J. Build. Mater. Struct. (2020) 7: 87-94 Original Article  
DOI : 10.34118/jbms.v7i1.706  

 

ISSN  2353-0057, EISSN : 2600-6936 

Effect of cement types on carbonation depth of concrete  

Merah A*, Korichi Y, Khenfer M M 

 
       Ammar Telidji University, Civil Engineering Research Laboratory, Laghouat-Algeria. 
* Corresponding Author: a.merrah@lagh-univ.dz 

 
Received: 23-05-2020 

 
 

 
Accepted: 29-07-2020 

Abstract.  Reinforced concrete as a building material is the most used in civil engineering 
structures. This one is exposed to several attacks (physical, chemical and mechanical). 
Among these attacks, we can cite the phenomenon of carbonation, which leads to corrosion 
of the reinforcements and consequently reduces the service life of reinforced concrete 
structures. In addition, this phenomenon generates additional repair costs, which can 
sometimes exceed the initial cost of the building. Furthermore, it depends on the type and 
class of cement, two main classes of cement are used for the formulation of concrete in 
Algeria, ordinary Portland cements and cements with additions. 
This paper enters in the context of sustainable development, in order to study the behavior 
of these two types of cements against accelerated carbonation. 
For this purpose, two concrete compositions (based on ordinary Portland cements and 
cements with additions) were formulated, from these two formulations, samples were made 
in order to subject them to accelerated carbonation in a chamber rich in CO2 according to the 
recommendations of the AFPC-AFREM. 
The results obtained clearly show that concretes based on ordinary Portland cements (OPC) 
are less sensitive to the phenomenon of carbonation compared to concretes based on 
blended cements. 

Key words: sustainability; reinforced concrete; OPC cement; blended cement, durability, accelerated 
carbonation. 

1. Introduction 

Reinforced concrete is widely used in the world for the realization of structures in all fields of 
civil engineering, the absolute need to protect this material against atmospheric aggressions is 
very necessary. Among these attacks, we can mention the concrete carbonation. 

Moreover, Concrete as a cementitious material is highly sensitive to the phenomenon of 
carbonation, which is due to the penetration of atmospheric carbon dioxide through the porosity 
of the concrete surface. This gas reacts with the portlandite (Ca (OH)2) by lowering the pH of the 
interstitial solution from 13 to 9. This decrease in pH causes the reserve of portlandite 
(component responsible for durability) to be consumed and Once the coating of concrete is 
carbonated, the steel reinforcement initially protected may corrode. The damage associated with 
this phenomenon corresponds to cracks by the degradation of the concrete coating, by the 
formation of iron oxides and hydroxides on the reinforcements These consequences of 
carbonation can have an impact on the bearing capacity of structural elements. 

In addition, most of the civil engineering structures realized in Algeria are made of reinforced 
concrete, these structures are mainly based on two classes of cements, ordinary Portland 
cements OPC and blended cement. 

Many researchers have been interested in the effect of cement additions on the concrete 
carbonation, Papadakis et al. (1992) developed a mathematical model that controls the 
evolution of carbonation in time with 50% relative humidity; this model has been extended to 
cover the case of carbonation of the coating system (lime cement) and concrete, this model has 

mailto:a.merrah@lagh-univ.dz


88 Mearh et al., J. Build. Mater. Struct. (2020) 7: 87-94  

 

 

been validated for concrete based on ordinary Portland cement (OPC) and on blended cement 
with pozzolanic additions. Elsewhere, Dakhmouche Chabil (2009) shows that the carbonation 
depth of concrete samples decreases if additions (silica fume and fly ash with a high and low 
calcium content) replace a quantity of aggregates and increases if additions replace a quantity of 
cement. 

Moreover, Dakhmouche Chabil (2009) concludes that the carbonation depth in mortars based on 
blended cement is higher than the depth of carbonation mortars based on OPC cements. In the 
same context, Sisomphon and Franke (2007) show that additions in volume (pozzolan 
materials) increases the carbonation rate with increasing W / C ratio, and concluded that the 
depth of accelerated carbonation (chamber riched of 3% CO2) is 10 times higher than under 
natural exposure conditions. According to Kulakowski et al. (2009), a rate higher than 10% 
additions in silica fume increases the potential for carbonation. Moro et al. (2011) and Phung et 
al. (2015) studied the effect of limestone fillers on the microstructure and permeability due to 
carbonation of cement pastes conditionally controlled CO2 pressure, it shows that the 
carbonation samples (RH = 65%) is fast during the first hours while it decreases significantly if 
the relative humidity increases, this study shows that on the additional carbonation of 
portlandite, CSH are also carbonated. 

Moreover, Morandeau et al (2015) and Sideris et al. (2006) show that the fly ash additions 
(about 30%) to ordinary Portland cement with a ratio of W / C in order of 0.6, the cement pastes 
develop coarse capillary pores which for extensive drying occur even if the total porosity 
decreases. 

This work inscribed in a sustainable development approach, which focus to study the behavior 
of concretes based on OPC cement and blended cements (42.5 CEM II / B) produced in Algeria, 
subjected to the accelerated carbonation. This work studies the effect of the class of cement on 
the evolution of the accelerated carbonation depth, two  concrete formulations were made based 
on both classes of cement (OPC cement 42.5 and blende cements CEM II / B) from the two 
concrete formulations, prismatic test samples 7x7x28 cm were made, and they were subjected 
to the accelerated carbonation test in a chamber enriched in CO2 as recommended by AFPC- 
AFREM (Ollivier, 1997), carbonation depth measurements were carried out by spraying 
phenolphthalein at 4, 7,14, 28, 42 and 56 days 

For this study, the choice is oriented for the cements produced in Algeria, the OPC cement CEM I 
and cement CEM II 42.5 / B. 

2. Experimental program 

2.1. Concrete formulation 

The cement used for the 1st concrete formulation is ordinary Portland cement (OPC) CEM I 42.5,  

Table 1 shows the chemical and physical characteristics of this cement.  

Table 1. Physical and chemical characteristics of the OPC cement CEM I 42.5 

CEMI 
42.5 

SiO2 Al2O3 Fe2O3 CaO MgO K2O Na2O SO3 
S.s 

cm2/g 

20-23 
4.07-
4.80 

4.70-
5.40 

62-
65 

0.71-
1.22 

0.35-
0.50 

0.07-0.18 
1.00-
1.45 

2500-
3263 

*S.s : Specific surface 

The used Cement for the 2nd concrete formulation is the blended cement CEM II 42.5 / B, Table 2 
shows the chemical and physical characteristics of this cement. 

 



 Merah et al., J. Build. Mater. Struct. (2020) 7: 87-94 89 

 

 

Table 2. Chemical and physical characteristics of the blended cement CEM II/B 

CEM 
II/B 
42.5 

SiO2 Al2O3 Fe2O3 CaO MgO K2O Na2O SO3 
S.s 

cm2/g 

20.58 4.90 4.70 62.8 0.63 0.42 0.07-0.18 2.28 3700 

*S.s : Specific surface 

The used method for the two concrete formulations is the Dreux Gorisse method. Two used 
classes of gravel were (3-8mm, 8-15 mm), with absolute density equal to 2700 kg/m3, and the 
used sand has an absolute density of 2400 kg/m3.  

The results of these formulations show that the cement content in concrete was 408 kg/m3 for 
the both concrete formulations, the slump cone was 11cm. The compressive strength at 28 days 
of the formulated concrete is 30MPa (the most used concrete in Algeria). The W / C ratio is 
around 0.52. 

Table 3. Results of the concrete composition of the concrete formulation (OPC cement CEM I 42.5) 

Sand (0-5) kg Gravel 3-8 (kg) Gravel 8-15 (kg) Ciment CEM I 42.5 (kg) Water (l) W/C 

708 115 933 408 211 0.52 

Table 4. Results of the concrete composition of the 2nd formulation (CEM II 42.5 / B) 

Sand (0-5) kg Gravel 3-8 (kg) Gravel 8-15 (kg) Ciment CEM II 42.5/B (kg) Water (l) W/C 

708 115 933 408 211 0.52 

The compressive strength at 28 days of the formulated concrete is 30 MPa, the W / C ratio is 
about of 0.57. Figure 1: show the DRX mineralogical composition of used limestone gravel  

 

Fig. 1. Mineralogical composition of used limestone gravel 

This analysis allowed to identify the nature of the component elements limestone gravel, they 
are all dolomite CaMg (CO3)2 and some quartz elements SiO2. 

2.2. Preparation of samples and conservations conditions for accelerated carbonation test 

The prismatic samples 7x7x28 cm were confectioned according the procedure recommended by 
AFPC-AFREM (Ollivier, 1997). For both formulations, samples were made to undergo 
accelerated carbonation test, and they will be used for the carbonated concrete depth 



90 Mearh et al., J. Build. Mater. Struct. (2020) 7: 87-94  

 

 

measurements, other samples will be used to monitor evolution of the mass during the test. All 
these samples were cured in water for 28 days 

Before initiating accelerated carbonation test, the procedure specified in AFREM 
recommendations follow two phases:  the first phase consist to saturate samples in the water. At 
the end of this phase, the samples will be weighed, dried for two days in an oven set at a 
temperature of 40 ± 2 C °, then they are still weighed, once before their introduction into the 
chamber of the accelerated carbonation. 

2.3. Accelerated carbonation test  

The test procedure adopted is the one recommended by the AFPC AFREM (Ollivier, 1997) which 
consist to place (after 28 days of curing and drying) the prismatic samples 7x7x28cm (Figure 2) 
of two concrete formulations in the chamber of accelerated carbonation (50 % CO2+50 % 
Air)( Figure 3) , Regulated at a temperature of 20 °C and a relative humidity of 65 ± 5%. 

All these samples were maintained in the chamber of accelerated carbonation for a period of 90 
days. 

For each formulations, samples were removed from the chamber of accelerated carbonation at 
different ages: 4, 7, 14, 28, 42, 56 and 90 days, and they  were sliced in two parts (figure 5) and a 
measurements of carbonation depth (by spraying the solution of phenolphthalein, (1% 
phenolphthalein in 70% ethyl alcohol) were executed with according to RILEM 
recommendations CPC-18 (1988).  

Carbonated depth corresponds to the distance between the outer surface of the concrete and the 
coloring front (Figure 4), the uncarbonated concrete takes a pink color and the carbonated 
concrete is not colored (Figure 5). This method is based on the change of the PH value, initially 
around 13 for the uncarbonated concrete and passes to 9 for the carbonated concrete, five 
distances are determined for each side of the test samples. The values of carbonation depth are 
given in mm. 

 

Fig. 2. Prismatic samples 7x7x28cm 

 

Fig. 3. Samples into the carbonation chamber  

 

 

Fig. 4. Method to measure of carbonation depth   

 

Fig. 5. Detection of the carbonated zone 



 Merah et al., J. Build. Mater. Struct. (2020) 7: 87-94 91 

 

 

3. Results and discussions 

3.1. DRX test  

This technique essentially qualitative, used to differentiate varieties of the same crystallographic 
mineral such as portlandite and calcium carbonate (calcite). However, it does not identify the 
semi-crystalline or amorphous compounds such as amorphous portlandite or amorphous newly 
formed calcium carbonates. 

This method involves bombarding a sample (isotropic homogeneous powder consisting of tiny 
crystals welded together) with X-rays and recording the X-ray intensity which is redistributed 
according to the orientation in space. The scattered X-rays interfere with each other, the 
intensity then has maxima in certain directions. There is a diffraction phenomenon. 

The detected intensity is then drawn as a function of the beam deflection angle. The obtained 
curves are called diffractograms.  

Figures 6 and 7, show diffractograms for an angle range (0 to 26 degrees), for the two types of 
carbonated concrete after 90 days in the carbonation chamber. 

 

Fig. 6. DRX analyzes on the carbonated (black)and uncarbonated (blue) samples for the 2nd concrete 
formulation (based on Blended cement) 

 

Fig. 7. DRX analyzes on the carbonated (black)and uncarbonated (blue) samples for the 1st concrete 
formulation (based on OPC cement) 

CaCO3 

SiO2 
Portlandite 

Portlandite 

CaCO3 

SiO2 



92 Mearh et al., J. Build. Mater. Struct. (2020) 7: 87-94  

 

 

In order to confirm the measures of carbonation depth obtained with the method of the spraying 
phenolphthalein, the x-ray diffraction was used for the detection of the new formed products 
after carbonation and compared to controlled samples for the two concrete formulations. 

For both concrete formulations of carbonated samples, we observe that the reserve of 
portlandite was higher in the concrete made with OPC cement compared to the samples of 
concrete made with blended cement. This can be explained that the concrete made with blended 
cement is more sensitive to carbonation compared with samples made with OPC cement. This 
constating is caused that the OPC cement has a high reserve of portlandite compared to blended 
cement. In another way, the composition of the two cements is different.  

3.2. Impact of the cement type on the accelerated carbonation 

Figure 8 shows the results of the accelerated carbonation test for the test samples of the two 
concrete formulations. From this figure, it can be seen that the 1st concrete formulation based on 
the OPC cement is less sensitive to carbonation phenomenon that the second one. 

0 2 4 6 8 10 12

0

1

2

3

4

5

6

7

8

9

10

11

12

13

C
a

rb
o

n
a

ti
o

n
 d

e
p

th
 i
n

 m
m

 f
o

r 
th

e
 s

e
c
o

n
d

 c
o

n
c
re

te
 f
o

rm
u

la
ti
o

n

square root of time in days

 carbonation depth of concrete formulation based on OPC cement

 Carbonation depth of concrete formualtion based on Blended cement

 

Fig. 8. : Carbonation depth (concrete based on OPC cement and concrete based on blended cement) 

The 1st concrete formulation gives a better protection for the concrete against the carbonation 
phenomenon compared with the 2nd concrete formulation. These results are in agreement with 
those obtained by Sisomphon and Franke (2007). 

In addition, for concrete samples of the 1st formulation, it was found that the depth of 
carbonation is low during the first days and increase from the 7th day, but it is still inferior to 
the depth of carbonation samples of the 2nd concrete formulation; This is due to the fact that 
during the first days the relative humidity is not stable within the chamber due to water 
exchange between the concrete and the relative humidity inside the chamber of accelerated 
carbonation. 

3.3. Evolution of mass during the accelerated carbonation test 

Figure 9 shows the evolution of the mass during accelerated carbonation test for samples of the 
two concrete formulations. 



 Merah et al., J. Build. Mater. Struct. (2020) 7: 87-94 93 

 

 

0 10 20 30 40 50 60 70 80 90 100

3390

3400

3410

3420

3430

3440

3450

3460

m
a

s
s
 i
n

 g

age in days

 Mass gain for concrete based on OPC cement

Mass gain for concreye based on Blended cement

 

Fig. 9. Mass gain during the accelerated carbonation test 

From this figure, it was found a mass gain in the early days of the test, especially for the samples 
of the 2nd concrete formulation; this can be explained by the fact that in the early days the 
relative humidity varies depending on the water exchange between the concrete and the 
atmosphere in the accelerated carbonation chamber. Then the relative humidity stabilizes at a 
value of 65 ± 5%. Moreover, this figure has the same form for the two concrete formulations, 
which agree with the results of AFREM crossover tests. We also note that the mass gain during 
the accelerated carbonation test is less important for samples from the 1st formulation of 
concrete, this is due that the cement CEMII / 42.5 B of the second formulation contains 
additions. 

These results confirm that the use of the 1st formulation of concrete based on cement CEM I 42.5 
OPC gives a supplementary protection against the carbonation that the 2nd concrete formulation 
based on blended CEM II 42.5 /B 

4. Conclusion  

In the present work, a concrete composition B30 was made (2 fractions of gravel). Samples from 
both concrete formulations were made and submitted to the accelerated carbonation test. 

We can draw the following conclusions: 

1. The use of the OPC cement for the confectioning of reinforced concrete structures 
minimizes carbonation depth compared to concretes based on blended cement CEM II / 
B 42.5. 

2. It was found that a low mass change for concrete samples-based cements CEM I / 42.5, 
compared to concretes-based cements CEM II / 42.5 B. 

3. As regards the accelerated carbonation test, it was also found that the water exchange 
between the concrete and the atmosphere in the chamber do not stabilize after the 7th 
day. 

4. The results show that the formulation of concrete-based OPC cement is less sensitive to 
carbonation phenomenon compared to the concrete formulation based on cements CEM 
II / 42.5 B. 



94 Mearh et al., J. Build. Mater. Struct. (2020) 7: 87-94  

 

 

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algériennes (PhD Thesis). Orléans. 

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Kulakowski, M. P., Pereira, F. M., & Dal Molin, D. C. (2009). Carbonation-induced reinforcement corrosion 
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Morandeau, A., Thiéry, M., & Dangla, P. (2015). Impact of accelerated carbonation on OPC cement paste 
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Phung, Q. T., Maes, N., Jacques, D., Bruneel, E., Van Driessche, I., Ye, G., & De Schutter, G. (2015). Effect of 
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Sideris, K. K., Savva, A. E., & Papayianni, J. (2006). Sulfate resistance and carbonation of plain and blended 
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