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V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55                                                               
 

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Focussed on: Fracture and Structural Integrity related Issues 
 

 
 
  
Fatigue crack behavior on a Cu-Zn-Al SMA 
 
 
V. Di Cocco, F. Iacoviello 
Università di Cassino e del Lazio Meridionale, DICeM, Via G. Di Biasio, 43, 03043, Cassino (FR), Italy 
v.dicocco@unicas.it 
 
S. Natali, V. Volpe 
University of Rome “Sapienza”, DICMA, Via Eudossiana 18, Rome, Italy 
stefano.natali@uniroma1.it 
 

 
ABSTRACT. In recent years, mechanical property of many SMA has improved in order to introduce these alloys 
in specific field of industry. Main examples of these alloys are the NiTi, Cu-Zn-Al and Cu-Al-Ni which are used 
in many fields of engineering such as aerospace or mechanical systems. Cu-Zn-Al alloys are characterized by 
good shape memory properties due to a bcc disordered structure stable at high temperature called β-phase, 
which is able to change by means of a reversible transition to a B2 structure after appropriate cooling, and 
reversible transition from  B2 secondary to DO3 order, under other types of cooling. In β-Cu-Zn-Al shape 
memory alloys, the martensitic transformation is not in equilibrium at room temperature. It is therefore often 
necessary to obtain the martensitic structure, using a thermal treatment at high temperature followed by 
quenching. The martensitic phases can be either thermally-induced spontaneous transformation, or stress-
induced, or cooling, or stressing the β- phase. Direct quenching from high temperatures to the martensite phase 
is the most effective because of the non-diffusive character of the transformation. The martensite inherits the 
atomic order from the β-phase. Precipitation of many kinds of intermetallic phases is the main problem of 
treatment on cu-based shape memory alloy. For instance, a precipitation of α-phase occurs in many low 
aluminum copper based SMA alloy and presence of α-phase implies a strong degradation of shape recovery. 
However, Cu-Zn-Al SMA alloys characterized by aluminum contents less than 5% cover a good cold machining 
and cost is lower than traditional NiTi SMA alloys. In order to improve the SMA performance, it is always 
necessary to identify the microstructural changing in mechanical and thermal conditions, using X-Ray analyses. 
In this work a Cu-Zn-Al SMA alloy obtained in laboratory has been microstructurally and metallographically 
characterized by means of X-Ray diffraction and Light Optical Microscope (LOM) observations.  Furthermore 
a fatigue crack propagation and fracture surface scanning electron microscope (SEM) observations have been 
performed in order to evaluate the crack path and the main crack micromechanisms. 
  
KEYWORDS. SMA; Cu alloys; Structure; Fatigue crack propagation. 
 
 
 
INTRODUCTION  
 

ince the discovery of the first shape memory alloy (Au-Cd, in 1938), many alloys characterized by memory property 
have been studied. Often, the chemical composition was characterized by the presence of rare metals with low 
mechanical properties and SMA effects that did not allow an industrial development on a large scale. In recent S 



 

                                                             V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55 
 

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years, mechanical properties of many SMA have improved, allowing to introduce these alloys in specific field of industry. 
Main examples of these alloys are the NiTi, Cu-Zn-Al and Cu-Al-Ni which are used in many fields of engineering such as 
aerospace or mechanical systems [1]. 
Many scientific papers are published mainly on NiTi alloy (Nitinol), analyzing both the microstructure peculiarities and the 
thermo-mechanical properties [2]. However, this alloy is characterized by some processing difficulties that imply an 
increase of costs. The main difficulty is due to presence of titanium that makes it readily oxidisable and, because of its 
good mechanical properties, it must be hot worked. 
In the last decades, different shape memory alloys have been optimized, such as the copper-zinc-aluminum (ZnCuAl), 
copper-aluminum-nickel (CuAlNi), nickel-manganese-gallium (NiMnGa), nickel-titanium (NiTi), and other SMAs 
obtained alloying zinc, copper, gold, iron, etc.. However, the near equiatomic NiTi binary system shows the most 
interesting properties and it is currently used in an increasing number of applications in many fields of engineering, for the 
realization of smart sensors and actuators, joining devices, hydraulic and pneumatic valves, release/separation systems, 
consumer applications and commercial gadgets [1, 2]. Due to their good biocompatibility, another important field of SMA 
application is medicine, where the pseudo-elasticity is mainly exploited for the realization of several components such as 
cardiovascular stent, embolic protection filters, orthopedic components, orthodontic wires, micro surgical and endoscopic 
devices [3]. 
From the microstructural point of view, shape memory and pseudo-elastic effects are due to a reversible solid state 
microstructural transition from austenite to martensite, which can be activated by mechanical and/or thermal loads [4]. 
Copper-based shape-memory alloys are very sensitive to thermal effects, and it is possible that in thermal cycles its 
properties change (e.g., shape-recovery ratio, transformation temperatures, crystal structures, hysteresis and mechanical 
behavior). 
Cu-Zn-Al alloys are characterized by good shape memory properties due to a bcc disordered structure stable at high 
temperature called β-phase, which is able to change by means of a reversible transition to a B2 structure after appropriate 
cooling, and reversible transition from  B2 secondary to DO3 order, under other types of cooling. In β-Cu-Zn-Al shape 
memory alloys, the martensitic transformation is not in equilibrium at room temperature. It is therefore often necessary to 
obtain the martensitic structure, using a thermal treatment at high temperature followed by quenching. The martensitic 
phases can be either thermally-induced spontaneous transformation, or stress-induced, or cooling, or stressing the β- 
phase. Direct quenching from high temperatures to the martensite phase is the most effective because of the non-
diffusive character of the transformation. The martensite inherits the atomic order from the β-phase [5]. 
Precipitation of many kinds of intermetallic phases is the main problem of treatment on Cu-based shape memory alloy. 
For instance, a precipitation of α-phase occurs in many low aluminum copper based SMA alloy and presence of α-phase 
implies a strong degradation of shape recovery [6]. However, Cu-Zn-Al SMA alloys characterized by aluminum contents 
less than 5% cover a good cold machining and cost is lower than traditional NiTi SMA alloys. 
Other investigations carried out on CuZnAl alloys, showed a strain influence on the macroscopic behavior and on 
martensite morphology. Martensitic transformation occurs initially in deformed material and the manufact shape follows 
the transformation [7]. Larger grains dimensions allow an easier transformation process, allowing the growth of 18R 
martensite [8]. 
In this work a Cu-Zn-Al SMA alloy obtained in laboratory has been microstructurally and metallographically characterized 
by means of X-Ray diffraction and Light Optical Microscope (LOM) observations. These analyses have performed under 
load conditions in order to identify the behavior of alloy. Furthermore fatigue crack propagation and fatigue crack paths 
were investigated by means of a scanning electron microscope (SEM). 
 
 
MATERIAL AND PROCEDURES 
 

n this work, a CuZnAl pseudo-elastic alloy, made in laboratory by using controlled atmosphere furnace and 
characterized by chemical composition shown in Tab. 1, has been investigated focusing the fatigue crack propagation 
paths.  

 

Cu Zn Al Other 

73.00 21.80 5.04 0.16 
 

Table 1: Chemical composition of Cu-Zn-Al investigated alloy. 
 

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V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55                                                               
 

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Prior to evaluate mechanical properties, crono-amperometric tests have been performed in order to evaluate the 
homogeneity of material and its electrochemical behaviours, using a 0.1 mol NaCl solution at -50mV/SCE for 1800s [9]. 
In order to evaluate the structure transformation, a customized testing machine equipped with a removable loading frame 
was used to perform X-Ray analyses at fixed values of applied load and/or deformations. XRD measurements were 
carried out by using a Philips X-PERT PRO diffractometer equipped with vertical Bragg-Brentano powder goniometer. A 
step-scan mode was used in the 2θ range from 25° to 90° with a step width of 0.02° and a counting time of 3 s per step, 
and receiving slit 0.02 mm. The employed radiation was monochromated Cu Kα (40kV – 40 mA).  
Fatigue crack propagation tests were performed by using CT specimens obtained by machining the cast ingots according 
to ASTM E 647 prescriptions. Both lateral surfaces have been metallographically prepared to Scanning Electron 
Microscope (SEM) observations. A servohydraulic testing machine has been used in order to evaluate fatigue crack 
propagation using the ASTM E 647 testing conditions. 
Fatigue cracks propagation tests are performed by using the following conditions: 

1) P = const. 
2) R = Pmin/Pmax = 0.1 and 0.5. 
3) Load: Sinusoidal waveform. 
4) Load frequency = 30Hz. 
5) Lab conditions. 

Finally, fracture paths have been analysed by means of a SEM in order to evaluate the loading conditions influence. 
 
 
RESULTS AND COMMENTS 
 

OM observations show a traditional structure whose grain diameter mean value is about 700 m. Alloy 
microstructure is not completely homogeneous and grains are characterized by a needle like morphology as shown 
in Fig. 1. 

 
 

 
 

Figure 1: Etched surface of the investigated material. 
 
Needles microstructure is oriented: needles only partially cover the diameter of the prior austenitic grains. No subgrains 
are observed. 
The alloy inhomogeneities have been highlighted by crono-amperometric tests which the results are shown in Fig. 2a [9]. 
The electrochemical behaviour is characterized by a decrease of current due to presence of corrosion products on the 
etched surface and to the consequent lower passive property. Corrosion products are not homogenous due to the 
microstructure differences between grains bulk and boundary. 

L 



 

                                                             V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55 
 

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4.E‐03

5.E‐03

6.E‐03

7.E‐03

8.E‐03

9.E‐03

1.E‐02

0 200 400 600 800 1000 1200 1400 1600 1800 2000

C
u
rr
e
n
t 
d
e
n
si
ty
 [
A
/c
m

2
]

Time [s]

a) b) 
 

Figure 2: Electrochemical behavior and microstructure etched of material: a) polarization curve, b) microstructure of boundary grain. 
 
 “Acicular like” zones near grains boundaries are shown in Fig. 2b. Evidence of microstructure transitions are in Fig. 3, 
where two diffractograms show respectively the undeformed and the deformed at eng = 5% specimen.  
 

0

200

400

600

800

1000

1200

1400

40 50 60 70 80 90

In
te
n
si
ty

2θ [°]

Serie1

Eng. Epsilon 5%

εeng = 0%
εeng = 5%

 
Figure 3: Diffraction spectra. 

 
The undeformed specimen spectrum shows four peaks corresponding to 42.35°, 43.71°, 70.39°, 80.23° that correspond to 
two different phases [10]: 

- Cubic B2 phase (like CsCl lattice), sometimes named as β2 that take place at 550°C, but measured peaks are not 
sufficient to evaluate the cell parameter; 

- Cubic L21 phase (like Cu2MnAl), sometimes named as β3 that take place at 320°C, characterized by cell parameter 
about a=5.8707 Ǻ.  

The eng = 5% deformed specimen shows also four peaks but corresponding to different diffraction angles (42.27°, 
43.43°, 43.85° and 85.71°). Presence of these peaks are compatible with presence of two phases [11, 12]: 

- Austenite β3 (L21 structure not stress induced transformed), characterized by cell parameter about a=5.8707 Ǻ as 
in the undeformed state.; 

- Martensite M18R structure, characterized by a=4.4189 Ǻ, b=5.332 Ǻ, c=38.8 Ǻ and angle β=89.7°. 
Peaks modifications (considering both angles and intensity) show the mechanical deformation influence on the 
microstructure modifications.  
Fatigue crack propagation results (da/dN-K) at R=0.1 and R=0.5 are shown in Fig. 4a.  



 

V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55                                                               
 

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Focusing the R=0.1 results, five different stages can be observed (Fig. 4b). Considering the increase of the crack tip plastic 
zone radious with the increase of the applied K, a possible crack propagation micromechanism is proposed (to be 
confirmed by further experimental and numerical analyses): 

- stages 1 and 2: the specimen is almost completely austenitic, with the exception of the crack tip plastic zone, but, 
considering the applied K values, its radious be considered as negligible; corresponding to Kmin values, 
considering the typical SMA stress-strain behaviour (Fig. 5), almost all the crack tip plastic zone  reverts from 
martensite to austenite (point A).  

- stage 3: transition 
- stages 4 and 5: the higher applied K values imply an increase of the radious of the crack tip plastic zone 

(martensitic!). Corresponding to Kmin values, the radious of the crack tip plastic zone that does not reverts its 
microstructure is  larger than the one observed in stage 1 and 2 (Fig. 5, point B). In this zone, the stress induced 
martensite (obtained corresponding to Kmax)  remains unchanged. 

 
 

4.0E‐09

4.0E‐08

4.0E‐07

3 30

d
a
/d
N
 [
m
/c
y
le
]

ΔK [MPa√m]

R=0.1

R=0.5

4.0E‐09

4.0E‐08

4.0E‐07

3 30

d
a
/d
N
 [
m
/c
y
le
]

ΔK [MPa√m]

R=0.1

R=0.5

Stage 1

Stage 2

Stage 3

Stage 4

Stage 5

Stage 1

Stage 2

Stage 3

 
a) b) 

Figure 4: Fatigue crack propagation results: a) da/dN behavior, b) stages. 
 
 

For R=0.5, only three “traditional” stages are observed. This is probably due to the higher Kmin values and to the larger 
extent of the crack tip plastic zone, also corresponding to lower K values,  if compared to R = 0.1: martensite obtained 
corresponding to Kmax at the crack tip remains unchanged also corresponding to Kmin. 
 
 

 

Martensite

Austenite

& 

Martensite 

Austenite

ε

σ
 

B 

A 

 
Figure 5: Scheme of σ-ε curve of SMA materials with structure transitions. 

 



 

                                                             V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55 
 

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a) b) 
 

 

c) d) 
 

Figure 6: Fatigue crack path at R=0.1: a) and b) two different values of crack extension, c) main and secondary path corresponding to 
boundary grains, d) high magnification in a zone in the front of conventional crack tip. 
 
 
For R = 0.1, the crack path is characterized both by the presence of linear paths (Fig. 6a) and by the presence of a sort of 
“zig-zag” propagation paths (Fig. 6b), with secondary paths that after some hundreds of microns join again the main 
crack. Presence of “zig-zag” paths are probably due to presence of inhomogeneities boundary grains (brittle precipitates) 
as shown in Fig. 2b. Secondary crack paths are due to a different interaction of main path to boundary grains, as shown in 
Fig. 6c. In this case, the main crack is almost to 90° respect the boundary grain and the brittle precipitates deviate the path 
with an angle that that is analogous to the precipitates angle observed in Fig. 2b. Finally, short microcracks are observed 
ahead of the crack tip under loading conditions (Fig. 6d), probably due to the stress field around the crack and the 
consequent microstructure stress-induced transformation.  
Considering R=0.5, analogously to the results obtained for R = 0.1, crack paths (Fig. 7a and b) are characterized by the 
presence of the “zig-zag” path propagation and by the presence of secondary cracks that can be observed at boundary 
grains (Fig. 7c). The main differences can be summarized as follows: 
- Microcracks are not observed ahead of the crack tip. This is probably due to the absence of stage 4 and the crack tip 
stress field generate a transformed structure characterized by a homogenous behaviour;  
- Secondary cracks do not join again the main crack (Fig. 7d).  
 
 



 

V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55                                                               
 

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a) b) 
 

  
 

c) d) 
 

Figure 7: Fatigue crack path at R=0.5: a) and b) two different values of crack extension, c) a zone in the front of conventional crack 
tip, d) damaged zone near the main crack path. 
 
 
CONCLUSIONS 
 

n this work, the fatigue crack propagation in a Cu-Zn-Al shape memory alloy, obtained in laboratory, has been 
evaluated in correlation to main crack micromechanisms by using Scanning Electron Microscopy. Fatigue crack 
propagation has been carried out by means of traditional hydraulic fatigue crack machine tests and CT specimens, at 

ΔP=constant, R=0.1 and R=0.5 in lab conditions (ASTM E 647). 
For R=0.1, the ability for material to change its structure under load generates a particular fatigue crack propagation 
behavior characterized by five different stages. Corresponding to the third stage, microstructure transformation takes 
place. 
Considering the crack paths, the following conclusions can be summarized: 
1) da/dN-K results are strongly influenced by the R  value, probably due to peculiar mechanical behavior of the 

investigated alloy, with a possible reversion of the stress induced martensite (obtained for Kmax) to austenite, 
depending on the loading conditions (R and K values) 

2) main crack path is characterized by the presence of a “zig-zag” path, probably due to the presence of brittle 
inhomogeneities at boundary grains; the angle between main crack and boundary grains determine the initiation of 
secondary cracks; 

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                                                             V. Di Cocco et alii, Frattura ed Integrità Strutturale, 30 (2014) 454-461; DOI: 10.3221/IGF-ESIS.30.55 
 

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3) for R = 0.1, corresponding to “Stage 4”, a stress induced microstructure modification is obtained as a consequence of 
the crack tip stress field, with the consequent initiation of very short microcracks; 

4) For R=0.5, no microcracks are observed ahead of the crack tip; 
5) For R=0.5, Secondary cracks do not join again the main crack. 
 
 
REFERENCES 
 
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[3] Chen, B., Liang, C., Fu, D., Pitting corrosion of Cu-Zn-Al shape memory alloy in simulated uterine fluid, J. Mater. 

Sci. Technology, 21(2) (2005) 226-230.3 
[4] Liu, Y., Tan, G.S., Formation of interfacial voids in cast and micro-grained γ′-Ni3Al during high temperature 

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[5] Suzuki, T., Kojima, R., Fujii, Y., Nagasawa, A., Acta Metall., 37 (1) (1989) 163–168.3 
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Scripta Materialia, 58 (2008) 599-601.7 
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[10] Rapacioli, R., Ahlers, M., Ordering in ternary β CuZnAl alloys, Scripta Met., 11 (1977) 1147-1150. 
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