SQU Journal for Science, 2018, 23(2), 111-119  DOI: http://dx.doi.org/10.24200/squjs.vol23iss2pp111-119 

Sultan Qaboos University  

111 

 

Preliminary Assessment of Utilization of  
Al-Jaif Scoria (NW Sana’a, Yemen) for 
Cement Production  

Ibrahim A. Al-Akhaly
1
*, Ahmed M. Al-Anweh

2 
and Mohammed I. El-Anbaawy

3 

1
Department of Earth and Environmental Science, Faculty of Science, Sana’a University; 

2
Amran Cement Plant, Amran,Yemen; 

3
Department of Geology, Faculty of Science, Cairo 

University. *Email: Ibnalakhaly@hotmail.com 
 
ABSTRACT: This paper presents the results of investigations on the potential industrial utilization of scoria, 

collected from Al-Jaif quarry, NW Sana'a, Yemen as a cement additive. Scoria was chosen as a cement additive 

material due to its availability and low cost from the Sana’a-Amran volcanic field in Yemen. The chemical 
composition of scoria was determined by X-ray fluorescence (XRF). The studied scoria is mainly composed of 

volcanic glass with a few zeolites (e.g. clinoptilolite) as revealed from petrographic investigation and X-ray 

diffraction (XRD). The scoria was added to the clinker in the range of 2, 4, 6, 8, 10 and 12% by weight. The 

fineness, surface area, water demand, setting time and compressive strength were conducted on scoria blended 

cement. According to experimental results, the high volcanic glass allows the addition of up to 12% scoria to the 

clinker to maintain a good potential of manufacturing blended cement. The results satisfy the European Standard 

EN requirements and confirm the viability of using scoria as a cement additive.  

 

Keywords: Scoria; Pozzolan; Cement; Al-Jaif; Sana’a; Yemen. 

 سمنتالتقييم األولي الستخدام اسكوريا الَجائف )شمال غرب صنعاء، اليمن( في إنتاج األ

 االنبعاويإبراهيم عبدالحميد األكحلي، أحمد محمد العنوة ومحمد إبراهيم 

معها من َمخروط الَجائف والتي تم جَ  ،هذه الورقة العلمية تَعرض نتائج التجارب المعملية حول إمكانية االستخدام الصناعي لالسكوريا:صلخمال

قل خص ثمنها وتوفرها في حَ ر   سبب  سمنت ب  صناعة األ عندَ ضافة ختيار االسكوريا كمادة م  ناعة األسمنت. تم ا  ضافة في ص  م   ركاني الستخدامها كمادة  الب  

أن  االسينية بين تشعة األالسينية. الدراسة البتروجرافية وحيود شعة فلراألتَ حديده  باستخدام تَ  ان البركاني. التركيب الكيميائي لالسكوريا تم  مرَ عَ -نعاءصَ 

 12و8،01، 6، 4، 2 بإضافة االسكوريا إلى الكلنكر بنس ت، تم  من الزيولي قليلة   ركاني مع كمية  ب   شكل  أساسي من زجاج  االسكوريا المدروسة تتكون ب  
قاومة االن ضغَاطي ة لألسمنت المنتج والمخلوط باالسكوريا. اعتماداً عومة، مساحة السطح، ن سبة الماء الم ضاف، زمن الت صل  ٪ وزناً. تم تحديد ن   ب والم 

٪ إلى الكلنكر مع احتفاظ األسمنت ٢١االسكوريا يمكن إضافة االسكوريا بنسبة تصل إلى  على التجارب المعملية ونسبة الزجاج البركاني المرتفعة في

ز صالحية استخدامها كمادة م   المخلوط باالسكوريا بخواص   ا ي عز  ه.جيدة ت طابق م تطلبات المواصفات االوروبية، مم   ضافة لألسمنت عند إنتاج 

 ائف، صنعاء، اليمن.الجَ سمنت، أاسكوريا، بوزوالن، : مفتاحيةالكلمات ال

 

1. Introduction  

he cement industry utilizes natural pozzolans (e.g. scoria) as substitutes for Portland cement (PC) due to their 

environmental, economic and chemical advantages [1-4]. In this respect pozzolans lower costs and CO2 

emissions, and increase chemical resistance of cementacious materials through reduction of the alkali aggregate 

reaction. The manufacture of one ton of PC clinker consumes about 4 GJ of energy, and releases nearly one ton of 

CO2 to the atmosphere [5]. World PC clinker production is responsible for about 7% of the total CO2 emissions 

[6-8]. For this reason, particular attention has recently been given to the exploitation of scoria in many countries, 

including Turkey [9,10], Syria [11,12] and Yemen [13,14].  

Scoria can be utilized in several industrial applications including the manufacturing of lightweight concrete, 

as a source of pozzolan to manufacture Portland-pozzolan cement additives, as a heat insulating material, in low 

cost fillers in paint, filter materials and absorbents, in architectural applications [15], for producing geopolymer 

mortar [16-18] and as a sand in PC mortar [19]. Scoria is abundant in various parts of the world including Turkey 

[9,10], Syria [11,12], Saudi Arabia [15,21,22] and Cameroon [16,17,19].  

 

 

T 

mailto:Ibnalakhaly@hotmail.com


IBRAHIM A. AL-AKHALY  ET AL 

 

112 

 

Scoria is also abundant in Yemen [13,14,20], where more than 9,000 km
2
 of the country is covered with 

Quaternary volcanic rocks [23] (Figure 1). Scoria is locally used in Yemen in road construction as a sub -base 

material and there are several quarries operating on scoria deposits in NW Sana'a where the Sana'a-Amran 

volcanic field covers a total area of some 1200 km
2
. Whilst scoria has been used in industry worldwide for a long 

time, it has only had importance in Yemeni industry for the last 6 years. However, Yemen has an important 

potential reserve of 613 million m
3
 [24] and about 500,000 metric tons are exploited annually [25]. 

 

 
 

Figure 1. Quaternary volcanic rocks in Yemen [24]. 

 

The cement produced in Yemen is almost entirely of PC, although an addition of up to 5%  natural pozzolan is 

frequently used in most local cement plants. 

Previous work has shown the possibility of using scoria in the production of blended cements in Yemen [13]. 

The aim of the current research is to determine the potential industrial use of scoria from Al-Jaif (NW Sana'a, 

Yemen) as a cement additive material. The use of scoria as a construction material would provide both low cost 

cement and also a cleaner environment. This study is important not only for Yemen but also for other countries of 

similar geological setting. 

2. Materials and methods  

2.1. Sample preparation  

More than 500 kg of bulk sample was collected from scoria pyroclastic deposits in the Al-Jaif volcanic cone, 

about 24 km NW of Sana'a, Yemen (Figure 2). Three sub-samples were selected from the bulk sample to represent 

its apparent lithological varieties. These sub-samples were prepared for thin section investigation. Cutting and 

polishing processes were performed using an oil system. Glue that hardens under UV light was used. To reduce the 

amount of sample, sampling was performed using the cone and quartering method and riffles, since sampling must 

have mineralogical, physical and chemical homogeneity. The sample was crushed and ground using a laboratory 

dodge jaw crusher, rod mill and ball mill to reduce their size to sieve No. 200 (74 μm) for mineralogical and 

chemical analyses, which were conducted in Amran Cement Plant (ACP) (Amran/Yemen).   

2.2 Chemical and mineral analysis 

Chemical analysis of five samples of scoria was carried out of by unit model ARL 9800 XP SIM-SEQ XRF of 

Quality Laboratory of ACP. This XRF device unit is manufactured by Thermo Electron Corporation and uses Rh-

tube and UniQuant program. The preparation of powder pellets for analysis included crushing the samples using the 

Jaw Crusher, then grinding them to fine powder using the Disk Vibration Mill. In this stage of sample preparation, 

about 6-7 ml of hexane (C6H14) were added to the crushed sample in order to decrease the temperature during the 

grinding. 

To investigate petrographical characteristics of the sample, thin sections of three representative samples were 

prepared and determined using the LEICA Polarizing Microscope. These thin sections were carried out in the 



PRELIMINARY ASSESSMENT OF UTILIZATION 

113 

 

Geology Department, Faculty of Science, Cairo University, Cairo, Egypt. These investigations were supported by 

bulk mineralogical study using a Philips XRD equipment model PW/1710 with Monochromator Cu-radiation (λ 

=1.542A
o
) at 40 K.V., 35 m.A. and a scanning speed of 0.02

o
/sec. The reflection peaks between 2θ = 2

o 
and 60

o
, 

corresponding spacing (dÅ) and relative intensities (peak areas) were obtained. The diffraction charts and relative 

intensities obtained were compared with ICDD files that were carried out by the Egyptian Mineral Resources 

Authority (EMRA), Cairo, Egypt. 

 

Figure 2.  Satellite image showing the location of the studied scoria field and the Amran Cement Plant [26]. 

 

2.3 Test specimen Preparation 

The clinker used for producing all types of cement (PC and scoria blended cement) was obtained from ACP 

(Amran/Yemen) (Figure 2). The clinker, scoria and gypsum were mixed to produce cement. A reference cement 

(pure PC) was produced by mixing PC clinker, 96%, and gypsum, 4% by weight. This mixture was then ground for 

40 minutes in a laboratory-type ball mill.  Scoria blended cement samples were obtained by replacing 2, 4, 6, 8, 10 

and 12% (by weight of clinker) of the PC clinker by scoria and mixing and inter-grinding. The gypsum content was 

kept constant in all cements at 4%. Before the grinding operation, PC clinker, scoria and gypsum were crushed and 

sieved through a 9.5 mm sieve to maintain uniformity between the specimens through using the same feed size. PC 

clinker, scoria and gypsum were ground to fine powder using a ring crusher to obtain a Blaine fineness of about 

3200 cm
2
/gm. The gypsum was dried at 40°C prior to crushing whereas the scoria was dried at 110°C.  

2.4 Cement Tests  

Analyses of the chemical composition of the PC (reference specimen) and scoria blended cements were 

performed by the XRF. Fineness analyses were performed in accordance with EN 196-6 [27]. The fineness of the 

blended cement samples was determined by measuring the Blaine fineness and amount of material retained on 45 

μm and 90μm sieves after vacuum sieving. The following tests were carried out on the PC and blended materials: 



IBRAHIM A. AL-AKHALY  ET AL 

 

114 

 

fineness, specific surface area by Blaine instrument, normal consistency, setting time and compressive strength. The 

amount of water necessary for the cements to have normal consistency was determined according to EN 196-3 [28]. 

Pastes having normal consistency were then used to determine the setting time by conducting tests as described in 

this standard. Preparation of cement mortar mixtures was completed according to EN 196-1 [29]. In these tests, 450 

± 2 gm of cement and 1350 ± 5 gm of standard sand were used. Scoria blended cement mortars were prepared with 

225 cm
3
 of water so that the water content of the scoria blended cement mortars were adjusted to have a w/c ratio of 

0.5 as stated in the standards. The prepared mortars were poured into cubic shaped three-part mortar molds 

7.06x7.06x7.06 cm
3
 (surface area 50 cm

2
). The mortar specimens of all cements used in the experiments were 

prepared in a laboratory environment at a room temperature of 20 ± 2 
o
C and 80 ± 4 % relative humidity. After 

being kept in a wet cabinet for 24 hours, the mortar specimens were demulded and kept in water until they were 

tested. Compressive strength tests were performed by an automated strength testing machine in accordance with EN 

196-1 [29]. The compressive strength of the cubes was determined after 3, 7 and 28 days curing. Three cube 

specimens were tested for each day for each type of cement. The reported values represent the average of three 

readings. 

3. Results and discussion  

3.1 Scoria composition  

Al-Jaif scoria is one of the natural pozzolan volcanic cones in Yemen that formed during Quaternary 

explosive eruptions. It has a highly porous structure which was formed by dissolved gases precipitated during 

cooling as the lava hurtled through the air. Therefore, scoria consists of pyroclastic ejects, of irregular morphology, 

and has the basic composition of basalt. It is formed of vesicular fine to coarse fragments, reddish or black in color 

and light in weight. 

Petrographic investigation shows that the scoria is mainly composed of volcanic glass with phenocrystals 

of olivine in the matrix and has hyalopilitic-porphyritic and vitrophyric-porphyritic textures with vesicles in the 

matrix (Figure 3a). The vesicles are filled with secondary minerals (e.g. chlorite) (Figure 3b). Olivine is easily 

distinguished by color tone and Y-cracks (Figure 3c). 

 

 
 

Figure 3. Microphotographs of scoria sub-samples: (a) Connected and isolated vesicles in reddish brown glassy 

groundmass, (b) The vesicles filled with chlorite, (c) Cracked phenocrysts of altered olivine to iddengzite. 

 

The results of chemical analysis of the scoria sub-sample are given in Table 1. Chemical analysis indicates 

that SiO2, Al2O3, Fe2O3, CaO and MgO constitute its major contents. According to the XRF results, scoria shows 

basic composition due to the relatively low SiO2 and high Fe2O3 contents.  

The chemical composition of the scoria was compared with that of ASTM Type I PC (Table 1). Chemical 

analysis indicates that scoria is mainly composed of SiO2 (46.55 %); while the main oxide component of PC is CaO 



PRELIMINARY ASSESSMENT OF UTILIZATION 

115 

 

(60-67 %). However, scoria also has CaO (9.34 %), Al2O3 (16.68 %) and Fe2O3 (38.56 %). The content of Na2O and 

K2O known as ‘alkalis’ was found to be higher in scoria (3.55 %) than in PC (≤ 1 %). 

The XRD pattern of scoria is given in Figure 4. As stated before, scoria is an amorphous volcanic rock. XRD 

data (Figure 4) indicates that, scoria consists mainly of glassy volcanic materials (of amorphous structure), with 

some crystalline mineral phases, e.g. labradorite, bytownite, pigeonite, augite, forsterite, magnetite, zeolite 

(clinoptilolite), calcite and caladonite, and with traces of clay minerals (mainly kaolinite and chlorite).  

 

Table 1.  Chemical composition of the studied bulk scoria sample and ASTM Type I PC. 

 

Oxides 
Scoria  

(mass, %) 
ASTM Type I PC [30] 

(mass, %)  

SiO2 46.55 17-25 

Al2O3 16.68 3.0-8.0 

Fe2O3 12.54 0.5-6.0 

CaO 9.34 60-67 

MgO 7.82 0.5-4.0 

K2O 0.86 0.5-1.3 

Na2O 2.69 0.5-1.3 

SO3 0.05 1.0-3.0 

P2O3 0.36 - 

TiO2 2.09 - 

LOI 0.67 1.22 

Total 99.65 - 

 

 

 
 

Figure 4.  X-ray diffraction chart of the scoria bulk sample. 

 

Scoria can be considered a good component for the cement industry if it contains volcanic glass and high 

amounts of zeolite minerals [30]. The thin section studies show that scoria is mainly composed of volcanic glass, 

while the XRD analysis indicates the presence of a few zeolites mainly in the form of clinoptilolite mineral, 

establishing that the Al-Jaif scoria is a good additive for the cement industry.  

3.2  Cement properties  

Chemical analyses of the control specimen and scoria blended cements are given in Table 2. The chemical 

composition of the PC indicates that the CaO/SiO2 ratio is greater than 2 and the percent of MgO content is 

smaller than 5%. These values satisfy the main composition requirements imposed by the EN 197-1 [32]. Due to 

the scoria’s chemical composition, SiO2, Al2O3, Fe2O3 and MgO contents increase and CaO content decreases 

with increasing the scoria content ratio in the cement mixture (Figure 5).  



IBRAHIM A. AL-AKHALY  ET AL 

 

116 

 

Physical and mechanical properties of PC and scoria blended cements are given in Table 3. They have 

nearly the same water demand ratio. This was evidenced by the results of water demand of the investigated mortar 

mixes. Therefore the scoria’s effect on the compressive strength of mortars could be considered marginal. A 

literature survey shows that the chemical composition, porosity and specific surface area of cement mixtures affect 

water demand [34]. 

The setting times of the PC and scoria blended cement mortars including 2, 4, 6, 8, 10 and 12% scoria 

content ratio were all close. 

  

Table 2.  Chemical composition of the control (PC) and the scoria blended cements. 

 

Standard 

After Ghosh 

[33] 

ASTM Type 

I PC [30] 
Scoria (%) 

PC 
(%) 

Oxides 

12 10 8 6 4 2 

20 ± 6 17-25 23.31 22.75 22.39 21.74 21.15 20.89 20.32 SiO2 

6 ± 2 3.0-8.0 7.12 6.82 6.61 6.37 6.06 5.86 5.58 Al2O3 

3 ± 2 0.5-6.0 3.96 3.99 3.67 3.41 3.33 3.08 2.98 Fe2O3 

62 ± 5 60-67 55.13 56.25 57.46 58.38 59.5 60.67 61.78 CaO 

3.5 ± 1.5 0.5-4.0 2.01 1.96 1.91 1.86 1.80 1.77 1.71 MgO 

1.5 ± 1.2 1.0-3.0 2.09 2.10 2.19 2.22 2.15 2.42 2.26 SO3 

minor minor 0.60 0.54 0.50 0.45 0.41 0.36 0.31 TiO2 

0.7 ± 0.3 0.5-1.3 0.55 0.46 0.38 0.31 0.22 0.15 0.07 Na2O 

minor minor 0.21 0.19 0.17 0.15 0.13 0.11 0.11 P2O5 

minor minor 0.12 0.11 0.10 0.09 0.09 0.08 0.07 MnO 

0.7 ± 0.3 0.5-1.3 0.98 1.00 1.00 1.01 1.01 1.03 1.03 K2O 

 

Table 3.  Physical and mechanical properties of the control and the blended cements. 

 

Scoria (%) 
PC   

12 10 8 6 4 2 
 

35 36 36 37 36 37 38 3 days 
Compressive 

strength (MPa) 42 43 43 44 44 45 46 
7 days 

48 50 51 53 54 55 57 28 days 

1.2 0.8 1.2 1.2 1.2 1 0.9 90 μm 
Fineness 

13 11.2 12 12 12 9 11 45 μm 

3310 3420 3340 3330 3290 3380 3300      Blaine (cm
2
/gm) 

70 70 60 70 60 60 60 Initial Setting Time 

(min.) 140 130 130 120 130 130 140 Final 

29.2 29.2 29.2 29.2 28.8 28.8 28.8 Water demand (%) 

 

 

The scoria blended cement mortars to be used for compressive strength testing were prepared to have a w/c 

of 0.5 as stated in EN 196-1 [29]. Table 3 shows the compressive strength values after 3, 7 and 28 days curing. 

The results of compressive strength development for all mortar mixes containing varying amounts of scoria are 

given in Figures 6 and 7. As expected,all mortars show an increase in strength with curing time. Mortar specimens 

containing PC have higher compressive strengths at any curing time compared to scoria blended cement mortars. 

Also, it is seen that the compressive strength of scoria blended cement mortars decreases as the scoria content 

increases for all curing times. In EN 197-1 [32], early strength (3 days) values should be greater than 10 MPa and 

standard strength (28 days) values should be between 42.5 MPa and 62.5 MPa. A literature survey shows that the 

compressive strength of a mortar is decreased by scoria content, due to the reduction of clinker content in the 

cement mixture [10-12]. However, according to comparison of the obtained results with the EN 197-1 [32], the 

strength requirements were satisfied by the scoria blended cements up to 12% content. 

 

 



PRELIMINARY ASSESSMENT OF UTILIZATION 

117 

 

 

 

Figure 5.  Relationship between major oxides and the scoria content in cements. 

 
 

Figure 6. Correlation between compressive strength of the PC and the scoria blended cement at different curing   

times. 

30

35

40

45

50

55

60

0 5 10 15 20 25 30

C
o

m
p

r
e

s
s

iv
e

 s
tr

e
n

g
th

 (
M

P
a

)

Curing time (Day)

12%  Scoria

10%  s

8% s

6% s

4% s

2% s

0 % (PC control)



IBRAHIM A. AL-AKHALY  ET AL 

 

118 

 

 

 

Figure 7. Effect of the scoria content on compressive strength at different curing times. 

4. Conclusion  

This paper describes the potential use of scoria from Al-Jaif (NW Sana'a, Yemen) as an additive material to 

manufacture blended cement. The following conclusions were obtained: The studied scoria is mainly composed of 

amorphous silica (volcanic glass) and there are phenocrysts of olivine, plagioclase, pyroxene and a few of zeolite 

(clinoptilolite). It has a mainly hyalopilitic-porphyritic texture. Accordingly, it can be considered as a good 

additive for the cement industry. The scoria has as its major chemical components SiO2, Al2O3 and Fe2O3, 

conforming to the chemical requirements of the ASTM and EN standards. The experimental results presented in 

this study show that the physical characteristics of the cement containing scoria are in conformity with the 

standard requirements. The scoria possesses sufficient pozzolanic characteristics to be used as an additive during 

cement production, since it satisfies the standard requirements. Finally, according to the results obtained, it is 

suggested that Al-Jaif scoria can be used up to 12% as a partial substitute for PC in production of blended cement. 

This addition ratio could provide economic and environmental benefits due to reduced clinker consumption and 

lowered CO2 emissions from cement production. 

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C
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34. Lea, F.M. The chemistry of cement and concrete, 3rd Edition. London: Arnold Publishers, London, UK, 1976.  
 

Received   15 October 2017 

Accepted   26 February 2018 
 

 

http://dx.doi.org/10.3989/mc.2017.00716