Mech070131.qxd


The Journal of Engineering Research  Vol. 6, No.1, (2009)  51-58

1.  Introduction

The main water supplies in the Dhofar Region (south
of the Sultanate of Oman) come from a groundwater dis-
tribution system. The exploitation of the water system
contributes to the underground intrusion of salt water into
the coastal plain around Salalah (Salalah is the administra-
tive  capital of  Dhofar Region).  Hence, as  more ground
_______________________________________
*Corresponding author’s e-mail:  sabah1@squ.edu.om

water is extracted from the mountains,  less water is avail-
able to the people living on the plain (Alesh, 1998).
Moreover, the coastal plain (Salalah & sea) is an impor-
tant farming area.  The groundwater is used for coconuts, 
bananas, vegetables and grass fodder cultivation.
Recently, there has been an increase in grass fodder culti-
vation using large-scale groundwater irrigation
(Kobayashi, 2001). In the mountain area (Jabal Dhofar),
there is traditional livestock farming (mostly cows &
goats) utilizing wild vegetation as fodder.  In the arid area

Fog and Rain Water Collection from Trees in the Dhofar
Region in the Sultanate of Oman

S. A. Abdul-Wahab*a, H. Al-Hinaia, K. A. Al-Najarb, M. S. Al-Kalbanic

aMechanical & Industrial Engineering Department, College of Engineering, Sultan Qaboos University, P.O. Box 33, P.C. 123, 
Al-Khoud, Sultaname of Oman

bCivil Aviation and Meteorology, Meteorology Department, Salalah Airport, Muscat, Sultanate of Oman
cCivil & Architectural Engineering Department, College of Engineering, Sultan Qaboos University, P.O. Box 33, PC 123, 

Al-Khoud, Muscat, Sultanate of Oman

Received 12 May 2007; accepted 13 November 2007

Abstract: This work had two purposes.  The first was to measure and investigate the amount of fog and rain water collect-
ed by a sample of trees during the summer monsoon season in the mountains of the Dhofar region in the south of Oman.
The second purpose was to assess the potential of trees with different leaf shapes, sizes and cross sectional canopy areas to
collect fog and rain water in the area.  In order to meet these purposes three different tree species, were selected for experi-
mental investigation and field measurements. They included fig, lemon, and tamarind trees.  The experiments were designed
and implemented in the monsoon season of 2006, between the 13th of July and the 3rd of September.  The daily measure-
ments of water collection showed that the three species of tree have different water collection capacities.  It was found that
the fig tree collected the least water.  The fog water collection of the fig tree over a period of 47 days between the 13th of
July and the 3rd of September was 140.5 L/m2, or an average of 2.7 L/m2/d. The fog water collection of the lemon tree was
243.0 L/m2, or an average of 4.4 L/m2/d.  In terms of potential collection of the tamarind tree, the results showed that it col-
lected a fog water of 218.9 L/m2, or an average of 4.3 L/m2/d over the same period. The study contributes to the knowledge
of how different tree species collect fog and rain water, and concludes with a set of recommendations.

Keywords: Fog water  collection  by  trees, Fig, Lemon, Tamarind monsoon season, Dhofar region,
Oman

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The Journal of Engineering Research  Vol. 6, No.1 (2009)  51-58

(Nejid) there is traditional nomadic camel farming.  These
heavy demands on the water supplies stress the need to
investigate all possible sources of water which may con-
tribute to the alleviation of this situation (COWIconsult,
1992). 

Non-conventional water supplies, such as fog water
collection, offer possible solutions to this problem. Fog
water collection has the ability to provide an alternative
source of water, while at the same time reducing depend-
ence on traditional water sources such as groundwater.

The Dhofar Region, which is located between latitudes
16 and 20°N occupies nearly one third of the Sultanate's
total area, experiences the annual phenomenon of Al-
Khareef (ie. monsoon season) each summer between June
and September. This region of Oman is touched by the
south west monsoon and experiences by rain and thick fog
caused by wet air from the Indian Ocean. Generally, fog
occurs on 20% to 25% of days during the year.  This fog
has the potential to provide an alternative source of water.
It can be collected during the monsoon season (from mid-
June to mid-September) and can provide substantial vol-
umes of water for domestic use and small-scale farming in
the mountains.  Hence, exploitation of this phenomenon
and the development of some form of fog harvesting could
provide a valuable additional source of water where it is
most needed.  For example, the collected fog water could
be used for the reforestation of the mountains, thus reduc-
ing the dependence on groundwater.  

The first published studies on water collection from the
monsoon clouds of the Jabal Dhofar were developed by
Fallon (1978).  He used wire netting to intercept water and
increase the precipitation.  Stanley Price, et al. (1985)
started new investigations of fog water collection and the
results indicated that up to 50 L/d could be collected by a
1 m2 screen of aluminium wire mesh.  A research project
into fog collection technology was then undertaken in the
Dhofar Region during the 1989 monsoon season by
(Barros and Whitcombe, 1989). The study investigated the
possible applications and benefits of fog water collection
techniques.  The results of the study in the coastal moun-
tain region showed the feasibility of this technology for
collecting water.  It was demonstrated that in the upper
elevations from 900 to 1000 m, the average collection
rates, using 1 m2 standard collectors and much larger col-
lectors, of 30 to 40 L/m2/d were obtained over a 2 month
period.  This compared well with a study in Chile where 6
L/m2/d was collected over a period of 12 months (Barros
and Whitcombe, 1989). However, the pipe cost from col-
lectors to the point of use was one of the major infrastruc-
ture costs that made the system uneconomic and hydrauli-
cally difficult. For the same area, a second research proj-
ect was carried out during the monsoon in 1990.  A num-
ber of fog-collection experiments were undertaken in this
project in the coastal mountain region.  The results of the
experiments indicated the feasibility and applicability of
the fog collection technology for collecting water. Abdul-
Wahab, et al. (2006a) examined the potential of fog water
usage in certain Jabal areas (mountains) of the Dhofar
Region when fog collectors were built in the vicinity of

the houses in the mountains. The aim of this work was to
develop residential-type fog collectors to directly meet the
needs of the mountain residents during the monsoon sea-
son, and to decrease the abstraction of groundwater.  Costs
were reduced by constructing the collectors close to the
point of use.  The collected water was used directly in the
storage tanks, which were installed in the houses, to irri-
gate plants or to supply animals and people with water on
a daily basis. A detailed examination of several other fog
collection studies conducted in the Sultanate of Oman can
be found elsewhere (Abdul-Wahab, et al. 2006a, 2006b;
Abdul-Wahab and Lea, 2006; Alesh, 1998, 2003).  

The collection of water from trees is a long established
traditional practice. The experiments carried out in 1989
and 1990 in the Dhofar Region of the Sultanate of Oman
clearly indicated the ability of trees to collect water in sig-
nificant amounts (Barros and Whitcombe, 1989;
COWIconsult, 1992).  The experiments demonstrated the
water collecting ability of trees in the Jabal.  They also
showed the potentially important role of trees in aquifer
recharge in mountainous regions.   This was based on the
fact that much of the water collected by trees during the
monsoon exceeded their immediate needs.  Thus a consid-
erable amount of water is available to seep into the soil
and to percolate through into the local groundwater
aquifers (Barros and Whitcombe, 1989; COWIconsult,
1992).  COWIconsult (1992) reported that the trees play
an important role in the recharge of groundwater.  Water
which percolates through the soil is usually consumed by
the vegetation and so benefits the plant growth and there-
by grazing on the Jabal.  This means that water percolat-
ing into the groundwater aquifers is likely to benefit
groundwater abstraction in either the Jabal or the Salalah
plain.

When interpreting the results in terms of potential col-
lection per tree of a given canopy size, many factors
required to be considered.  Among these factors are: the
actual size of the canopy, its projection at right angles to
the wind direction, the effect of the three dimensional
canopy, the amount of collected water reaching the cis-
tern, any evaporation during the monitoring period, the
effect of the leaf size, branch and twig size, density, and
the effect of the surrounding trees (COWIconsult, 1992).

The present study was designed to derive more infor-
mation on collection of fog and rain water by trees during
the summer monsoon season  2006 at Dhofar Region in
the Sultanate of Oman.  In order to meet this objective, a
house in the mountains of Dhofar Region (at Ashta) was
selected.  At this house, fog collection experiments were
carried out by using three species of tree including fig,
lemon, and tamarind trees.  The amount of water collect-
ed by each tree was measured in a cistern constructed
under each tree.  The information derived from this study
will be useful in future water harvesting initiatives.  

2.  Methodology

A suitable house at Ashta in the Mountain of the Dhofar
region was selected for the fog collection experiments



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(Fig. 1) by taking into account four factors, namely, (a) the
potential for collecting large volumes of water, (b) the
proximity of a water-poor community, (c) accessibility
and (d) security.  

At this house at Ashta, three specific trees were select-
ed- a fig, a lemon and a tamarind- to harvest the fog and
rain water during the monsoon season.    Characteristics of
the three trees used in the study together with the dimen-
sions of their cisterns are summarized in Table 1.  It can
be seen from this table that the approximate cross section-
al area of the tamarind tree (42.76 m2) was higher than that
of fig (16.18 m2) and lemon tress (20.84 m2).  

Under each tree a cistern was constructed to serve as
collecting tank.  The purpose of this cistern was to hold
fog and rain water harvested by the tree during the mon-
soon.  The cistern was constructed in such away that it was
big enough for the size of the tree over it.  This in fact
ensured that branches of the tree did not extend beyond
the rim of the tank and water thus did not drip outside the
cistern.    It was very important to make sure that the cis-
tern collected all the water that the tree harvested from the

fog.  It should be noted that the local residents were
involved to assist with the construction of the cistern
underneath the three trees.  The experiments at Ashta
house on the three trees started on 13th of July and lasted
until 3rd September 2006.  

During the foggy conditions or rain episodes, small fog
droplets were deposited on the tree and coalesced to form
larger drops which flowed downwards under the force of
gravity into the cistern fixed below the tree.  The water
was then channeled to a storage tank located in the house. 

Moreover, a standard rain gauge was placed in situ at
the project site to measure the daily amount of rainfall col-
lected on the site.  The purpose of this rain gauge was to
determine the contribution of fog relative to the total water
yield.  It was assumed that whenever rain was recorded by
the rain gauge, all the water deposited on the trees origi-
nated exclusively from rainfall. On the other hand, if no
rain was recorded, all the water collected by the trees was
assumed to originate from fog alone. Although this tech-
nique underestimates the contribution by fog, it does give
some indication of the relative contributions of fog and

Figure 1.  Map of the Sultanate of Oman and the project location at Ashta house in the mountain of Dhofar
Region



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rainfall to the total volume of water collected. Therefore,
rainwater collection was subtracted from the total fog and
rainwater collection to yield the fog water collection.

3.  Experimental Results

3.1. Fog and Rainwater Collection Data
Tables 2, 3, and 4 illustrate the total and net fog water

collected daily from the three trees during July, August
and September 2006, respectively.  It should be noted that
the net fog water collected was determined by taking the
difference between the total water collected (ie. both rain
and fog water collected by tree) and rainwater.  

It can be seen from these tables that the three sample
trees yielded considerable difference with respect to total
water collected.  In general, the amount of total water col-
lected by lemon tree was the highest, followed by
tamarind tree, and finally the fig tree.  The daily mean
total water collected by fig, lemon, and tamarind trees dur-
ing July was 5.9, 7.2, and 5.4 L/m2/d, respectively (Table
2).  The monthly total fog and rainwater collected by these
three trees during July was 112.0, 136.5, and 103.3 L/m2,
respectively.  

During August, the total water collected daily by fig,
lemon, and tamarind trees was 2.9, 5.3, and 5.5 L/m2/d,
respectively (Table 3).  Again, the results of water collec-
tion showed that the fig tree collected the least water of

Type of tree   
Characteristics  of the studied trees  Fig Lemon Tamarind 
Length of the canopy (m)  4.42 4.88 6.10 
Width of the canopy (m)  3.66 4.27 7.01 
Cross sectional area of the canopy (m 2)      16.18 20.84      42.76 
Height of tree from ground to upper branch (m)  6.71 4.08 5.18 
Height of tree from ground to the low er branch (m)  1.52 0.82 1.16 
Length of the leaf (cm)  5.0 5.7 3.5 
Width of the leaf (cm)  3.5 2.7 1.5 
Approximate area of the leaf (cm 2)       17.50 15.39   5.25 
Dimension of cistern beneath the tree (cm 3) 310x310x15 310x310x15  400x400x15  

Table 1.  Characteristics of trees used in the study

Total fog and rainwater collected 
(L/m2/d) 

Net fog water collected 
(L/m2/d) 

Date Fig Lemon Tamarind  

Rainwater 
collected 
(L/m2/d) 

Fig Lemon Tamarind 
13  12.1 13.1 0.0 0.4 11.7 12.7 - 
14       10.2 10.9 0.0 0.6 9.6 10.3 - 
15   10.5 4.4 0.0 1.2 9.3 3.2 - 
16  3.5 4.1 3.3 0.4 3.1 3.7 2.9 
17  1.0 0.7 0.9 0.2 0.8 0.5 0.7 
18  0.0 0.0 0.0 0.0 0.0 0.0 0.0 
19  0.0 0.0 0.0 0.0 0.0 0.0 0.0 
20 2.9 3.7 5.2 0.2 2.7 3.5 5.0 
21 8.4 8.7 5.2 0.4 8.0 8.3 4.8 
22 8.3 10.9 6.5 0.4 7.9 10.5 6.1 
23 4.7 10.7 4.4 1.0 3.7 9.7 3.4 
24 2.6 3.5 2.6 2.2 0.4 1.3 0.4 
25 0.7 0.7 1.2 0.2 0.5 0.5 1.0 
26 4.0 5.9 5.5 0.6 3.4 5.3 4.9 
27 10.4 22.2 18.4 7.0 3.4 15.2 11.4 
28 12.7 18.0 18.8 5.8 6.9 12.2 13.0 
29 9.7 11.2 14.2 5.0 4.7 6.2 9.2 
30 3.9 1.6 8.5 0.8 3.1 0.8 7.7 
31 6.5 6.1 8.4 1.0 5.5 5.1 7.4 

Average 
(L/m2/d) 

5.9 
 

7.2 
 

5.4 
 

1.44 
 

4.5 
 

5.7 
 

4.9 
 

Total 
(L/m2) 112.0 136.5 103.3 27.4 84.6 109.1 78.1 

Table 2.  Total water collected and net fog water collected by the three trees during July 2006



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the three trees.  The total water collected by fig tree was
89.6 L/m2, and that of the lemon tree was 163.6 L/m2, and
that of the tamarind tree was 169.5 L/m2.

During the three days of September, the amount of fog
and rainwater collected by fig was 2.3 L/m2/d, by lemon
tree was 3.7 L/m2/d, and by the tamarind tree was 4.0
L/m2/d (Table 4).  Again, the results indicated that the fig
tree collected least water of the three trees.  The total
water collected by the fig tree was only 7.0 L/m2, while
that collected by the lemon and tamarind trees was 11.0
L/m2 and 12.0 L/m2, respectively.  It should be noted that
in September the fog was not so frequent.  This explains
the lower amounts of water collected.

In terms of potential collection per tree, the results indi-
cated that the fig tree collected a total of 208.6 L/m2 over
a period of 47 days.  The lemon and tamarind trees collect-

ed a total of  311.1 L/m2 and 248.8 L/m2, respectively, over
the same period.

3.2. Fog Collection Data

The daily variations of fog water collected by the three
trees during July and August are presented in Figs. 2a and
2b, respectively.  It is interesting to note that the amount
of fog water collected by each tree differed considerably.
In general, the amount of fog water collected daily by
lemon tree was the highest, followed by the tamarind and
fig trees. Thus, the lemon and tamarind trees were more
efficient than the fig tree in harvesting fog water.  Looking
at Figs.  2a and 2b, it can also be seen that the daily
amount of fog water collected in July was lower than that
collected in August.  In certain day of August, the fog col-

Total fog and rainwater collected 
(L/m2/d) 

Net fog water collected 
(L/m2/d) 

Date Fig Lemon Tamarind  

Rainwater 
collected 
(L/m2/d) 

Fig Lemon Tamarind 
13  12.1 13.1 0.0 0.4 11.7 12.7 - 
14       10.2 10.9 0.0 0.6 9.6 10.3 - 
15   10.5 4.4 0.0 1.2 9.3 3.2 - 
16  3.5 4.1 3.3 0.4 3.1 3.7 2.9 
17  1.0 0.7 0.9 0.2 0.8 0.5 0.7 
18  0.0 0.0 0.0 0.0 0.0 0.0 0.0 
19  0.0 0.0 0.0 0.0 0.0 0.0 0.0 
20 2.9 3.7 5.2 0.2 2.7 3.5 5.0 
21 8.4 8.7 5.2 0.4 8.0 8.3 4.8 
22 8.3 10.9 6.5 0.4 7.9 10.5 6.1 
23 4.7 10.7 4.4 1.0 3.7 9.7 3.4 
24 2.6 3.5 2.6 2.2 0.4 1.3 0.4 
25 0.7 0.7 1.2 0.2 0.5 0.5 1.0 
26 4.0 5.9 5.5 0.6 3.4 5.3 4.9 
27 10.4 22.2 18.4 7.0 3.4 15.2 11.4 
28 12.7 18.0 18.8 5.8 6.9 12.2 13.0 
29 9.7 11.2 14.2 5.0 4.7 6.2 9.2 
30 3.9 1.6 8.5 0.8 3.1 0.8 7.7 
31 6.5 6.1 8.4 1.0 5.5 5.1 7.4 

Average 
(L/m2/d) 

5.9 
 

7.2 
 

5.4 
 

1.44 
 

4.5 
 

5.7 
 

4.9 
 

Total 
(L/m2) 112.0 136.5 103.3 27.4 84.6 109.1 78.1 

Table 3.  Total water collected and net fog water collected by the three trees during August 2006

Date 
Total fog and rainwater 
collected (L/m2/d) 

Net fog water collected 
(L/m2/d) 

 Fig Lemon Tamarind 

Rainwater 
collected 
(L/m2/d) 

Fig Lemon Tamarind 
1.0 2.5 3.3 5.4 0.4 2.1 2.9 5.0 
2.0 3.5 6.2 5.5 0.2 3.3 6.0 5.3 
3.0 1.0 1.5 1.1 0.3 0.7 1.2 0.8 
Average 
(L/m2/d) 2.3 3.7 4.0 0.3 2.0 3.4 3.7 
Total (L/m2) 7.0   11.0       12.0 0.9 6.1   10.1       11.1 

Table 4.  Total water collected and net fog water collected by the three trees during September 2006



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lection by the lemon tree was as high as 19.5 L/m2/d (7
August 2006).

The average fog water collected by fig, lemon, and
tamarind trees during July was 4.5, 5.7, and 4.9 L/m2/d,
respectively (Fig. 3a).  The average fog collection pro-
duced by tamarind tree on August was 4.9 L/m2/d, where-
as the fig and lemon trees produced a yield of 4.5 and 5.7
L/m2/d, respectively (Fig. 3b).  As shown in Fig. 4a, the
total fog water collected in July by fig, lemon, and
tamarind trees in the same order was  84.6, 109.1 and 78.1
L/m2.  The total fog collected by these trees during August
in the same order was 49.8, 123.8, and 129.7 L/m2  (Fig.
4b).

Over a period of 47 days in the monsoon period, the
tamarind tree collected 218.9 L/m2 of fog water, whereas
the fig and lemon tress collected 140.5 L/m2 and 243 L/m2,

respectively.

4.  Discussion and Conclusion

The main aim of this study was to assess the water col-
lection potential of trees and to investigate the fog water
potential of the selected area in the mountains of the
Dhofar Region in the Sultanate of Oman.  The water col-
lection efficiency of three different trees was analyzed
during the period from 13th July to 3rd September 2006
(ie. 47 days).  The experiments were conducted to study
the possibilities of harvesting the water of the monsoon
fog by different trees for possible use as a supplement to
the water sources of the mountains of  Dhofar Region.
The trees included in the study were fig, lemon and
tamarind trees.  

Figure 2a.  Amount of fog water collected daily by the three trees during July 2006

Figure 2b.  Amount of fog water collected daily by the three trees during august 2006



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Figure 3a.  Average fog water collected by the three trees during July 2006

A
ve

ra
ge

 o
f 

fo
g 

w
at

er
 c

ol
le

ct
ed

 (
L

/m
2 /

d)

Fig                             Lemon                         Tamarinds

0 
   

   
 1

   
   

  2
   

   
 3

   
   

  4
   

   
  5

   
   

 6

Fig                               Lemon                        TamarindsA
ve

ra
ge

 o
f 

fo
g 

w
at

er
 c

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ct
ed

 (
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2 /

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 1

   
   

  2
   

   
  3

   
   

 4
   

   
  5

   
   

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Figure 3b.  Average fog water collected by the three trees during August 2006

Fig                              Lemon                        Tamarinds

To
ta

l a
m

ou
nt

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f 

fo
g 

w
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58

The Journal of Engineering Research  Vol. 6, No.1, (2009)  51-58

The comparisons of the water collection from the three
different tress showed that large differences in collection
existed as a function of the size of the leaves of the trees
and the cross sectional area of their canopies.   It was
found that the fig tree collected the lowest amount of
water. The results indicated that the total water collected
during the experimental period of 47 days by the lemon
tree was higher (311.1 L/m2) than the amount of water col-
lected by tamarind (284.8 L/m2) and fig trees (208.6 L/m2)
over the same period.  

The findings showed that the fog and rain water col-
lected by the trees during the monsoon season provided
significant amounts of water.  The study also demonstrat-
ed that trees could collect amounts of water which evi-
dently far exceed their consumption during the monsoon.
The water collected can be used to supplement or replace
the groundwater.  The study confirmed that trees play an
important role in the recharge of water to soil and ground-
water.

It can be concluded from this study that trees have the
potential to harvest water from fog.  There is no doubt that
tree planting is important for water conservation in the
Dhofar region.  More researches are required to identify
areas where largest collection will take place and where
tree planting will have the largest effect on the water
resources.  Therefore, more research is required to deter-
mine the optimal locations for a forestation in the Dhofar
region.

Acknowledgments

The funding provided by Sultan Qaboos University
(Project IG/ENG/MIED/05/02) is gratefully acknowl-
edged. 

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