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                                                             J.T.P de Castro et alii, Frattura ed Integrità Strutturale, 25 (2013) 79-86; DOI: 10.3221/IGF-ESIS.25.12 
 

79 
 

Special Issue: Characterization of Crack Tip Stress Field 
 
  
Is notch sensitivity a stress analysis problem? 
 
 
Jaime Tupiassú Pinho de Castro, Marco Antonio Meggiolaro 
Mechanical Engineering Department, Pontifical Catholic University of Rio de Janeiro (PUC-Rio), Brazil 
 

 
ABSTRACT. Semi–empirical notch sensitivity factors q have been widely used to properly account for notch 
effects in fatigue design for a long time. However, the intrinsically empirical nature of this old concept can be 
avoided by modeling it using sound mechanical concepts that properly consider the influence of notch tip stress 
gradients on the growth behavior of mechanically short cracks. Moreover, this model requires only well-
established mechanical properties, as it has no need for data-fitting or similar ill-defined empirical parameters. 
In this way, the q value can now be calculated considering the characteristics of the notch geometry and of the 
loading, as well as the basic mechanical properties of the material, such as its fatigue limit and crack propagation 
threshold, if the problem is fatigue, or its equivalent resistances to crack initiation and to crack propagation 
under corrosion conditions, if the problem is environmentally assisted or stress corrosion cracking. Predictions 
based on this purely mechanical model have been validated by proper tests both in the fatigue and in the SCC 
cases, indicating that notch sensitivity can indeed be treated as a stress analysis problem. 
 
KEYWORDS. Notch sensitivity; Stress gradient effects; Non-propagating short cracks. 
 
 

 

INTRODUCTION  
 

emi-empirical notch sensitivity factors 0  q  1 have been long used to relate linear elastic (LE) stress 
concentration factors (SCF) Kt  = max/n, to their corresponding fatigue SCF Kf  = 1 + q(Kt – 1) = SL(R)/SLntc(R), 
where max and min are the maximum and minimum LE stress at the notch root caused by n, the nominal stress 

that would act at that point if the notch did not affect the stress field around the notch, whereas SL(R) and SLntc(R) are the 
fatigue limits measured on standard (smooth and polished) and on notched test specimens (TS), respectively, at a given R 
= min/max ratio. Despite their empirical nature, such Kf values are still widely used to quantify notch effects on the fatigue 
strength of structural components [1].  
On the other hand, it is well known that the notch sensitivity in fatigue can be associated with the relatively fast generation 
of tiny non-propagating cracks at notch roots when SL(R)/Kt < n < SL(R)/Kf, see Fig. 1 [2]. Based on this behavior, a 
model has been proposed to calculate the q values from the fatigue behavior of short cracks emanating from notch tips, 
using only relatively simple but sound mechanical principles, which do not require heuristic arguments, neither any 
arbitrary data-fitting parameter [3-5]. In particular, this model does not require a critical distance concept, a good idea 
which originally assumed that the notch sensitivity should be dependent on some (yet never discovered) microstructural 
parameter [6-10]. In fact, to operationalize the critical distance concept it needs in practice to be fitted to the measured 
material properties, not to its microstructural parameters. The alternative explanation proposed here may be appealing for 
those who tackle such problems from a more mechanical viewpoint. Such an approach allowed it to explain notch effects 
not only on fatigue, but also on environmentally assisted cracking problems. Indeed, it is claimed here that notch 
sensitivity exists on such problems as well, and that it can be described using the same techniques successfully applied to 
model the fatigue problem. In fact, this can be done by just considering the proper resistances to crack initiation and to 
crack propagation in the given material/environment pair, both standard well-defined mechanical properties. Data is 
already available to support the proposed model predictions both in fatigue and SCC conditions.    

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Figure 1: Classical data showing that non-propagating fatigue cracks are generated at the notch roots if SL/Kt < n < SL/Kf [2, 7]. 
 
 

ANALYSIS OF NOTCH EFFECTS ON THE FCG BEHAVIOR OF SHORT CRACKS  
 

he generation of non-propagating fatigue cracks shown in Figure 1 indicates that whereas crack initiation by 
fatigue is controlled by the stresses acting at notch tips, the fatigue crack growth (FCG) behavior of short cracks 
emanating from them should be affected by the stress gradients around them too. It also indicates that notch 

sensitivity is caused by the existence of those non-propagating cracks. Indeed, to start a crack at a notch tip and then stop 
it after a short growth, its driving force must decrease in spite of its growing size. As the cracking driving force depends 
on the crack size and on the stress acting on it, the only mechanical explanation for such an apparently odd behavior is 
that the stresses ahead of the notch tip must decrease more than the crack growth contribution. Therefore, the stress 
gradients ahead of the notch tips must be as important as their SCF to understand the notch sensitivity behavior. Indeed, 
based on this sensible argument, even before developing its mechanics it could be claimed that, contrary to the traditional 
practice, for any given material the notch sensitivity value q should depend not only on the notch tip radius , but also on 
its depth b, since both affect the stress gradients around notch tips. This means that shallow and elongated notches of 
same  may have quite different q. But before jumping to conclusions, let’s work out this mechanical model. 
First note that short fatigue cracks must behave differently from long cracks, since their FCG threshold must be smaller 
than the long crack threshold Kth(R) [11], otherwise the stress range  required to propagate them would be higher than 
the material fatigue limit SL(R). Indeed, assuming as usual that the FCG process is primarily controlled by the stress 
intensity factor (SIF) range, K  (a), if short cracks with a  0 had the same Kth(R) threshold of long cracks, their 
propagation by fatigue would require   , clearly a nonsense. Note also that the word “short” is used here to mean 
“mechanical” and not “microstructural” small cracks, since material isotropy is assumed in their modeling, a simplified 
hypothesis corroborated by the tests. The FCG threshold of short fatigue cracks under pulsating loads Kth(a, R  0) can 
be modeled using El Haddad-Topper-Smith (ETS) characteristic size a0 [12], which is estimated from S0  SL(R  0) 
and K0  Kth(R  0). This clever trick reproduces the Kitagawa-Takahashi plot trend [13], see Fig. 2, using a modified 
SIF range K’ to describe the fatigue propagation conditions of any crack, short or long, defined by: 
 

 0( )K a a     , where   
2

0 0 01a K S         (1) 
 

This K’ has been deduced for the Griffith’s plate SIF, K = (a). To deal with other geometries it should be 
rewritten using the non-dimensional geometry factor g(a/w) of the cracked component: 

 

 0( ) ( )K g a w a a     , where    
2

0 0 01 ( )a K g a w S         (2) 
 

But the tolerable stress range  under pulsating loads only tends to the fatigue limit S0 when a  0 if  is the notch 
root (instead of the nominal) stress range. However, most g(a/w) expressions found in tables include the notch SCF, thus 
they use  instead of n as the nominal stress. A clearer way to define the short crack characteristic size a0 when the 
short crack departs from a notch root is to explicitly recognize this practice, separating the geometry factor g(a/w) into two 

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                                                             J.T.P de Castro et alii, Frattura ed Integrità Strutturale, 25 (2013) 79-86; DOI: 10.3221/IGF-ESIS.25.12 
 

81 
 

parts: g(a/w) = (a), where (a) describes the stress gradient ahead of the notch tip, which tends to the SCF as the crack 
length a  0, whereas  encompasses all the remaining terms, such as the free surface correction: 
 

 0( ) ( )K a a a        , where    
2

0 0 01a K S           (3) 
 

 
 

Figure 2: Kitagawa-Takahashi plot describing the fatigue propagation of short and long cracks under pulsating loads (R = 0) in HT80 
steel with K0 = 11.2 MPam and S0 = 575 MPa. 
 
Operationally, the short crack can be better treated by letting the SIF range retain its original form, while modifying the 
FCG threshold expression to become a function of the crack length a, namely K0(a), resulting (under pulsating loads) in: 
 

  0 0 0( )K a K a a a              (4) 
 

The ETS equation can be seen as one possible asymptotic match between the short and long crack behaviors. Following 
Bazant’s idea [14], a more general equation can be used introducing an adjustable parameter   to fit experimental data: 
 

  
1/2

0 0 0( ) 1K a K a a
                (5) 

 

Equations (1) to (4) result from (5) if    2. The bi-linear limit, (a  a0)  S0 for short cracks and K0(a  a0)  K0 
for the long ones, is obtained if g(a/w)  (a)  1 and   .  Most short crack FCP data is fitted by K0(a) curves with 
1.5    8, but   6 better reproduces classical q-plots based on data measured by testing semi-circular notched fatigue 
TS [3-5]. Using (5) as the FCP threshold, then any crack departing from a notch under pulsating loads should propagate if: 
 

    
12

0 0 0( ) 1K a a K a K a a


    


                 (6) 
 

where   1.12 is the free surface correction. As fatigue depends on two driving forces,  and max, (6) can be extended 
to consider max (indirectly modeled by the R-ratio) influence in short crack behavior. First, the short crack characteristic 
size should be defined using the fatigue limit SR and the FCP threshold for long cracks KR  Kth(a >> aR, R), both 
measured or properly estimated at the desired R-ratio: 
 

    
2

R R1 1.12Ra K S             (7) 
 

Likewise, the corresponding short crack FCP threshold should be re-written as: 
 

  
1/2

( ) 1R R RK a K a a
                (8) 

 

According to Tada [15], the SIF of a crack with size a  that departs from a circular hole of radius  given within 1% by: 
 

2 3

6

1.1215 ( ),

0.2 0.3
1( ) 2 2.354 1.206 0.221(1 )(1 ) 1 1 1

IK a x x a

x x x
x xx x x x

   



    


                                 

  (9) 

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So, for circular holes (x  0)  3 and (x )  1/1.12152  0.63. Since to propagate by fatigue any crack its SIF 
must be larger than its threshold, then for pulsating loads: 
 

   
1//2

0 0( ) 1I thK a a K a K a a


    


                  (10) 
 

Note that a0 cannot depend on the stress gradient factor (a/w), otherwise it would not be a material property. The FCG 
criterion can thus be rewritten using two dimensionless functions, one related to the notch stress gradient (a/w), and the 
other g(S0/, a/, K0/S0, ) which includes the applied stress range , and depends on the crack size, on the 
notch radius , on the fatigue resistances K0 and S0, and on the data fitting exponent  (if it is used): 
 

 
   

   
0 0 0 0 0

1/
0

0 0

, , ,
S K S S Ka

a g
S

a K S


 
  

  
   

                       

   (11) 

 

Therefore, if x  a/ and   K0/S0  (a0/), a fatigue crack departing from a Kirsch hole under pulsating loads 
grows whenever (x)/g(S0/, x, , ) > 1. Figure 3 plots some /g functions for several fatigue strength to loading 
stress range ratios S0/ as a function of the normalized crack length x, assuming a small notch root radius compared to 
the short crack characteristic size with  1.40a0, and a material with   1.5 and   6 [5].  
 

 
 

Figure 3: Cracks that can start from the border of a (small) circular hole may propagate by fatigue and then stop if their /g< 1. 
 

For high applied stress ranges , the strength to load ratio S0/ is small, and the corresponding /g curve is always 
higher than 1, so cracks initiate and propagate from this Kirsch hole border without stopping during this process. Small 
stress ranges with load ratios S0/  Kt  3 have /g < 1, meaning that such loads cannot initiate a fatigue crack from 
this hole, and that small enough cracks introduced there by any other means will not propagate at such low loads. 
Intermediate load ranges can initiate and propagate a fatigue crack from this hole border, until the decreasing /g ratio 
reaches 1, where the crack stops because the stress gradient ahead of its small root is sharp enough to eventually force 
KI(a) < Kth(a). Finally, the curve is tangent to the /g  1 line identifies the smallest pulsating stress range that can cause 
crack initiation and propagation (without arrest) from the notch border by fatigue alone. Hence, by definition, it is 
associated to this hole fatigue SCF Kf. Moreover, the abscissa of its tangency point gives the largest non-propagating crack 
size that can arise from it by fatigue alone, amax. For any other /a0, , and  combination, Kf and amax can always be found 
by solving the system  
 

 
   
   

max max

max max

, , ,1

0 , , ,

f

f

x g x Kg

g x x x g x K x

  
   

  
         

     (12) 

 

Kirsch holes induce relatively mild stress gradients. Larger holes compared with the short crack characteristic size, with 
radii  >> a0, are associated to small  values and do not induce short crack arrest. That is a nice way to mechanically 

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83 
 

interpret the notch sensitivity concept. In other words, if the system {/g  1, (/g)x  0} is solved for a given  and 
several tip radii using K0/S0, then the notch sensitivity factor q is obtained by: 
 

( , ) [ ( , ) 1] ( 1)f tq K K               (13) 
 

This approach has 4 advantages: (i) it is an analytical procedure; (ii) it considers the effect of the fatigue resistances to 
crack initiation and propagation on q; (iii) it can use the exponent  used to modify the original ETS model to better fit 
short FCG data; and (iv) it can be easily extended to other notch geometries. For example, the SIF of cracks that depart 
from a semi-elliptical notch with semi-axles b and c, with b collinear with the crack a and perpendicular to the (nominal) 
stress n, can be described by: 
 

 I ,K F a b c b a                (14) 
 

where   1.1215 is the free surface correction factor and F(a/b, c/b) is the geometrical factor associated to the notch 
stress concentration effect. Such notches SCF Kt is given by [15]: 
 

  2.51 2 1 0.1215 (1 )tK b c c b               (15) 
 

Using s  a/(a + b) two analytical expressions for F(a/b, c/b) were obtained in [3] by fitting results obtained by a series of 
finite elements (FE) analyses for several types of semi-elliptical notches: 
 

   

 

2 2

2
22

2

, , 1 exp( ) ( ),

1 exp( )
( , ) , 1 exp( ) ,

t tt t

s
t

t t t
t

F a b c b f K s K K s K s c b

K s
F a b c b f K s K K c b

K s



         
            

    (16) 

 

Note that traditional notch sensitivity estimates, like Peterson’s q  (1 + /)-1, where  is a length parameter obtained by 
fitting only 7 experimental points, suppose that the notch sensitivity depends only on the notch tip radius  and on the 
steel tensile strength (and only on  for Al alloys). The model proposed here, on the other hand, recognizes that q 
depends on , S0, and K0 (and in , if it is used). There are reasonable relations between S0 and SU, the ultimate tensile 
strength, but none between K0 and SU. This means that two steels of same SU, but very different K0, should behave 
identically according to Peterson-like q estimates, for example, not a reasonable assumption. Further details on this model 
are available on [3], and experimental evidence that supports its predictions in fatigue is presented in [4-5]. Its extension 
for stress corrosion cracking conditions is developed in [16]. 
 
 
INFLUENCE OF SHORT CRACKS ON THE FATIGUE STRENGTH OF STRUCTURAL COMPONENTS 
 

he traditional SN and N fatigue design methods are used to analyze supposedly crack-free pieces, but very often 
it is not possible to fulfill this requisite in practice. In fact, it is impossible to guarantee that a component is really 
free of cracks smaller than the detection threshold of the non-destructive method used to identify them. 

Nevertheless, most structural components are still designed against fatigue crack initiation using procedures that do not 
recognize such small cracks. Hence, their “infinite life” predictions may become unreliable when they are introduced by 
any means during manufacture or service, and not quickly detected and properly removed. But while large cracks may be 
easily detected and dealt with, small cracks may pass unnoticed, even in careful inspections. Therefore, structural 
components that must last for very long fatigue lives should be designed to be tolerant to undetectable short cracks, since 
continuous work under fatigue loads cannot be guaranteed if any of the cracks they might have can somehow propagate 
during their service lives. 
Despite being self-evident, this requirement is still not included in most fatigue design routines used in practice. Indeed, 
most long-life designs just intend to maintain the service stresses at the structural component critical point below its 
fatigue limit,  < SL(R)/F, where F is a suitable safety factor. Such calculations can become quite involved when 
designing e.g. against fatigue damage caused by random non-proportional loads, but their safe-life philosophy remains the 
same. However, in spite of not recognizing any cracks, most long-life designs work just fine. This means that they are 
somehow tolerant to undetectable or to functionally admissible short cracks. But the question “how much tolerant” 

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cannot be answered by SN or N procedures alone. Such problem can be avoided by adding short crack concepts to their 
“infinite” life design criteria which, in its simplest version, may be given by [5]: 
 

  12( ) 1R F RK a g a w a a                              (17) 
 

where  
1/2

( ) 1R R RK a K a a
        , and   

2
1R R Ra K S           

Since the fatigue limit SR SL(R) already reflects the effect of the microstructural defects inherent to the material, 
equation (17) complements it by describing the tolerances to small cracks that may pass unnoticed in actual service 
conditions. The practical usefulness of this sensible criterion is well illustrated by a practical example, as follows.  
Due to a rare manufacturing problem, a batch of an important component left the factory with tiny surface cracks (only 
detectable by a microscope), causing some unexpected and embarrassing failures. Hence, it became necessary to properly 
quantify the actual effect of such tiny cracks in that component fatigue strength. Assume its rectangular cross-section has 
2 by 3.4mm; its (uncracked) fatigue limit is SL = 246MPa; and it is made from steel with SU = 990MPa. This measured 
fatigue limit is about ¼ of the steel SU/4, whereas it would be traditionally estimated by SL  SU/2  495MPa. This 
difference may be due to a surface finish factor ksf  0.5, a value between those proposed by Juvinall for SU  1GPa steels 
with cold-drawn (ksf  0.45) and machined surfaces (ksf  0.7) [17]. The surface finish should not affect cracks, but as this 
difference could be due to other factors too, like tensile residual stresses, the only safe option is to use SL = 246MPa to 
evaluate the tiny crack effects. Therefore, by Goodman SL(R) = SR = SLSU(1 – R)/[SU(1 – R) + SL(1 + R)] for R1 (or 
m  0), for example. The FCG threshold KR is also needed to model short crack effects, but if data is not available, as in 
this case, it must be estimated e.g. by KR(R  0.17)  K0  6MPam and KR(R > 0.17)  7(1 - 0.85R) [18]. This practice 
increases the predictions uncertainty, but it is the only option available. Besides, it tends to be conservative. Moreover, it 
assumes that KR(R < 0)K0, a safe estimate too (except if the load history contained severe compressive underloads 
which might accelerate the crack, not the case here.) Using the SIF of an edge cracked strip of width w loaded in mode I, 
then the tolerable stress ranges under pulsating loads shown in Fig. 4 are estimated within a fatigue safety factor F as: 
 

 0
0 12

3 02[ 0.752 2.02 0.37(1 sin ) ]sec tan 1
2 2 2

FK a

aa a a w a
w aw w w a



 


  



 

       
  

       (18) 

 

 
Figure 4: Larger stress ranges tolerable under several R–ratios by the analyzed component considering it contains an edge crack with 
size a, for w  3.4mm,   1.12, K0  6MPam, a0  59m,   6, and F  1.6. 
 
 
NOTCH SENSITIVITY IN ENVIRONMENTALLY ASSISTED CRACKING PROBLEMS 
 

he behavior of materials on aggressive environments is an important problem for many industries, because the 
costs and specially the delivery times for special EAC-resistant alloys keep increasing. Major problems occur e.g. in 
the oil industry, where oil and gas fields can contain considerably amounts of H2S, and in the aeronautical T 

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                                                             J.T.P de Castro et alii, Frattura ed Integrità Strutturale, 25 (2013) 79-86; DOI: 10.3221/IGF-ESIS.25.12 
 

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industry, where very light structures must operate in saline environments. But environmentally assisted cracking problems 
have been treated so far by simplistic structural integrity assessment procedures based on an overly conservative policy of 
totally avoiding material-environment pairs susceptible to EAC conditions. When such conditions are unavoidable during 
the service life of the structural component in question, the standard solution is just to choose a nobler material to build it, 
one that is resistant or immune to crack initiation and propagation by EAC in the operational environment. Alternatively, 
the solution may be to recover the structural component surface with a suitable properly adherent and scratch resistant 
EAC-resistant coating. But in many cases there are no such coatings available in the market.  
Such inflexible design criteria may be safe, but they can also be too conservative if the material is summarily disqualified 
when it may suffer EAC in the service environment, without considering any stress analysis issues. Such decisions may 
cause severe cost penalties. Indeed, even though EAC conditions may still be difficult to define, due to the number of 
metallurgical, chemical, and in particular mechanical variables that affect them, structural integrity assessment procedures 
should always be used on the design stage to define a maximum tolerable flaw size. In fact no crack can grow unless 
driven by a tensile stress, caused by the superposition of applied loads, residual stresses induced by previous loads or 
overloads, and maintenance or manufacturing procedures. Thus EAC cracks cannot be properly evaluated neglecting the 
stress and strain fields that may drive them. 
But such uneconomical decisions can be avoided, since we already know how different the behavior of deep and shallow 
fatigue cracks is, and how it can be treated in structural design. Therefore, it is now possible to propose an extension of 
the proved criteria for accepting shallow fatigue cracks to environmentally assisted cracking problems, assuming they also 
present a notch sensitivity behavior that can be mechanically described. If cracks behave well under EAC conditions, then 
a Kitagawa-like diagram can be used to quantify tolerable stresses, using the material EAC resistances to define a “short 
crack characteristic size under EAC conditions” by: 
 

  20 (1/ ) IEAC EACa K S             (19) 
 

In this way all corrosion features are assumed to be properly described by the resistance to crack propagation KIEAC and by 
the resistance to crack initiation SEAC under fixed stress conditions in the analyzed material-environment pair. In other 
words, this model supposes that the mechanical parameters that govern the environmentally assisted cracking problem 
behave analogously to the equivalent parameters Kth(R) and SL(R) that control the fatigue problem, see Fig. 5. 
 

 
 

Figure 5: A Kitagawa-Takahashi-like plot proposed to describe the environmentally assisted cracking behavior of short and deep flaws 
for structural design purposes. 
 
Consequently, if cracks loaded under EAC conditions behave mechanically as they should, i.e. if their driving force is 
indeed the stress intensity factor applied on them; and if the chemical effects that influence their behavior are completely 
described by the material resistance to crack initiation from smooth surfaces quantified by SEAC, and by its resistance to 
crack propagation measured by KIEAC; then it can be expected that EAC cracks may depart from sharp notches and then 
stop, due to the stress gradient ahead of the notch tips, eventually becoming non-propagating cracks, as it occurs in the 
fatigue case. Hence, if the size of non-propagating short cracks can be calculated using the same procedures useful for 
fatigue case, then the resistance to that kind of defect can be properly quantified using an EAC notch sensitivity factor in 
structural integrity assessments. Therefore, a criterion for the maximum tolerable crack size under EAC conditions can be 
proposed as: 
 

1
2

max 0(1 ) (1 ) ( )IEACa K a a a g a w
 


            (20) 

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J.T.P de Castro et alii, Frattura ed Integrità Strutturale, 25 (2013) 79-86; DOI: 10.3221/IGF-ESIS.25.12                                                                   
 

86 
 

 
CONCLUSIONS 
 

 generalized El Haddad-Topper-Smith’s parameter was used to model the crack size dependence of the threshold 
stress intensity range for short cracks, as well as the behavior of non-propagating environmentally assisted cracks. 
This dependence was used to estimate the notch sensitivity factor q of shallow and of elongated notches, from 

studying the propagation behavior of short non-propagating cracks that may initiate from their tips. It was found that the 
notch sensitivity of elongated slits has a very strong dependence on the notch aspect ratio, defined by the ratio c/b of the 
semi-elliptical notch that approximates the slit shape having the same tip radius. These predictions were calculated by 
numerical routines. Based on this promising performance, a criterion to evaluate the influence of small or large surface 
flaws in fatigue and in environmentally assisted cracking problems was proposed. Such results indicate that notch 
sensitivity can indeed be properly treated as a mechanical problem. 
 
 
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