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Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7927-7931 7927  
  

www.etasr.com Malkanthi et al.: Enhancement of the Properties of Compressed Stabilized Earth Blocks through the … 

 

Enhancement of the Properties of Compressed 

Stabilized Earth Blocks through the Replacement of 

Clay and Silt with Fly Ash 
 

S. N. Malkanthi 

Department of Civil and Environmental Engineering 
University of Ruhuna 

Sri Lanka 

snmalkanthi@cee.ruh.ac.lk  

Harsha Galabada 

Department of Civil Engineering  

University of Moratuwa 
Sri Lanka 

hyasasiri@yahoo.com  

A. A. D. A. J. Perera 

Department of Civil Engineering 
University of Moratuwa 

Sri Lanka 

asoka@uom.lk 

P. Dhammika Dharmaratne 

Department of Civil Engineering  

University of Moratuwa 
Sri Lanka 

makway.cons@gmail.com  
 

 

Abstract—The use of earth as a building material, in different 

forms, such as unburnt and burnt bricks, rammed earth, mud 

blocks, and soil blocks, is a common practice globally. This study 

is focused on soil blocks stabilized with cement which are 

referred to as Cement Stabilized Earth Blocks (CSEBs). The 

strength and durability of CSEBs are primarily governed by the 

amount of silt and clay content (finer) in the soil. Many 
researchers have shown that low finer content improves the 

properties of CSEB and they have altered the finer content by 

adding different additives. The current study used a washing 

method to reduce the finer content and fly ash was utilized as 

finer to re-fill the soil to the required finer content amount. Also, 

soil grading was modified by adding larger particles that were 

separated from the same soil to fit the soil grading to the 
optimization curves mentioned in the literature. The finer content 

was changed to 5%, 7.5%, and 10%. Blocks were made by 

stabilizing the soil with 6%, 8%, and 10% cement and with the 

size of 150mm×150mm×150mm. The results revealed that fly ash 

addition up to 10% improves the properties of CSEBs and 
compressive strength changes from 4.28N/mm

2
 to 13.43N/mm

2
. 

Keywords-cement stabilized earth blocks; fly ash; reduced silt 

and clay; improved properties 

I. INTRODUCTION  

Earth is one of the oldest and most widespread construction 
materials [1]. Raw earth as a building material has many 
advantages [2–5]. Soils in their natural state lack in strength, 
durability, and dimension stability. Authors in [6] showed the 
mechanical weakness and the absence of standard procedures 
to measure strength and stiffness as some demerits of earth-
based constructions. These deficiencies can be overcome by 
stabilizing the soil to produce building materials [7]. 
Compressed Stabilized Earth Blocks (CSEBs) are one such 
building material. Authors in [8] used soil to produce mud 

concrete blocks. Authors in [9], on their extensive literature 
survey, have shown the advantages and disadvantages of using 
earth-based building materials. They have the inherent 
advantages of being eco-friendly, having low thermal 
conductivity, while they are abundantly available in nature. 
However, the loss of strength and dimensional stability when in 
contact with water for a long time, is a serious disadvantage. 
Due to these disadvantages, the use of CSEBs as a common 
building material is not as expected. The use of burnt bricks 
and cement blocks is popular in Si Lankan housing 
construction also. As per statistics, the construction industry 
consumes a huge cost for burnt bricks and soil blocks usage is 
not even mentioned in the statistics [10]. The two main 
challenges of CSEBs are durability and compressive strength. 
The main variable for both these critical parameters is related 
to the amount of silt and clay (finer) in CSEBs. Past research 
work established the optimum finer in the region ranging from 
5% to 20% related to compressive strength but no firm 
indication of the range was associated with the durability of 
CSEBs. Lateritic soil is used for the production of CSEBs and 
the content of silt and clay in lateritic soils is generally around 
the range from 20 to 35% [11]. 

CSEBs can be used to overcome the problems associated 
with burnt bricks such as material availability and the 
economic viability. Generally, many researchers have shown 
the effect of finer content to the properties of CSEBs. The 
effect of soil grading to enhance the CSEB properties was 
examined in [12]. The authors showed that the particle size 
distribution of soil can be modified to fit into the theoretical 
distribution suggested by particle packing theories. Based on 
that, particle packing concepts suggested in [13–15] are valid 
for CSEB production. Crushed construction waste also can be 

used to modify the particle size distribution of the soil [16]. For 

Corresponding author: S.N. Malkanthi



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other soil-based products like mud concrete also, particle 
percentages in the different ranges need to be controlled [8].  

The current research examined the reduction of finer 
content by washing the soil for the production of CSEBs. 
Removing finer content to a certain extent may improve 
durability. Production practicability is another concern. With 
high clay content, the production process may face problems. 
Therefore, removing finer may help the production process and 
lower its cost. With this finer reduction, there can be more 
voids in the soil mix. Therefore, the study suggests the addition 
of fly ash to act as finer. With this background, the objective of 
the study is to check the suitability of using fly ash as a 
replacement for finer content in the soil to produce CSEBs. 

II. USE OF FLY ASH FOR CSEB PRODUCTION 

Fly ash is a fine, glass-like powder recovered from gases 
created by coal-fired electric power generation and its particles 
are generally spherical in shape and range in size from 0.5µm 
to 100µm [17]. SiO2, Al2O3, Fe2O3, and occasionally CaO are 
the main chemical components present in fly ash [18]. It has a 
long history of use as an engineering material and has been 
successfully employed in geotechnical applications [19]. 
Additionally, the use of fly ash to enhance the properties of 
concrete is not rare. Authors in [20] have used fly ash/rice husk 
ash mixture to enhance the properties of concrete. Authors in 
[21] showed the effect of using fly ash on the compressive 
strength of green concrete. Most of the times, fly ash is 
classified as secondary binder and cannot induce the desired 
effect by itself. However, with the presence of activators can 
form a cementitious compound which can improve the strength 
of the soil [22]. Highest compressive strength of CSEBs can be 
achieved when they were incorporated with 10% fly ash. The 
lowest water absorption was experienced by CSEBs when the 
fly ash percentage was 15% [23]. Authors in [24] have used 
high carbon fly ash for compressed earth blocks. As per their 
studies, they have varied the fly ash content from 0% to 50% in 
10% intervals keeping the cement content constant. Blocks 
with 0% fly ash have shown the maximum compressive 
strength and the lowest water absorption. They concluded that 
25% fly ash content gives the optimum compressive strength. 
Authors in [25] used lime and fly ash for soil blocks. Their 
study showed that the unconfined compression strength of the 
laterite soil with 5% fly ash and 15% lime was found to be 
around 2.5 times more than the strength of natural laterite soil. 
Also, they have shown that the average compressive strength of 
the blocks tested after 28 days of curing was more than the 
minimum compressive strength of fired bricks as per IS: 1077 
(1992). The water absorption value obtained for 28 days of 
curing was below the minimum value as specified in IS: 
1077(1992). 

III. RESEARCH METHODOLOGY 

Soil is the dominant part of CSEBs. Geotechnical analysis 
was carried out to analyze the characteristics of the soil. Wet 
sieve analysis as per [26] was conducted to identify the silt and 
clay content accurately. Atterberg test was conducted as per 
[27]. Specific gravity test also was performed to identify the 
physical properties of the soil. Wet sieve analysis showed that 
the soil contains 28% silt and clay. Therefore, to reduce the silt 

and clay content, the soil was washed. The washed soil 
consisted of nearly 5% slit and clay content.  

This particle size distribution of the soil revealed that 
modification is needed to get its particle distribution to fit into 
the optimization curves as described by the particle packing 
theories. Also, finer content was changed to 5%, 7.5%, and 
10% by adding fly ash. This fly ash was taken from 
Norechcholai Lakvijaya Power Plant, Sri Lanka. Fly ash was 
tested for its particle size distribution and chemical 
composition. Table I shows the chemical composition of the fly 
ash. Earlier separated larger particles in the range of 2.0-6.0mm 
and 6.0-12.0mm as in Figure 1(a) and 1(b) were also added to 
get the soil particle size distribution as per optimization curves. 
As per the objective of the study, cement was used as stabilizer 
in 6%, 8%, and 10% proportions. 

TABLE I.  CHEMICAL AN ALYSIS OF FLY ASH 

Constituents determined Content % Test method 

Calcium as CaO 5.63 

Acid digestion and 

atomic absorption 

spectrometry 

Magnesium as MgO 1.59 

Iron as Fe2O3 3.35 

Aluminum as Al2O3 19.74 

Potassium as K2O 0.47 

Sodium as Na2O 0.95 

Manganese as MnO 0.05 

Phosphorus as P2O5 1.89 Acid digestion and 

UV/VIS Titanium as TiO2 1.98 

Silicon as SiO2 47.48 
Gravimetry 

Loss on ignition 16.79 
 

 
Fig. 1.  (a) Gravel 2.0-6.0mm, (b) Gravel 6.0-12.0mm. 

Since the mixure of soil has more gravel parts and the 
casting was carried out using a cement sand block-making 
machine, the water requirement was comparatively less. For 
the practical easiness of casting 8-10% water (by soil weight) 
was sufficient. For each combination, 10 blocks were cast 
resulting to a total of 90 blocks. The 150mm×150mm×150mm 
blocks were prepared using the cement sand block-making 
machine shown in Figure 2. Both vibration and compaction 
were applied to block casting. Vibration time was regulated 
based on the preliminary conducted test. Casted blocks were 
cured using wet gunny bags and water for 7 and 28 days. Cast 
blocks were tested to determine their dry and wet compressive 
strengths, dry density, and water absorption, as per SLS 1382 
(Part 2) [28] as strength-related tests. Each block was placed 
carefully in the testing machine below the center of the upper 
bearing block and load was added until failure. The 
compressive strength was determined using the load at failure. 
Figure 3 shows the testing procedure and the cast blocks. 



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Fig. 2.  Use of block making machine for CSEB production. 

 
Fig. 3.  Cast blocks and compressive test procedure. 

The dry density of the blocks was determined after keeping 
the blocks in the oven for more than 24 hours at 105

0
C. Each 

specimen was oven-dried to a constant mass, weighed and 
measured to determine its dry density which was calculated by: 

�� �
�����		
��

������
��
� 10�    (1) 

To determine the water absorption of the blocks, oven-dried 
test specimens were immersed in water for 24 hours, and the 
increase in the mass of each specimen was calculated and 
expressed as a percentage of the specimen’s initial dry mass. 

� �
���������		������	���	��		
�
�� �!	���	��		
�

� �!	���	��		
�
� 100    (2) 

IV. RESULTS AND DISCUSSION 

The used original soil consists of 5% finer and its grading 
shows it as a fine-grained soil. So, gravel had to be added to fit 
the grading into the optimization curve. Then, finer content got 
to be reduced, hence separated finer should be added. Fly ash 

was added to the mix as finer, and the prepared CSEBs were 
tested. The fly ash used for the blocks was sieved through a 
0.425mm sieve. In this study, the purpose of using fly ash is to 
replace finer particles. Other than that, its binding properties 
were not considered. The specific gravity of fly ash is 2.2 and it 
is less than that of original soil (2.7) resulting in reduced 
specific gravity for the soil-fly ash mix. When mixing the soil 
and fly ash, the expected final particle size distribution was 
determined as per the power line. A maximum density line has 
been proposed in [29]. It gives a direction to select a correct 
proportion of aggregates to get the maximum density. So, to 
match with the power line, other than the fly ash, different size 
larger particles were also added to the mixture. These larger 
particles were earlier extracted from the same soil. Figure 4 
shows the particle size distribution for fly ash, used soil, re-
constitute soil and its comparison to the power line. 

 
Fig. 4.  Comparison of particle size distribution. 

A. Properties of CSEBs with Fly Ash Replacement 

Finer content was changed to 5%, 7.5%, and 10% by 
adding fly ash. Blocks were made with 6%, 8%, and 10% 
cement stabilizer. The dry compressive strength (at 7 and 28 
days) and the wet compressive strength (at 28 days) of blocks 

made with fly ash as finer are shown in Figures 5-7. 
Considering the compressive strength results of blocks with fly 
ash replacement, when the cement content is 10%, high 
compressive strength can be achieved, irrespective of the finer 
content. Among the tested samples, 7.5% finer with fly ash 
replacement has given the highest compressive strength. The 
test results were compared with SLS 1382 specification for 
CSEBs and SLS 855 specification for cement blocks. 
According to the test results shown in Table II, when the 
cement content is 10% for all the selected finer contents, 
compressive strength values are above the limiting value for 
grade 1 CSEB (6.0N/mm

2
 and 2.4N/mm

2
 for dry and wet 

compressive strength respectively). For 5% and 7.5% finer and 
8% cement, compressive strength values reached grade 2 
CSEB (4.0 - 6.0N/mm

2 
for dry compressive strength and 1.6 - 

2.4N/mm
2
 for wet compressive strength). Even with 6% 

cement, 7.5% finer can produce grade 3 CSEB (2.8 - 4.0N/mm
2
 

for dry compressive strength and 1.2 - 1.6N/mm
2
 for wet 

compressive strength). 



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Fig. 5.  7-day dry compressive strength results of soil blocks with fly ash. 

 
Fig. 6.  28-day dry compressive strength results of soil blocks with fly ash. 

Cement &

5 6 7 8 9 10 11

C
O
m
p
re
s
s
iv
e
 S
tr
e
n
g
th
 (
M
P
a
)

1

2

3

4

5

6

7

8

5% finer with fly ash

7.5% finer with fly ash

10% finer with fly ash

 
Fig. 7.  28-day wet compressive strength results of soil blocks with fly ash. 

Also, the density and water absorption values (Table III) 
are satisfied with the specified value (1750kg/m

3
 and 15% 

respectively) in SLS 1382 Part 1. Out of all the finer contents, 

7.5% finer replacement has the highest density and lowest 
water absorption when the cement replacement is 10%. 

TABLE II.  COMPRESSIV E STREN GTH RESULTS 

Cement % 6 8 10 

5% finer with 

fly ash 

Dry 2.72 4.57 9.8 

Wet 1.85 2.6 5.25 

Dry/wet 0.680 0.569 0.536 

7.5% finer 

with fly ash 

Dry 2.79 4.76 13.43 

Wet 1.67 3.16 7.35 

Dry/wet 0.599 0.664 0.546 

10% finer with 

fly ash 

Dry 2.43 3.76 8.75 

Wet 1.45 2.85 4.28 

Dry/wet 0.597 0.758 0.489 

TABLE III.  DENSITY AND WATER ABSORPTION RESULTS 

Cement % 6 8 10 

5% finer 

with fly 

ash 

Density 

(kg/m
3
) 

1968 1903 1943 

Water 

absorption % 
10.33 11.28 9.34 

7.5% finer 

with fly 

ash 

Density 

(kg/m
3
) 

1865 1833 2074 

Water 

absorption % 
11.40 12.40 6.32 

10% finer 

with fly 

ash 

Density 

(kg/m
3
) 

1761 1778 1912 

Water 

absorption % 
13.89 13.77 11.54 

 

V. CONCLUSIONS 

The current study used the abundantly available soil with 
high silt and clay (finer) content. The reduction of excessive 
finer was done by washing the soil. Then, the study focused on 
replacing the silt and clay content in the soil with fly ash for 
CSEB production. Also, soil grading was modified to fit into 
the optimization curves as explained in particle packing 
theories. The use of the washing method for finer reduction and 
the use of traditional cement sand block making machines for 
block production do not require highly technical skills. Hence, 
the local construction industry can use this method easily. The 
most notable findings of the present study are: 

• With 10% cement stabilization, CSEBs with all fly ash 
addition achieved high values of dry and wet compressive 
strengths, satisfying the Grade 1 requirements.  

• 8% cement stabilization gives compressive strength values 
of Grade 2 blocks for all fly ash addition percentages. 

• Even with 6% cement stabilization, 7.5% fly ash addition 
gives compressive strength in the Grade 3 range. 

• All the blocks, irrespective of the cement and fly ash 
content, have densities and water absorption values that 
satisfy the SLS 1382 requirements. 

The studies [12, 16] showed similar behavior of blocks’ 
compressive strengths. Both studies showed that 10% cement 
usage for block production leads to high compressive strength. 
Authors in [7] also recommended 10% as the highest cement 
percentage considering the financial aspect. Further, 7.5% finer 
contained soil contributes to improved properties compared to 



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5% and 10% finer contributions. Based on the obtained results, 
this study suggests the washing of soil as a novel method to 
reduce its finer content for soil block production. Finally, it can 
be concluded that the addition of fly ash as finer results to the 
improvement of the properties of CSEBs. 

ACKNOWLEDGMENT 

This research did not receive any specific grant from 
funding agencies in the public, commercial, or not-for-profit 
sectors. The authors would like to acknowledge the support 
given by Mr. D. M. N. L. Dissanayaka, technical officer of the 
Structural Testing Laboratory, Mr. H. T. R. M. Thanthirige, 
technical officer of the Building Materials Laboratory, and Ms. 
W. U. B. Rukma, technical Officer of the Construction 
Engineering and Management Division, University of 
Moratuwa, Sri Lanka. 

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