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Sismabeton: a new frontier for ductile concrete 

 
Bernardino Chiaia, Alessandro P. Fantilli, Paolo Vallini 
Politecnico di Torino, Dep. of Structural and Geotechnical Engineering Corso Duca degli Abruzzi, 24 -10129 Torino, Italy 
fantilli@polito.it, vallini@polito.it, chiaia@polito.it  
 

 
RIASSUNTO. I calcestruzzi fibrorinforzati ed autocompattanti (definiti Sismabeton) manifestano una elevata 
duttilità non solo in trazione ma anche in presenza di sforzi compressione. Ciò e messo in evidenza nel presente 
lavoro attraverso la misura della risposta meccanica, in regime di compressione triassiale, di calcestruzzi ordinari 
(NC) ed autocompattanti (SC) con e senza fibre. In strutture semplicemente compresse, la presenza del 
Sismabeton è da sola sufficiente a garantire un confinamento attivo uniforme. 
 
ABSTRACT. The high ductility of Fiber Reinforced Self-consolidating concrete (called Sismabeton) can be 
developed not only in tension but also in compression. This aspect is evidenced in the present paper by 
measuring the mechanical response of normal concrete (NC), plain self-compacting concrete (SC) and 
Sismabeton cylindrical specimens under uniaxial and triaxial compression. The post-peak behaviour of these 
specimens is defined by a non-dimensional function that relates the inelastic displacement and the relative stress 
during softening. Both for NC and SC, the increase of the fracture toughness with the confinement stress is 
observed. Conversely, Sismabeton shows, even in absence of confinement, practically the same ductility 
measured in normal and self-compacting concretes with a confining pressure. Thus, the presence of Sismabeton 
in compressed columns is itself sufficient to create a sort of active distributed confinement. 
 
KEYWORDS. Fiber-reinforced concrete, self-compacting concrete, confining pressure, triaxial tests, fracture 
toughness. 
 
 
 
INTRODUCTION 
 

everal reinforced concrete (RC) structures fail via concrete crushing in compressed zones. This is the case, for 
instance, of over-reinforced concrete beams, like those in four point bending tested by Mansur et al. [1]. When 
fiber-reinforced, the post-peak behaviour of such members is remarkably more ductile than that observed in beams 

having the same geometry, the same steel rebars, and the same bearing capacities, but made of normal concrete (NC) 
without fiber. Thus, when crushing occurs, the type of concrete rules both the mechanical response and the ductility of 
RC structures. 
The experimental campaign conducted by Khayat et al. [2] on highly confined RC columns, subject to concentric 
compression, also confirms the influence of the cement-based composites on the structural performances. More precisely, 
for a given cross-section, the load vs. average axial strain diagrams appear more ductile in the case of columns made of 
self-compacting concrete (SC) than in NC columns.  
These experimental observations can be usefully applied to designing RC compressed columns in seismic regions. 
According to Eurocode 8 [3], if a required ductility cannot be attained because concrete strains are larger than 0.35% , a 
compensation for the loss of resistance due to crushing can be achieved by means of an adequate confinement. 
Such a confinement, usually provided by transversal steel reinforcement (i.e., stirrups), and indicated by the confining 
pressure 3 (Fig.1), allows designers to consider a more ductile stress strain (c-c) relationship in compression. For 
instance, Fig.1 shows the so-called parabola-rectangle diagrams proposed by Eurocode 2 [4] for confined and unconfined 
concretes.  

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Short steel fibers randomly dispersed in a cement-based matrix can generate confining pressures comparable with that of 
stirrups. The experimental campaign of Ganesan and Ramana Murthy [5], performed on short confined columns with and 
without fibers (Fig.2a), investigates on this aspect. As shown in Fig.2b, the applied load- average strain (P-cm) diagram of 
RC columns, made with ordinary concrete and a transversal reinforcement percentage equal to s=1.6%, is more or less 
similar (in terms of strength and ductility) to that of fiber-reinforced (FRC) columns, made with a reduced quantity of 
stirrups (s =0.6%) and FRC (volume fraction Vf = 1.5%, aspect ratio L/ = 70). 
 

 
Figure 1: The stress-strain relationship of compressed concrete with and without confinement [4]. 

 

 
Figure 2: The columns tested by Ganesan and Ramana Murthy [5]. 

 
Although fiber-reinforcements have been introduced in order to increase the ductility of cement-based composites in 
tension, they can also provide a sort of confinement, and therefore higher ductility in compression. For this reason, when 
a better fiber matrix bond can be achieved, like the Fiber-Reinforced Self-compacting Composites [6], higher compressive 
fracture toughness should be expected. To confirm such a conjecture, the post-peak responses of different cementitious 
composites under uniaxial and multi-axial compression are here investigated.  
 
 
POST-PEAK RESPONSE OF CONCRETE UNDER COMPRESSION 
 

he stress-strain relationships of concrete and quasi-brittle materials in compression (Fig.3a) can be divided into 
two parts (Fig.3b). In the first part, when the stress is lower than the strength fc (and c < c1 ), the specimen can be 
considered undamaged. In the case of plain concrete, the ascending branch of c-c can be defined by the Sargin’s 

relationship proposed by CEB-FIP Model Code [7]. As soon as the peak stress is reached, localized damage develops and 
strain softening begins. In this stage, the progressive sliding of two blocks of the cement-based material is evident. In 
Fig.3a, the angle between the vertical axis of the specimen and the sliding surfaces is assumed to be =18°. This value, as 
measured in many tests, can be also obtained through the Mohr-Coulomb failure criterion, if the tensile strength is 

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assumed to be 1/10 of compression strength ( fct = 0.1 fc ). The inelastic displacement w of the specimen, and the 
consequent sliding s of the blocks along the sliding surface, are the parameters governing the average post-peak 
compressive strain c of the specimen (Fig. 3). 
Referring to the specimen depicted in Fig. 3a, post peak strains can be defined by the following equation [8]: 
 

H

w

EH

w

c

c
celcc 





 1,          (1) 

 

where, c1 = strain at compressive strength fc ; c = stress decrement after the peak; H = height of the specimen (see 
Fig. 1b). 
 

 
 

Figure 3: The post-peak response of quasi-brittle materials in compression. 
 

According to test measurements [8, 9], the post-peak slope of c-c increases in longer specimens (Fig.3b), due to the w/H 
ratio involved in the evaluation of c [Eq.(1)]. The stress decrement c can be defined as: 
 

  wFff cccc  1          (2) 
 

where, F(w) = non-dimensional function which relates the inelastic displacement w and the relative stress c / fc during 
softening (Fig.3c); fc = compressive strength (assumed to be positive). 
Substituting Eq.(2) into Eq.(1), it is possible to obtain a new equation for c : 

 

  
H

w

E

wFf

c

c
cc 




1
1                  for   c > c1       (3) 

 

Eq.(3), adopted for the post-peak stage of a generic cement-based material in compression, is based on the definition of 
F(w), which has to be considered as a material property [8-9]. In all cement-based composites, this function should be 
evaluated experimentally on cylindrical specimens, as performed by Jansen and Shah [9] for plain concrete (Fig.3c).  
Fig.4a shows the F(w) relationships proposed by Fantilli et al. [10]. It consists of two parabolas and a constant branch:  
 

                               1 2 wbwa
f

wF
c




  
a

b
w




2
0for    (4a) 

             
44

4
1 2

2

22










 















 w

b

a
w

b

a

a

b

f
wF

c


 

a

b
w

a

b





2
for    (4b) 

                                                       0
cf

wF


  
a

b
w for     (4c) 

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The parabolas are both defined by the same coefficients a, b and have the same extreme point at w = -0.5 b/a , whereas 
w = - b/a  (i.e. twice the value at extreme point) is considered the maximum inelastic displacement corresponding to F(w) 
higher than zero. 
 

 
 

Figure 4: The stress-inelastic displacement relationship proposed by Fantilli et al. [10]. 
 

In the case of the plain concrete specimens, the values a = 0.320 mm-2 and b = -1.12 mm-1 were obtained by means of the 
least square approximation of several tests [10]. As observed in Fig.4b, the curves defined by Eqs.(4) fall within the range 
of the data experimentally measured by Jansen and Shah [9]. 
In the case of multi-axial compression, stress-inelastic displacement relationships, which should reproduce the confined 
post-peak stage, cannot be found in the existing literature. As is well known, two types of confinement, namely passive 
and active, can be produced. In compressed columns, passive confinements provided by transversal reinforcement (i.e., 
stirrups, tubes, strips, spirals, etc.), are only activated by concrete displacements. Thus, to define quantitatively this 
contribution, it is necessary to know the stress-transversal displacement relationship of concrete. Active confinement is 
due to external stresses 3 applied by multi-axial compression tests on cubes in two or three directions, or by triaxial tests 
on cylinders (see the book by van Mier [8] for a review).  
Only a single campaign of triaxial tests, performed by Jamet et al. [11] on micro-concrete, is reported in the current 
literature. In that case, the applied confinement was relatively high (3 >3 MPa), if compared to those produced by 
stirrups in ordinary RC columns. In accordance with Eurocode 2 [4], in columns under concentric compression, 
transverse reinforcement can develop about 3 = 1MPa [12]. Consequently, with the aim of analyzing the equivalent 
confing pressures produced by a new Fiber-reinforced Self-consolidating concrete (called Sismabeton), the comparison 
between the results of new triaxial tests on NC, SC and Sismabeton cylinders under uniaxial compression are reported.  
 
 
EXPERIMENTAL PROGRAM 
 

he post-peak behaviour of cement-based composites under multi-axial compression has been investigated at the 
Department of Structural and Geotechnical Engineering of Politecnico di Torino (Italy) by means of triaxial tests 
on concrete cylinders (Fig.5a). The experimental equipment, named HTPA (High Pressure Triaxial Apparatus) and 

described by Chiaia et al. [13], is generally used to test cylindrical specimens made of soft rocks.  
Each triaxial test consists of two stages. A specimen is initially loaded with a hydrostatic pressure σ3 (Fig.5b), then 
deviatoric loads P are applied along the longitudinal direction with a velocity of 0.037 mm per minute (Fig.5c). During the 
second stage of loading, the confining pressure 3 = const. is applied to the lateral surface, whereas the longitudinal 
nominal stress c becomes: 
 

23
4

D

P
c


            (5) 

 

where, P = applied deviatoric load; D = diameter of the cross-section.  
Through a couple of LVDT, local longitudinal displacements, and therefore nominal longitudinal strains c , are also 
measured (Fig. 5a). 
Two confining pressures, namely σ3 = 0 MPa and σ3 = 1 MPa (reached in 10 minutes), are applied to the specimens. 
During the application of hydrostatic loads (Fig.5b), stress increments are electronically recorded every 10 seconds. 

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Similarly, in the second stage, when σ3 = const. and P increases, the values of deviatoric load, the relative displacement 
between the specimen’s ends, and the longitudinal displacement along the lateral surface (taken by the LVDTs of Fig.5a) 
are measured. 
Two types of self-consolidating concrete (SC_mix1 and SC_mix2) and a single ordinary concrete (NC) were tested. 
 

 
 

Figure 5: The two stages of triaxial tests on cement-based cylinders. 

Their compositions and strengths are reported in Tab. 1. Specifically, the self-consolidating concretes have the same unit 
weight, but different amounts of aggregates. With respect to SC_mix1, in a cube meter of SC_mix2 the content of 
carbonate filler was increased by 90 N and, contemporarily, the weight of coarse aggregate was reduced by the same 
quantity.  
Regarding the Fiber-reinforced Self-consolidated concrete (i.e., Simabeton), two specimens were tested, under uniaxial 
compression (σ3 = 0). As indicated in Tab. 1, Sismabeton is  reinforced with  700 N/m3 of Dramix RC 65/35 BN steel 
fibers having hooked ends (length L = 35 mm, diameter Φ = 0.55 mm, volume fraction Vf = 0.9%). which were added to 
the self-consolidating concrete with the higher quantity of filler (i.e., SC_mix2). 
 

 NC SC_mix 1 SC_mix 2 Sismabeton

Component N/m3 N/m3 N/m3 N/m3 

Water 1770 1770 1770 1770 
Superplasticizer  

(Addiment Compactcrete 39/T100) - 44 44 44 
Superplasticizer  

(Addiment Compactcrete 39/T11) 14 - - - 
Cement  

(Buzzi Unicem II/A-LL 42.5 R) 2840 2450 2450 2450 
Carbonate filler  

(Nicem Carb VG1-2) 0 3240 3730 3730 
Fine aggregate (0-4 mm) 8830 8930 8930 8930 

Coarse aggregate (6.3-12 mm) 6380 6380 5890 5890 
Steel fibers 

Dramix RC 65/35 BN - - - 700 
 

    
Cubic strength -MPa-  30.0 31.1 30.4 33.8 

 

Table 1: Compositions and strengths of NC, SC_mix1, SC_mix2, and Sismabeton. 
 

The specimens of each concrete mixture were cast simultaneously in polystyrene form, then cured for one week under 
identical laboratory conditions, and finally tested after one month. Three couples of cylinders, with H=140 mm and D=70 
mm, were made of NC (NC0 and NC1), SC_mix1 (SC0 and SC1), and SC_mix2 (SC0b and SC1b). The two specimens of 

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these couples were tested, respectively, at σ3 = 0 MPa and σ3 = 1 MPa. Two Sismabeton cylinders (HC0 and HC0b), with 
H=140 mm and D=70 mm, were tested in uniaxial compression. The properties of each specimen are reported in Tab. 2. 

 
 
 
 
 
 
 
 
 
 
 
 
 

Table 2: Mechanical and geometrical properties of the specimens tested in uniaxial and triaxial compression. 
 
 
TEST RESULTS 
 

ig. 6 reports the stress-strain relationships obtained from the specimens made respectively with Sismabeton 
(Fig.6a), normal concrete (Fig.6b) and self-consolidating concrete (Fig.6c). The higher the confinement, the higher 
the values of fc and c1 , which are reported, together with Young’s modulus Ec , in Tab. 3. In all the cases, after the 

peak stress fc , a remarkable strain softening branch can be observed in the c-c diagrams.  
Although Sismabeton is fiber-reinforced, its compressive strength does not differ substantially from those of ordinary and 
self-consolidating concrete. However, the post peak response of Sismabeton appears more ductile. Only when the 
confining pressure 3 increases, does the ductility of NC and SC increase. By comparing all the post-peak branches 
reported in Fig.6, it seems that the post-peak branches of SC and NC specimens in the presence of 3 =1 MPa are more 
or less the same of Sismabeton without any confinement. 

 

 
 

Figure 6: The stress-strain relationships of Sismabeton, NC and SC. 
 

Specimen 
fc 

(MPa) 
c1 
(%) 

Ec 
(MPa) 

0NC0 19.4 0.293 24000 
0NC1 30.5 0.473 23000 
0SC0 20.1 0.479 17000 

0SC0b 23.2 0.372 23000 
0SC1 36.4 0.604 19000 

0SC1b 32.0 0.696 27000 
HC0 21.8 0.352 19000 

HC0b 22.2 0.534 20000 
 

Table 3: Mechanical properties measured in the tests. 

Specimen 
H 

(mm) 
D 

(mm) Type of concrete 
3 

(MPa) 
NC0 140 70 NC 0 
NC1 140 70 NC 1 
SC0 140 70 SCC mix 1 0 
SC1 140 70 SCC mix 1 1 

SC0b 140 70 SCC mix 2 0 
SC1b 140 70 SCC mix 2 1 
HC0 100 50 Sismabeton 0 

HC0b 100 50 Sismabeton 0 

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However, a direct comparison between the analyzed concretes is not possible in terms of nominal stress and strain, 
because specimens have different nominal strengths. 
 
Post-peak comparison in terms of F(w) 
A more accurate comparison between the post-peak responses of Sismabeton, NC and SC under compression can be 
conducted in terms of F(w) (Fig.7). In particular, for a given c  c1, the decrease of compressive stress c = fc-c (and 
F = c / fc ) can be obtained through the c-c diagrams experimentally evaluated (Fig.6), whereas the corresponding w 
(Fig.3a) can be obtained from Eq.(3) (fc , c1 , Ec and H are known from the tests).  
The F(w) curves reported in Fig.7 are limited to w = 2mm, when compressive strains c are relatively high although, in 
some cases, stresses are higher than zero. However, in all the tests the relative stress F = c / fc decreases with w. The 
dashed curves reported in Fig.7 represent the behaviour of NC and SC as predicted by Eq.(4) in the case of zero 
confinement. As in the case of 3 = 0 the post-peak responses of the specimens NC0, SC0, SC0b are correctly predicted 
by Eq.(4), and all the tests can be considered consistent [10].  
Both for NC and SC, Fig.7a and Fig7b, respectively show the increase of the compressive fracture toughness (within the 
range w0-2 mm) with the confining pressure 3. However, this phenomenon is also evident in the case of Sismabeton, 
which can show, in absence of confinement, more or less the same F(w) obtained for NC and SC when 3 = 1MPa.  
 

 
 

Figure 7: The post peak behaviour in terms of F(w). 
 

 
 

Figure 8: The active confinement of Sismabeton. 

Fig.8a shows the post-peak responses of the specimens HC0 and HC0b, which are closer to those of confined SC and NC 
(i.e., the range defined by NC1, SC1, SC1b), than to the theoretical F(w) obtained in absence of confinement [10] (the 
dashed line in Fig.8a). 
Within the observed range (w0-2 mm), compressive facture toughness of different concretes can be objectively measured 
by the area AF under the function F(w): 
 

  dwwFAF 
2

0

          (6) 

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In fact, as F(w) is a relative stress normalized with respect to the compressive strength fc , a comparison between all the 
cement-based composites, under uniaxial and multi-axial compression, is possible. Higher values of AF  are attained in 
concretes capable of maintaining high loads after failure (i.e., in the case of ductile materials). Obviously, the maximum 
ductility AF,max = 2mm is reached in the case of plastic behaviour [F(w) = 1= const.]. 
The areas AF computed by Eq.(6)  for the tested specimens (Tab. 2) are also reported in the histogram of Fig. 8b. In all 
cases, AF is between AF,max = 2 mm and the lower limit AF,min = 0.61 mm, corresponding to the normal and self-
consolidating concretes without any confinement (Fig.8b). To be more precise, AF,min is obtained by substituting Eqs.(4) 
(with a = 0.320 mm-2 and b = -1.12 mm-1 ) into Eq.(6). At 3 = 1MPa, for the specimens made of SC and NC (i.e., NC1, 
SC1, SC1b) the values of AF  range between 1.39 mm and 1.46 mm (Fig.8b), and do not differ substantially from those 
measured for Sismabeton (AF 1.56 mm) without confinement.  
 
 
CONCLUSIONS 
 

rom the results of an experimental campaign performed on NC, SC and Sismabeton cylinders under uniaxial and 
multi-axial compression, the following conclusion can be drawn: 
 

- In normal and self-consolidating concrete, fracture toughness in compression increases in the presence of an active 
confinement. 

- During the post-peak stage, the ductility of Sismabeton is comparable with that of NC or SC at 1MPa of confining 
pressure. 

- In compression, the performance of fiber-reinforced composites can be quantified by the distributed confining 
pressure generated by the fibers. 

The presence of an active confinement can improve the mechanical behaviour of concrete and, consequently, its 
durability. Thus, further researches should be developed in order to introduce new sustainability indexes, which take into 
account fracture toughness, both in tension and compression.  
 

 
ACKNOWLEDGEMENTS 
 

he authors wish to express their gratitude to the Italian Ministry of University and Research (PRIN 2006) and to 
Fondazione Cassa di Risparmio di Alessandria for financing this research work, and also to Buzzi Unicem S.p.A. 
for its technical support. 

 
 
REFERENCES 
 
[1] M. A. Mansur, M. S. Chin, T. H. Wee, ACI Structural Journal, 94-6 (1997) 663. 
[2] K. H. Khayat, P. Paultre, S. Tremblay, ACI Materials Journal, 98-1 (2001) 371. 
[3] UNI EN 1998-1:2005. Eurocodice 8 – Design of structures for earthquake resistance - Part 1: General rules, seismic 
actions and rules for buildings, (1998) 229 
[4] UNI EN 1992-1-1:2005. Eurocodice 2- Design of concrete structures- Part 1-1: General rules and rules for building, 
(1992) 225. 
[5] N. Ganesan, J. V. Ramana Murthy, ACI Materials Journal, 87-3 (1990) 221. 
[6] G. Pons, M. Mouret, M. Alcantara, J. L. Granju, Materials and Structures, 40-2 (2007) 201. 
[7] CEB (Comite Euro-International du Beton), “CEB-FIP Model Code 1990”, bulletin d'information n°203-205, Thomas 
Telford, London, UK (1993). 
[8] J. G. M. van Mier, , Fracture Processes of Concrete: Assessment of Material Parameters for Fracture Models. CRC 
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[9] D. C. Jansen, S. P. Shah, ASCE Journal of Engineering Mechanics, 123-1 (1997) 25. 
[10] A. P. Fantilli, H. Mihashi, P. Vallini, ACI Materials Journal, 104-5 (2007) 501. 
[11] P. Jamet, A. Millard, G. Nahas, Int. conference on concrete under multiaxial conditions, Toulouse (1984) 133. 
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[13] B. Chiaia, A. P. Fantilli, P. Vallini, in 3rd North American Conference on the Design and Use of Self-Consolidating 
Concrete (SCC), Chicago (2008). 

 

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