STATE-OF-THE-ART REVIEW OF COLLAPSING SOILS


  Science and Technology, 6 (2001) 55-66 
  ©2001 Sultan Qaboos University 
 

Use of Isotope and Solute Chemistry to Define the 
Sources of Pollution in Mawqaq Groundwater, Hail, 
Saudi Arabia  

Ibrahim Abdulaziz Al-Sagaby and Mohamed Ali Moallim 

Earth Sciences Program, Natural Resource and Environment Research Institute King  
Abdulaziz City for Sciences and Technology (KACST), Box 6086 Riyadh 11442, Saudi 
Arabia.   

 فى المياه الجوفية مصادر التّلوِث على عّرفَ التحليلية فى التإستعمال النظائر المشعِة والكيمياِء 
 العربية السعوديةبالمملكة  يل،، حا    فى ماوقاق      

 معلمالساجابي ومحمد علي  زيزالعإبراهيم عبد

أكثر  .الجمالىزراعي و ال  و صناعيستعمال المنزلى و ال    اال لألغراِض المختلفِة مثل  المياه الجوفية فى المنطقة     ستعمُل  ت :خالصة
هو الهدف   وقد كان    . والمناطق المحيطة بها   في مدينِة ماوقاق    فى حقل ضحل  قَْد ُجِمعتْ    المياه الجوفية    عينات   عينة من    نيمن ست 

نظائر ال لستعمابا مياه الجوفية  ال بكتريولوجي في التلوث  الو) 03 أوإن  ( نترات   ال مصادرالمياه الجوفية وتحديد    وعية  دراسة ن 
). لتر/ ملغرام 500 (لمسموح به فى مياه الشرب    حِد ا الملوحِة أعلِى من    التركيِز    متوسط وقد اتضح من نتائج الدراسة أن     . ةمشعال

في )  إن   03  أو إن( النّتراِت  كنتروجيِن     كميات عالية من     صودفَ أيضا من المياه المالحة كما     ثالث مجموعات   وقد تم تحديد    
 ُعمرأمكن تحديد مستقّرة المشعة النظائر وباستخدام ال. كوليفورم في بعض اآلباِرال جراثيم منطقة ، وقد تم العثور أيضا على  الهذه  

إجراءات عالجية وبرنامِج وقد أتخذت السلطات الصحية المختصة والبلديات . وقاقالمياه الجوفية فى منطقة ما التّلوِث في ومصدر
 .سلطاتهذه البين لتّنسيِق طبقان بايُمَراقََبة 

 
ABSTRACT: Groundwater in the area is used for different purposes like domestic, agricultural, 
industrial and landscaping. More than sixty groundwater samples were collected in an alluvial 
shallow aquifer in and around Mawqaq Town. The objective was to study groundwater quality and 
identify the sources of Nitrate (NO3) and bacteriological pollution in groundwater using 
environmental isotopes (2H, 3H and 18O). The results of the study have revealed the presence of 
average salinity concentration higher than the permissible limits (500 mg/l) for drinking water. Three 
groups of water saline boundaries were identified. The presence of high nitrate as nitrogen (NO3-N) 
was also encountered in the study area. Coliform bacteria have also been identified in some wells. 
Application of stable isotope has shown the age, origin and the sources of the pollution in the 
groundwater of Mawqaq area. Appropriate health and municipal authorities of the area have initiated 
remedial measures and a monitoring program is to be implemented in coordination with these 
authorities. 
 
KEYWARDS: Salinity, Bacteriological, Pollution, Septic Tanks, Nitrate, Saudi and Remedial.  

1. Introduction 

The shallow groundwater aquifers have been increasingly used to meet the different uses 
resulting from urban expansion and agricultural activities. Constraints imposed by quality and 
growing problems of contamination has become very important issues. Water supply requires an 
understanding of groundwater flow and the chemical processes involved in the water bearing 
systems in order to develop, augment and present a solution to any problem in the water supply 
system. Shallow aquifers in the Kingdom are the main water supply for rural areas and are prone to 
chemical change and contamination from many factors such as formational change, high pumping, 
salt intrusion, septic tanks and agricultural activities. Concerns for water resources shortage and 
augmentation demands were received from the inhabitants of Mawqaq town, in central Saudi 

55 



AL-SAGABY and MOHAMED ALI MOALLIM  
 

Arabia. The research presented in this paper is part of a study that covered hydrogeology, 
hydrogeochemical and geophysical investigations to develop water resources and to find adequate 
water supply in an acceptable quantity and quality for the town. The nearest similar groundwater 
quality studies were done in Qasim and Hail. Few detailed studies can be found in the literature 
about the chemistry and quality change (Alsagaby and Moallim, 1996; Sharaf and Hussein, 1996; 
Sowayan and Allayla 1989; Hussein, et. al. 1992; Segar, 1988; Edgell, 1989; Jerias, 1986; BRGM, 
1985 and Watban, 1976). Various ideas in different topics were achieved and presented in these 
studies. High saline groundwater, elevated nitrate concentration and bacteriological contamination 
were encountered in the supply system of Mowqaq town. The objective of this study is to apply 
solute chemistry and isotopes to clarify the sources of water quality change and biological 
contamination in the shallow aquifer and present a solution to the contaminated groundwater 
supply system. 

2. Description and Geological Setting of the Study Area 

       Mawqaq Town lies in the middle of a Wadi alluvial deposit surrounded by mountains, at an 
elevation of 1200 m above sea level. It lies 65 km southwest of Hail the capital of the area. It is 
elongated in an alluvial strip towards northwest direction and depicted between longitude 410 00’ 
00” and 410 20’ 00” and latitude 270 15’ 00” and 270 30’ 00”. The relevant physiographics 
structures (Figure 1) around the town can be described as dunes in the north, mountains in the east 
and south and wadis in the west. Three alluvial Wadi trends are identified to be the main 
watercourses, which enter the town from the south and passes towards the north as observed from 
the satellite image and verified in the field. These trends were also observed from the preliminary 
analysis of water samples. Three distinctive water types were defined from the preliminary 
chemical data analysis.   
 

to Hail

mawqaq

to Hail

 
Figure 1. Topogaphic map of Mawqaq- Hail area. 

 56



USE OF ISOTOPE AND SOLUTE CHEMISTRY  
 

Geologically, the study area is located in the middle of the northern part of the Arabian shield 
in central Saudi Arabia. It is composed of a low lying plain composed of sand and gravel of various 
grain sizes with low strength of consolidated beds intercalated in the alluvial material deposited 
originally by floods from the mountains. A complex of crystalline rocks of various nature and 
origin surrounds this low land filled by alluvial fans. Buried channels of various extensions are 
located. The forms and directions of the channels were controlled by structural phenomenon. Small 
mountains of crystalline rocks are scattered in the plain. The major crystalline rocks surrounding 
the study area can be texturally classified into porphyry and aphanitic Granite. The age of the 
recognized rock range from Precambrian to Tertiary followed by Quaternary alluvial deposits in 
stratigraphical sequence, (Figure 2). 

The Precambrian units in the area are divided into two groups: Sedimentary and volcanic  
(layered) rocks and plutonic rocks. The layered rocks are classified as Banana Formation (volcanic 
and hypabysal rocks) and Hadn Formation of silicic volcanic intercalated with fieldpathic 
sedimentary rocks. The rocks covering this area are characterized by the presence of medium to 
coarse Granite, monzogranite and Grandiorate with Biotite and Hornblende. The Mawqaq complex 
is, in general, made of deformed, metamorphosed and foliated Biotite with or without hornblende, 
Granodiorite, Tonalite, Monzogranite and quartz Diorite.  The overall intrusive relationship of all 
rock types in the area is not clear, but it appears that these quartz Diorites and Tonalites are closely 
related and Granodiorite and Monzograinte appears to be somewhat younger. These rocks are cut 
by series of Basalt dikes, which also appears to be related to the intrusive complex.  Olivine Basalt 
of Tertiary age occupies, as a field of pipeline and necks, throughout the area. Quaternary alluvial 
and colluvim deposits of unconsolidated Wadi material and pediment silt, sand and gravel occur in 
the study area.  Deposits of alluvial fan originating from the Wadi drainage system were located to 
the south and west of Jabal Aja. Moderate to well sort sand sized particles, but includes silt, and 
pebbles in the wadi channels dominate these sediments. Complicated tectonic history and 
formation of structural diversity in consequence of tectonic events have affected the area. 
Metamorphism of various degrees has been reported and intrusion of molten material, resulting in 
the creation of dikes.  Lineaments and faults, which control the pattern and formation of the 
alluvial aquifer and groundwater flow, were also found in the study area (Stoesser and Elliot, 
1985). 

 

 
 

Figure 2. Simplified geologic map of Mawqaq (Hail area). 

 57



AL-SAGABY and MOHAMED ALI MOALLIM  
 

3. Methods and Material 

More than 60 samples from water wells in the study area for water quality assessment were 
collected in order to achieve reasonable interpretation, evaluate the sources of groundwater salinity 
and delineate any possible pollution. Representative chemical and bacteriological groundwater 
samples in the study area were used in order to assess water quality.  Measurements of pH, 
temperature, and EC were done in the field. The analyses conducted in the laboratory included 
major anions like Ca, Mg, Na, K, CL, SO4, HCO3, NO3, and hardness as CaCO3 and CO3. 
Sampling has been conducted with time difference of about three month.  The first sampling (55 
samples) was started in March 1998 and second part (11 samples) was in July 1998. 

 
Figure 3. Total dissolved solids in Mawqaq wells, Hail area. 

4. Results and Discussion 

4.1   Water Quality 
The results of the data collected from the field have shown field pH variation ranging from 

7.86, slightly alkaline water, to 5.67, slightly acidic water.  
Groundwater salinity in the aquifer changes from low to high saline along the down gradient. 

The maximum TDS (5786 mg/l) in the aquifer is found in the north and the minimum (265 mg/l) in 
the south with average of about 1960 mg/l. The average salinity is higher than the permissible limit 
(500 mg/l) for drinking water (WHO, 1984). This increase of TDS coincides with the decrease of 
well production in the area. The result also revealed an abrupt salinity change within a perimeter in 
some locations coupled with water well depth change in some parts of the study area, especially in 
the northern part. Structural complexity, which controlled the depositional environment of the 
alluvial material of the aquifer, may have contributed to the salinity increase. 

Figure 3 presents the pattern and distribution of salinity in the aquifer. Three salinity trends 
and boundaries were observed from the Figure. The first saline condition extends from the southern 
boundary to 1000 mg/l salinity (low salinity condition) and the second lies between 1000 mg/l-

 58



USE OF ISOTOPE AND SOLUTE CHEMISTRY  
 

salinity boundary and 3000 mg/l-salinity boundary (moderate salinity condition). The third system 
of salinity is seen above 3000 mg/l salinity boundary (high salinity condition). The chemical data 
have also revealed that about 50% of the sampled wells high chloride concentrations above the 
acceptable limits for drinking water (CL>250 mg/l). About 43 % of the samples have a sulfate 
concentration of more than the acceptable limits for drinking water (SO4 >250 mg/l). High sodium, 
calcium and bicarbonate concentrations were also observed (Table1). Geologically, the aquifer is a 
recent alluvial aquifer and has characteristically high saline water.  

4.2   Ion Relationship and Water Composition 

The quality of water generally expected from an alluvial aquifer is an access of Ca-HCO3 
water type unless influences by other materials are involved in the system. A plot of chloride 
versus sodium (Figure 4) for the study area shows nearly a 1:1 ratio in the beginning of the graph 
and chloride starts increasing reaching a concentration of about 1400 mg/l (39.5 meq/l), while 
maintaining the same sodium concentration of up to 200 mg/l (8.7 meq/l).  Scattered points, were 
observed at the end of the graph.  Figure 5 displays a water type of high chloride with proportional 
sodium in the beginning and in the middle part, while at the end of the graph the ratio is nearly 
maintained constant proportion. The line nearly extrapolates to the sodium axis, indicating that 
high concentration of sodium is present in the system. Moreover, significant concentration of 
sulfate scattered at three different groups with different concentrations and positive correlation 
between TDS and sulfate were observed. Figure 6 presents bicarbonate distribution as a function of 
total dissolved solids in the aquifer and displays three distinctive constant concentrations of 
bicarbonate. The possible interpretation is mixing between fresh water and saline water. This 
mixing could be the result of modern day recharged waters (high bicarbonate).  

 
Table 1: Mawqaq isotopic data 

 
Serial # Name Delta 0-18 Delta D 

1.  Mq1 -1.72 -0.4 
2.  Mq2 -1.95 -3 
3.  Mq3 -0.35 -0.8 
4.  Mq7 9.53  
5.  Mq8 0.03 1.6 
6.  Mq9 0.01 1.7 
7.  Mq10 -1.38 -3 
8.  Mq13 -0.93 -2.2 
9.  Mq15 -0.77  
10.  Mq17 -1.35 -1.9 
11.  Mq19 -0.98 -4 
12.  Mq20 -2 -7.1 
13.  Mq22 0.46 -0.3 
14.  Mq29 -2.21 -2.4 
15.  Mq32 5.67  
16.  Mq36 6.45 15.7 
17.  Mq42 0.5 -4.6 
18.  Mq43 -2.14 -2.3 
19.  Mq44 -1.59 -2.9 
20.  Mq50 -2.27 -4.5 
21.  Mq53 -1.06 -5.2 
22.  Mq55 -0.32 -2 

 
Hem (1970) has reported that nearly all-natural waters, in terms of chemical classification, lie 

between 0.55 to 0.75 (correlation coefficients for EC and TDS). A mixture of water types 

 59



AL-SAGABY and MOHAMED ALI MOALLIM  
 

represented by NaCL, CaSO4 and NaSO4 range between 0.65 to 0.75. The relationship between EC 
and TDS is shown in Figure 7. 

The  coexistence  of  a  good  relationship is  evident from  the correlation coefficients (R2 = 
1). The conversion factor (0.65) for the samples falls in the range designated for NaCL, Mg-CaSO4, 
NaSO4 and Ca-HCO3 water type by Hem (1970). Therefore, a mixing system of waters is prevalent 
in the aquifer.  

4.3  Groundwater Pollution 

Certain environmental conditions may have resulted in a widespread distribution of 
groundwater pollution in Mawqaq town. In the study area, it is manifested by the way in which 
septic tanks are constructed. The presence of harmful contaminants indicates that environmental 
controls should be applied in the area.  Biochemical contaminant presence in the groundwater of 
the study area makes it necessary to initiate protection of the groundwater for the inhabitants of the 
town. The sources of the pollution, its impact and solutions will be considered in the following 
paragraphs. 

4.4  Nitrate Pollution (NO3-N) 

In addition to high salinity presence, very significant high nitrate concentrations, which 
increases towards down gradient of the aquifer, have been recorded in the study area. The nitrate 
concentration recorded in the water samples range from 2.8 mg/l (minimum) to 497 mg/l 
(maximum) with an average of 111.53 mg/l. The geographical distribution of nitrate concentration 
in groundwater of the alluvial aquifer is shown in Figure 8. Elevated concentrations are found in 
the northern part of the aquifer although local variations are common in some parts.  Artificial 
fertilizers for farming purposes were not used in the area (personal contact with inhabitants). The 
presence of nitrate as nitrogen in Mawqaq groundwater is higher than the permissible limit for the 
drinking water (10 mg/l), which was defined by World Health Organization in 1981 and 1993 
(Edmunds and gaye, 1997).  

Figure 4. A plot of chloride versus sodium for Mawqaq wells, Hail area

0

200

400

600

800

1000

1200

1400

0 500 1000 1500 2000 2500

Chloride concentration (mg/l)

So
di

um
 c

on
ce

nt
ra

tio
n 

 
High nitrate concentrations are generally assumed to be the results of human activities, but 

occurrences of high NO3 groundwater far from man made activities have been recorded in arid and 
semiarid regions, especially in North Africa. Up to 2800 mg/l of NO3-N were recorded in Sudan, 

 60



USE OF ISOTOPE AND SOLUTE CHEMISTRY  
 

near Khartoum. This was attributed to very low recharge rates and the accumulations from 
vegetation over many centuries. In Kalahari and Libya similar problems were encountered 
(Edmunds et. al., 1992). Excess of Nitrogen concentrations in groundwater, leaching from the 
domestic septic systems, (residential area) and wastewater disposals were also recorded in 
Australia (Gerriste, et. al. 1995) and in Ontario, Canada (Aravena, et. al, 1993). 

 
 

0

200

400

600

800

1000

1200

1400

1600

1800

0 1000 2000 3000 4000 5000 6000 7000

TDS concentration ( mg / l )

Su
lf

at
e 

co
nc

en
tr

at
io

n 

 
Figure 5. A plot of TDS versus sulfate in the study area. 

 
 

 

0

100

200

300

400

500

600

700

0 1000 2000 3000 4000 5000 6000 7000

TDS (mg /l)

B
io

ca
rb

on
at

e 
co

nc
en

tr
at

io
n 

Figure 6. A plot of TDS vs biocarbonate in the study area. 
 

 61



AL-SAGABY and MOHAMED ALI MOALLIM  
 

y = 0 .65 x
R 2  = 1

0

1000

2000

3000

4000

5000

6000

7000

0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000

EC Micromhos /cm )

T
D

S 
co

nc
en

tr
at

io
n 

Figure 7. Electric conductivity vs total dissolved solids (TDS) in the study area. 
 

 

 62



USE OF ISOTOPE AND SOLUTE CHEMISTRY  
 

Figure 9 presents a pattern of NO3 /Cl ratio. The nitrate enrichment is a wide variation of 
wetter and drier periods in the unsaturated soils. Therefore, the mechanism of enrichment of NO3–
N in the system is likely to be due to the presence of leguminous plants or nitrogen fixation of 
indigenous plants (vegetation). It could come as a loss of nitrogen from the domestic septic tanks 
systems since there are no applications of fertilizers in the agricultural system or manure from the 
animals. The latter hypothesis (septic tanks) is more acceptable because the concentration of nitrate 
as nitrogen in groundwater is relatively very high in the inhabited area while nitrate concentration 
in the outside of the town (Mq1 and Mq2) is very low. 

4.5   Bacteriological Pollution 

The significance of the various coliform organisms in Mawqaq groundwater was considered in 
order to determine the nature of the pollution, detect and estimate the coliform group of bacteria. 
Almost all the extension of aquifer was not covered for bacteriological sampling but random 
sampling has been conducted for this matter, especially in the northern part, where some people are 
utilizing water for various usage. The Directorate General of Health in the Region has sampled 
about 10 wells and reported the presence of harmful bacteria in some wells.  The septic tank 
systems are parallel with the wells in some areas, especially in the north of the town with slight 
difference in depth. Aquifer material is mainly channeling deposits, which helps seepage, 
infiltration, and easy flow in the fractures and faults available in the area. 

 

0

0.5

1

1.5

2

2.5

MQ
1
MQ

2B
MQ

3B
MQ

6
MQ

8
MQ

10
MQ

13
MQ

15
MQ

17
MQ

20
MQ

23
MQ

25
MQ

27
MQ

29
MQ

31
MQ

34
MQ

36
MQ

38
MQ

41
MQ

43
MQ

45
MQ

47
MQ

49
MQ

52
MQ

54
MQ

57
MQ

59
MQ

61
MQ

63
MQ

65
MQ

67

Well ID #

R
at

io
 o

f N
O

3/ C
L

Figure 9. Plot of NO3/CL for Mawqaq groundwater. 
 

 
The presence of bacteria, which lives in the intestine of human being and animals, is suspected 

in the groundwater system. The main point source of contaminants in shallow groundwater systems 
in the area and the growth of bacteria in these systems is mainly attributed to the processes, which 
occur in the septic systems for household wastewater disposals. The impact of septic tank systems 
on groundwater contamination and its consequence to the environment have been addressed and 
disinfection of the wells has been made with constant monitoring of the concerned authorities. 

 63



AL-SAGABY and MOHAMED ALI MOALLIM  
 

4.6   Isotopic Application 

4.6.1  Tritium  
Tritium data, which are useful for providing information for modern recharge, have been collected 
randomly in the study area. The tritium result has shown that the maximum content of tritium in 
Mawqaq groundwater is about 8.7TU and the minimum is about 1TU and the average is 5.33TU. 
These values present a picture of a pre-and post-pump replenishment and characterization of old 
and young recharge in the alluvial aquifer.  Figure 10 shows a linear plot of tritium versus TDS and 
emphasizes the relationship between the salinity and tritium in Mawqaq groundwater. Sample 
Mq16 is spring water, which flows from the mountains, with low TDS concentration and relatively 
moderate content of tritium.  This plot shows three grouping patterns of samples in relation to the 
salinity of the area. First group shows low TDS concentration, which represents juvenile water, and 
relatively high content of tritium. The second group has moderate TDS concentration and relatively 
low tritium (transitional of two mixing system) while the third group is characterized by very high 
salinity and moderate tritium content. Thus, this is the condition of Post pump groundwater with 
the exceptional salinity elevation presence cases. There are rare cases in which fresh groundwater 
is characterized by high salinity. The attribute to the presence of high saline groundwater is due to 
the vicinity of the source of sabkha deposits in Mawqaq area. 

4.7  Oxygen-18 and Deuterium 

Deep groundwater usually reflects the long-term average isotopic composition recharge waters 
while shallow groundwater reflects more closely short-term isotope variability in precipitation and 
change in the ratio of winter and summer. Table 1 shows the oxygen-18 and deuterium data for the 
study area. Figure 11 reflects the pattern of deuterium and Oxygen-18 in Mawqaq groundwater. 
The picture presents mainly three types of distribution of isotope, which has a relation with the 
origin of water, and replenishment of groundwater. These groups present a picture of old and 
young groundwater. These groupings are also mentioned earlier in Figure 10.   

0

1

2

3

4

5

6

7

8

9

10

0 500 1000 1500 2000 2500 3000

TDS (mg /l)

3H
 

(

Sping water

Figure 10. TDS concentration vs tritium content in the study area. 

 64



USE OF ISOTOPE AND SOLUTE CHEMISTRY  
 

y = -17x + 396
R2 = 0.9897

y = -0.0755x - 0.3042
R2 = 0.0134

-100

-50

0

50

100

150

200

250

300

350

400

0 5 10 15 20 25 30

Delta Deuteriu

D
el

ta
 O

xy
ge

n
18

GMWL

MAWQAQ Wat

Figure 11. Istopic composition Mawqaq  groundwater. 

5. Conclusions 

This study has revealed progressive groundwater quality deterioration towards the central and 
northern part of the town (in the alluvial aquifer). Groundwater salinity in the aquifer increases 
from low to high along the down gradient with maximum TDS (5786 mg/l) is found in the north 
and minimum TDS (265 mg/l) in the south. Ion relationship sequence, water chemistry and 
application of stable isotopes have also shown water grouping in the study area. Transitional 
mixing system was deducted from these results. Structural constraints, improper distribution of 
water wells and uncontrolled pumping are the other main causes of the aquifer deterioration, 
especially in the central and northern part. 

Presence of high-elevated NO3-N concentration was encountered in the study area. The 
existence of hydraulic continuity between septic tank systems and groundwater may be the cause of 
the elevated nitrate concentration. Some harmful bacteria have also been identified in some wells.  

References 

AL-SAGABY, I.A. and MOALLIM, M.A.,  1996, Hydrogeochemical Investigation of the Water  
Wells In and Around KACST Research Center in Qassim Region, Saudi Arabia,  Internal 
Report No.121-18-ES, Natural Resources and Environmental Research Institute, KACST, 
Saudi Arabia.  

ARAVENA, R., EVANS, M.L. and CHERRY, J.A., 1993, Stable Isotopes of Oxygen and Nitrogen 
For Identification of Nitrate from septic systems, Ground water-April-March, 31( 2): 180-186. 

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AL-SAGABY and MOHAMED ALI MOALLIM  
 

BRGM, 1985, Water, Agriculture and Soil Studies of Saq and Overlying Aquifers, Study For 
Ministry of Agriculture and Water, Riyadh, Saudi Arabia. 

EDMUNDS, W.M., DARLING, W.G., KINNIBURGH, S.,  KOTOUB, S. and MAHGOUB, S.  
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EDMUNDS, W.M. and GAYE, C.B., 1997, Naturally High Nitrate Concentrations in Ground  
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GERRISTE, R.G., ADENEY, J.A. and HOSKING, J., 1995. Nitrogen Losses From a Domestic 
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HEM, J.D., 1970. Study and Interpretation of Chemical Characteristics of Natural Water, U. S. 
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HUSSEIN, M.T., BAZUHAIR, A.G. and AGEEB, A.E., 1992. Hydrogeology of the Saq 
Formation,  East of Hail, Northern Saudi Arabia, Quar. J. Eng. Geol. 25: 57-64. 

JERAIS, A.A., 1986. Hydrogeology of Saq Aquifer in Hail Region, Msc. Thesis, Fac. Earth 
Sciences, King Abdulaziz University, Jeddah, Saudi Arabia. 

SEGAR, D.A., 1988. A groundwater Model of the Saq and Tabuk Sandstone Aquifers in South 
Eastern Jordan and Northwestern Saudi Arabia, Msc. Thesis, School of Earth Sciences, 
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SOWAYAN, A.M. and ALLAYLA, R., 1989.  Origin of the saline groundwater in wadi ar rumah, 
Saudi Arabia, Groundwater, 27(4): 481-490.  

SHARAF, M.A. and HUSSIEN, M.T., 1996. Groundwater Quality in Saq Aquifer, Saudi  Arabia, 
Hydrogeological Sciences Journal, 41(5): 683-670. 

STOESSER, D.B. and ELLIOT, J.E., 1985. Reconnaissance Geology of Al-Qasr Quadrangle, sheet 
27/41c: Open-file report USGS-of-05-2, Ministry of Petroleum and mineral Resources, 
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WATBAN, N.F., 1976. Groundwater Potentiality of Tabuk and Saq aquifers in Qassim Region, 
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WORLD HEALTH ORGANIZATION (WHO), 1984, Guidelines for Drinking Water Quality, Vol. 
2, Health Criteria and Other Supporting Information, Geneva. 

 
 
 
Received   4 March 2000   
Accepted   1 June 2000  
 

 
 
 
 
 
 

 

 66


	Ibrahim Abdulaziz Al-Sagaby and Mohamed Ali Moallim
	Introduction
	
	
	
	Methods and Material


	JERAIS, A.A., 1986. Hydrogeology of Saq Aquifer in Hail Region, Msc. Thesis, Fac. Earth Sciences, King Abdulaziz University, Jeddah, Saudi Arabia.