press, New York, (1985). 
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