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RESPONSES TO WATER SCARCITY: SOCIALADAPTIVE CAPACITY AND THE ROLE OF
ENVIRONMENTAL INFORMATION.A CASE STUDY FROM TAÕIZ, YEMEN.
by:
Yasir Mohieldeen
ym5@soas.ac.uk
Occasional Paper No. 23
Water Issues Study GroupSchool of Oriental and African Studies (SOAS)
September 1999
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ABSTRACT
The main purpose of this study is to demonstrate the importance of thesocial aspects (dynamics) of water in the highly political process of waterpolicy formulation and implementation. A second purpose is to illustratethe potential usefulness of one type of data in the enhancement of themutual adaptive capacity of governments and local communities indeveloping safe and sustainable water allocation and management practices.The type of data used were derived from remotely sensed imagery and havebeen integrated into geographical information systems. The data enabledrural water use to be detected in the 1980s and in the 1990s.
The social dynamics of water scarcity are exceptionally complex. Societieshave different abilities to cope with water deficits, which are referred to inthe study as 'first order scarcity'. Ohlsson (1999) calls the ability to copewith water deficits the 'adaptive capacity' of a society. Lack of 'adaptivecapacity' can be considered as a 'second order scarcity'. A recentlydeveloped framework by Turton (1999a) emphasises that it is the 'adaptivecapacity' of the society that determines its water development trajectory.
The experience of competing water users in the Ta'iz region of Yemen in the1960-1996 period provides empirical evidence on a number of technical,informational and social factors which contributed to the 'closure' of agroundwater resource. The hydropolitical circumstances were conflictualand, as a result, the resource managing strategies of both the localcommunities, that is the irrigators, and of the government providing waterfor the city, failed. Special attention is given to the way that the domesticand drinking water crisis in Ta'iz has been addressed after the failure of thegovernment installed public system. The local community has adapted bydeveloping an unregulated private market operated by well-owners andwater-browser operators. The system meets current needs although it isnot founded on sound water resource information and therefore may not besustainable.
The crisis in the TaÕiz area represents a case of total water managementfailure. The failure occurred because of the absence of feedback and supportprocesses between the government and the local societies throughout theimplementation of all water strategies adopted by the government.
Keywords: Water demand management, water scarcity, adaptive capacity,
feedback and support, remote sensing and GIS, information dissemination.
3
ACKNOWLEDGEMENT
I would like to acknowledge my supervisor, Professor Tony Allan for his enormous and
invaluable assistance and support during the entire study. I am indebted to Mr. Chris
Handley of the SOAS Department of Geography, for his generous assistance, and
provision of valuable information as an expert who worked in the study area. I would
also like to thank Mr. Tony Turton for his valuable conversations, and Mr. Gerhard
Lichtenth�ler, of the SOAS Geography Department, for his continuos support and
guidance during the study.
Thanks must also be given to the many that offered to proof read this work and, of
course, many thanks to those who carried out such an arduous task.
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CHAPTER I. INTRODUCTION AND OBJECTIVE OF THE STUDY.
ÔWe made from water every living thing.Õ (Holy QurÕan, 21:30).
1.1 Introduction:
ÒWe ask you É your opinion of artesian wells. You think they are unimportant. All
right, the hell with you. WeÕll ask somebody else who will give us the answer we
want. Nothing personal.Ó
(Reisner, 1993; cited in Turton, 1999a)
The above quote is what Senator Moody of South Dakota said when he heard John
Wesley PowellÕs report on the proposed use of artesian wells in the Dakotas, in the
1870s. One century later, in 1976, Leggette et al., were commissioned by the Yemeni
National Water and Sanitation Authority (NWSA) to carry out hydrological studies in
Wadi Al Hayma, 12 km north of the city of TaÕiz, Yemen. The objective was to assess
the groundwater aquifer in Wadi Al Hayma, and to estimate the amount of water that
could be siphoned through a pipeline from Al Hayma to the city of TaÕiz which faced
water shortage.
In their report, Leggette et al., (1977) estimated a quantity of 10 Mm3/yr to be
transported to the city of which 8 Mm3/yr is from Al Hayma and Miqbaba, an
Ôeffective end to irrigated farmingÕ in the area, as a Ôreasonable objectiveÕ for sustainable
abstraction for the city.
5
In 1982/83, the NWSA started the commissioning of wells. Some locals thought that the
NWSA would drill only seven deeper wells in the area, yet now there are more than
thirty (Word & Moench, unpub, cited in Handley, 1999). The shaikh1 of Lower Wadi
Al Hayma, the late shaikh Sadiq, who agreed to the drilling, managed to get three deeper
drilled wells for himself out of the deal (Handley, 1999). The farmers had been informed
that pumping water from the deeper wells drilled by the NWSA, its transporting to the
city through the pipe line, would not effect their shallow wells or their farms, since there
is an aquiclude between their wells and the NWSAÕs wells. The NWSA promised
$10M2 compensation for loss of crops (Handley, 1999). However, Why the
government should offer such a huge amount of money beforehand and before anything
had occurred, is not clear.
In 1986, after four years of abstraction for the city, and by local farmers in Wadi Al
Hayma, the farmersÕ shallow dug wells dried up. The lower part of the wadi was left
barren, apart from a few fields including shaikh SadiqÕs successorsÕ fields which were
irrigated from his deeper drilled wells. To date nothing has been received from the
promised $10M government compensation.
In 1987, and as part of an emergency drilling campaign to rescue the city, the NWSA
started drilling new wells in the Lower Wadi Al Hayma, four times deeper than the ones
they had drilled in 1982. The locals in Wadi Al Hayma prevented the drilling in the area
by force. The army interfered and took school children hostages in the school for one
day, and five shaikhs were detained by the Yemeni security services for five days in
TaÕiz, while local men went into the mountains with their weapons. The shaikhs were
1 The head man of the tribe
6
released after they had signed an agreement not to stop the drilling; their sons guarded
the drilling team.
During 1996-99, a hydrological study was completed by Chris Handley of the SOAS
Geography Department, University of London, as part of his PhD degree. By using
remotely sensed data, processed in SOAS, GIS work carried out by the author, and
HandleyÕs results proved that Legette et al., got it wrong. The amount of water that
they considered as a safe yield for siphoning to the city was unrealistic. HandleyÕs
results suggest that to achieve Legette et alÕs Ôreasonable objectiveÕ of complete demise
of irrigated agriculture, only 4.8 Mm3/yr rather than 8 Mm3/yr, would be the sustainable
abstraction to the city (Handley, 1999). However, LeggetteÕs report (1976) has
provided the ÔanswerÕ the government wanted.
This thesis will try to record and analyse water development in Wadi Al Hayma over
the past two decades, through a recently developed social framework/model which
emphasises the importance of linking the technical and social aspect of water demand
management together. The purpose will be to show that social integrity, government
legitimacy, accurate information about water resources, sharing of information and
participation of local societies in decision making are the basis of effective water
strategies that lead to water Ôresources reconstructionÕ.
1.2 Water Crisis and the National Extent:
Water is a natural resource of vital importance; no life is possible without water. In arid
regions water brings livelihoods and security. These circumstances politicise water
2 10M was really a lot of money in Yemen in the 1970s. Still it is a lot.of money.
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supply and demands and can make managing water resources a very hot issue. They
cause different social sectors in a society act according to water resource availability, and
adapt to its scarcity. However, information on water resources in developing countries
is blatantly lacking. The need for accurate information and data about water resources
and about the pattern of its use and, how this pattern changes, is of vital importance to
any water strategy formulation. The Middle East region provides a number of good
examples of social entities facing severe water resource scarcity combined with severe
lack of data and information about their water resources. Among these societies, Yemen
stands out very distinctly.
Yemen is one of the oldest irrigation civilizations in the world. When dam irrigation,
rainwater harvesting techniques, and water management methods were developed there,
Rome was still marsh and America was a trackless waste (The World Bank report, 1997:
i). Ibn Khaldun3, in his book ÔMuqaddimahÕ, attributed the development of the Middle
East at that time, and the underdevelopment of Europe in general, to the cold
environment in Europe, and so can be said to have adopted an environmental
determinism approach. In recent times, Yemen has experienced an extreme water crisis,
characterised by severe water shortages in the major cities, very limited access of the
population to safe drinking water and rapid depletion of groundwater aquifers. The
annual replenished renewable water supply is around 2.1 Ð 2.5 billion cubic metres/yr
(Abdo, 1997). Which renders an average of 130 cubic metres per person/yr. To get a
sense of the significance of this number, one has to remember that the average supply in
3 Arabian scholar (1332 - 1395 C.E) He is considered universally as the founder and father of Sociology.
8
the world is 7,500 cubic metres per person/yr and, in the Middle East region it is 1,250
cubic metres per person/yr (Abdo, 1997).
The main causes of the water crisis are: the rising demand as population increases; the
rapid growth of market-led agriculture; the increasingly uncontrolled exploitation of
groundwater; and the implementation of frameworks which has promoted expansion
rather than efficient use and sustainable management of water resources (World Bank
report, 1997). Yemen represents an extreme case of water shortage. The country stands
out among countries in water crisis (The World Bank report, 1997). Firstly, because of
the size of the problem: the rate of exhaustion of the aquifers is the fastest in the world,
and in no other country in the world will the capital of the nation and the major cities
run out of water in a decade. Secondly, Yemen stands out because of the lack of
governance and social-structures that allow anything approaching a real solution to be
imposed. In other words, the country lacks the Ôsocial capacityÕ to make the relevant
adjustments needed to cope with increased water scarcity.
Different authors and social scientists variously explain the lack of social and governance
structures. Some attribute it to the difficult mountainous topography of the country,
which led to internal isolation of the tribal societies from one another, and isolation from
outside Yemen. Others, such as Schoch (1982), attribute the lack of social and
governance structures to the long isolation of Yemen from Middle East countries and the
rest of the World. Not until after the Civil War, lasting from 1962 to 1969, did Yemen
open up to regional and international influence. This long-lasting isolation has led the
country, on the one hand, to preserve many traditions and practices unique to Yemen.
9
On the other hand, this isolation had some other implications such as: rudimentary
infrastructure (transport, communication, Éetc.), lack of industry and the domination of
old-fashion agriculture, and lack of well-trained experts in any economic or
administrative sector. In addition, there has been severe lack of quantitative and
qualitative information on natural resources and population, and socio-economic
structures (Schoch, 1982).
The severe lack of information about natural resources in Yemen, especially water,
prevents proper planning and development. Therefore, there exists an urgent need for
fast accurate data showing past and present natural resource conditions (status) to help
manage and utilize these valuable natural assets in a sustainable way, so that future
generations can meet their own needs without stress. Turton (1999a) suggests, at
present, water sector reform is widespread within the developing world, indicating that
the existing water policies are inadequate. Therefore, more and more data and
information on water resources are going to be in high demand in order to formulate
efficient water strategies that lead to its sustainable use, and water Ôresource
reconstructionÕ in the cases of the water resource depletion. (Allan & Karshenas, 1996a)
Different water resource management strategies are adopted by different countries with
different degrees of success. Water resource management strategies can be categorised
into two main categories: Water Demand Management (WDM), and Water Supply
Management (WSM) (Merret, 1997; Merret, 1998). WDM is a policy that stresses
making better use of existing supplies, rather than developing new ones (Winpenny,
1997; Lichtenth�ler & Turton, 1999). WDM is becoming more and more an essential
strategy and alternative to supply management strategy.
10
Allan and Karshenas (1996a) regard WDM as becoming an alternative when societies
have developed their political economies to a degree that new alternatives are
economically, politically and socially bearable. Another situation where WDM becomes
a must is when there is a severe water scarcity. Therefore, WDM strategies are likely to
become increasingly important as adaptive mechanisms to water scarcity and for
sustainable use of water in/for the future (Turton, 1999a). This is basically because
most of these water policies and strategies are based on wrong assumptions centred
around the idea that there is always unlimited water supply and, that water is a free
good.
Different social entities have different abilities to adapt and make the necessary
adjustments in the face of natural resource scarcity. Ohlsson (1999) describes this
ability as the Ôadaptive capacityÕ of the society. The Ôadaptive capacityÕ of a society
can be regarded as a valuable Ôsocial resourceÕ or Ôsocial capitalÕ. This Ôsocial capitalÕ
can be mobilised to make the required adjustments to water scarcity. If sufficient Ôsocial
resourceÕ is mobilised, it can even lead to what Karshenas (1996) describes as Ônatural
resource reconstructionÕ. This can only happen through the implementation of efficient
water strategies, for example, water demand management WDM.
Recent work by Turton (1999a), using these concepts, resulted in the development of a
model linking Ônatural resource reconstructionÕ to the Ôadaptive capacityÕ of a social
entity through Ôwater demand managementÕ. The model is illustrated schematically in
Figure (1). The model resembles the construction of a monument, the foundation of
which is Ôadaptive capacityÕ. The superstructure consists of WDM strategies, and the
apex is Ônatural resource reconstructionÕ. The two components of adaptive capacity Ð
the structural and social components - are presented in the model as the pillars that take
11
the weight of the superstructure (WDM). The right-hand pillar represents the social
component of the Ôadaptive capacityÕ. The Ôsocial componentÕ is the willingness and
ability of the people to accept the WDM. It is endogenous perceptions of water,
normally derived from existing belief systems. It is what is in the Ôhearts and mindsÕ of
the people.
The left-hand pillar represents the structural component of Ôadaptive capacityÕ. The
Ôstructural componentÕ is the institutional, intellectual and technical abilities that make
the society able to find alternative technical solutions to water scarcity. Only through
this part of the model external role-players such as development agencies and NGOs can
play an active role in creating the capacity building needed. They can advise on
institutional arrangements, IT systems, information generation and analysis, data flow
and availability, and training of skilled personnel (Turton, 1999a:26).
Water Demand Management
Feedback
NaturalResource Reconstruction
Gen
erat
ion
ofal
tern
ativ
eso
luti
ons
byte
chno
crat
icel
ites
Will
ingn
ess
and
abili
ty o
f th
eso
cial
ent
ity to
acc
ept t
hese
tech
nocr
atic
sol
utio
ns a
s be
ing
both
rea
sona
ble
and
legi
timat
e.
ÔAdaptive CapacityÕor
Stock of ÔSocial ResourcesÕ available
Institutionalcapacity
Intellectualcapital
SocialComponent
Largelyendogenous,
existing in theÒhearts and
mindsÓ of thegoverned and
cannot beartificially
created.
StructuralComponent
Partiallyexogenous andcan be assisted
by foreigntechnical and
financialsupport in form
of ÔcapacitybuildingÕ.
Support
Figure 1. TurtonÕs model linking Ônatural resource reconstructionÕ via Ôwaterdemand managementÕ to the Ôadaptive capacityÕ of a social entity.
12
1.3 The Objectives of the Study:
The model, in Figure 1, provided by Turton (1999a), demonstrates that a high level of
Ôadaptive capacityÕ is needed for effective formulation and implementation of WDM.
The model identifies two components of the adaptive capacity these are, the Ôstructural
componentÕ and the Ôsocial componentÕ. For any WDM strategy to be effective, and to
have an impact on water resource reconstruction, both the ÔsocialÕ and the ÔstructuralÕ
components (the two pillars) of the adaptive capacity should be equally considered by
policy makers. However, the social dynamic aspects of WDM, represented by the
social component of Ôadaptive capacityÕ, the right pillar in the model, is often neglected.
Furthermore, Evans (1997: 53) explicitly states that Òbefore a national water policy can
be prepared, the future water availability and the future demands need to be determined
with a reasonable degree of accuracyÓ. However, Evans notes that within developing
countries water-related decision-support structures are very poor, and Òdata collection
has been abandoned for yearsÓ. Therefore, for WDM formulation, accurate information
about past and current water resource use, demand, patterns is needed to predict future
demand. This addresses the Ôstructural componentÕ of Ôadaptive capacityÕ, the left
pillar in the model.
The objective of the study is to look at two main factors that are vital to the
effectiveness of WDM strategies, these are: the Ôsocial componentÕ of Ôadaptive
capacityÕ; and the information on which WDM strategies are based. The second factor
is an essential to the decision-support structures, which is a major part of the structural
component of the Ôadaptive capacityÕ. The thesis will try to highlight and stress:
13
• the importance of the social aspects of water in the formulation of WDM strategies.
WDM strategies developed by technocratic elites, to manage increasing levels of
water resource scarcity, have serious knock-on effects on social entities that can lead
to high levels of social instability. These effects can result in the failure of WDM
strategies. In other words, WDM strategies cannot be effective if the social
component of the Ôadaptive capacityÕ (the right hand pillar in the model, Figure 1) is
missing or ignored.
• the importance of accurate information for the water-related decision-support
structure, that flows into and is essential to the different aspects of the Ôstructural
componentÕ of Ôadaptive capacityÕ, the left-hand pillar in the model.
Accordingly, the thesis will look at how different Ôsocial entitiesÕ in the study area
adjust to and/or cope with water scarcity. Secondly, to address the latter point, the
thesis will examine how modern techniques, such as EO and GIS, can be used to provide
information about water use patterns to help build decision-support structures,
especially in developing countries where such structures hardly exist.
The study area is defined and described in chapter two. Chapter three discusses the
social frame-work used for the analysis in this study. Chapter four will look at some
technical aspects of remote sensing and GIS and will discuss their potentials in
providing data about water resources. Chapter five will look at how various social
entities (stakeholders) in Wadi Al Hayma adapt to water scarcity. Chapter six is a
concluding chapter.
14
1.4 The Problem:
Water scarcity is prominent all over Yemen. Depending on the water use pattern and
the socio-economic condition - whether rural or urban - the problem is perceived
differently in various parts of the country. The TaÕiz area, in the southern highland of
Yemen (see Figure 2.), represents a situation where urban and rural water problems are
mixed, and conflict with each other creating an extreme case of water management
problem in the whole of the Middle East. Water crisis in the TaÕiz area represents a
case of total water management failure (Handley, 1999).
There are two major groups of water use in the TaÕiz area. Rural water use, which is
irrigated agriculture, and urban water use, which is basically for industrial and domestic
use by the increasing industry and population of the city of TaÕiz.
Using LegetteÕs et al., (1977) incorrect estimates, the government implemented a re-
allocative water strategy that has had a detrimental effect on the whole area. To increase
the Ôreturn to waterÕ, the government allocated the water from the agricultural sector in
the rural areas to the industrial sector and, the urban population in the city of TaÕiz Ð i.e
the government has adopted Ôallocative efficiencyÕ strategy (Allan, 1998). However, the
water shortage/crisis in the area has affected both the inhabitants of rural areas as well as
the people and the industrial sector of the city.
In the urban area, the people of TaÕiz receive water from the public water supply only
once every 15 to 40 days. The water delivery crisis in the city reached a peak during the
15
summer of 1995 (Handley & Dottridge, 1997). The scene of women and children
collecting water from standpipes has become a normality, and water fetching has become
part of the daily life for most families in the city. In the rural area of Wadi Al Hayma,
from where the water has been siphoned through the pipeline, the exploitation of the
groundwater aquifer for both agriculture and for the city has resulted in the depletion of
the aquifer and the drying-up of local farmersÕ wells. From the above, the problem of
the water crisis in the TaÕiz area can be addressed in the following contexts:
• Rural-urban distinction in the water resource use, with the rural area being ReesÕs
Ôecological footprintÕ for the urban area (Rees, 1996).
• The environmental impacts/damages on the rural area resulting from this distinction.
These are:
- The depletion of the groundwater aquifer due to water over-abstraction to the
city supply and for agriculture.
- The pollution of surface and ground water by the industrial and urban
development of the area.
The analysis of the status of the groundwater resource use pattern of Wadi Al Hayma
will be the focus of this study and, will be examined as a case study of water
management in the wider TaÕiz area. This is because the depletion of water in this
particular valley has had the biggest knock-on effect on the water supply in the area and
its water resource management of the region.
16
CHAPTER II. THE STUDY AREA.
2.1 Location, Demography and Social-economy:
Figure (2) shows the location of the TaÕiz area which comprises the upper catchment
area, upstream, of Wadi Rasyan. Wadi Rasyan is one of the seven major wadis that
form the Red Sea drainage basin, and drain the high and midland region of the Yemen to
the west into the Red Sea. The area of the upper and middle catchment of Wadi Rasyan
is about 1,990 km2 (Gun and Ahmed, 1995). The TaÕiz study area extents from the
point 378 E UTM and 1510 N UTM. It covers approximately 929 km2. Wadi Al
Hayma constitutes the upper eastern part of Wadi Rasyan.
Demographically, the population of the TaÕiz area is among the largest in the country.
Because of inaccuracies and unavailable data on population, and missing settlement
names in the only available 1:50,000 topographic map (published in 1981 from aerial
photographs taken in 1973 by DOS4), the population of the study area was estimated
using the 1994 census data (Dar El Yemen report, 1997). In 1994, the population of the
study area according to the census was 605,000. Given that the annual population
growth of Yemen is 3.6%, the current population of the area, in 1999, is about 698,000
of which 400,000 live in the main urban centre in the area Ð the city of TaÕiz. The city
of TaÕiz represents the main demographic feature in the area.
4 Directorate of Overseas Surveys (U.K.).
17
Socio-economically, the study area is dominated by the city of TaÕiz, and the rural parts
around the city serve as the cityÕs hinterland.
18
Figure 2. The Location of the study area.
19
The city suburbs accommodate most of the largest industrial plants that provide
employment for local people. Most of the working male population of the countryside
work in the city and return to their villages daily or weekly. The agricultural products
from the rural area are brought to the market in TaÕiz city. A considerable proportion of
the exploited water resources of the area is used for domestic and industrial needs of the
city (UN/DDSMS, 1997).
2.2 Geology, Physiography and Hydrogeology:
The TaÕiz area is located within a low plateau the Southern Highlands of Yemen
(Dresch, 1989). The plateau lies in an east-west faulted graben 25km wide (Figure 3).
The graben descends from 1500m in the east to less than 900m in the west in a series of
step-faulted blocks of stratified volcanics, which dip to the east or north east. The
eastern edge of the area is occupied by a flat loess covered plateau, forming the surface
water divide between the Red Sea and the Indian Ocean (UN/DDSMS, 1997: 6; Handley
& Dottridge, 1997: 1). The volcanic rocks of the graben are comprise of fractured basic
and acidic lavas, and therefore have low water storage. This precludes the successful
development of wellfields in the volcanics.
The water supply of TaÕiz is derived from the alluvial deposits in the graben. The first
wellfields to be developed in the alluvium, Hawban and Al Hawgala, were located
downstream of the city. Because of the sewage disposals of the increasing population
of the city, the water quality has drastically deteriorated. Another alluvial aquifer in the
area is in Wadi Al Hayma, which lies in the northern edge of the graben. The most
20
promising future water resource in the area is the Tawilah Sandstone. It outcrops to the
north of the graben, and is thought to be present throughout the graben beneath the
volcanic sequence (Figure 3b) (Handley & Dottridge, 1997).
Graben
Figure a.
Figure b.
Horst
TaÕizWell
GrabenHorst
TaÕiz
Horst
Horst
Al Hayma
NORTH
Tawilah Sandstone
Wadi (ephemeral)
Alluvium deposits
Figure 3. Geology and Physiography of the TaÕiz area. North-south cross sectionof the area (b).
Alluvium
Tawilah Sandstone
Volcanic
NO
RT
H
Wadi (6-10month flow)
21
CHAPTER III. SOCIAL DYNAMICS OF NATURAL RESOURCE SCARCITY.
HeracleitusÕ famous statement ÔAll is flux, nothing is stationary5Õ proves to be valid in
different fields of study, including social science, and the way that societies cope with
natural resource scarcity in general. Societies are continually trying to adapt and react to
natural resource scarcity.
It is well known that there is an increase in water scarcity in general at the global level
(Falkenmark, 1989), and that this is affecting the developing world. Turton (1999b)
argues that this increased water scarcity will impact in some form or other on social
stability within these developing states, but it is not known exactly where or how this
will manifest itself. In order to survive, societies have to adapt and adopt different
mechanisms to adjust the resource scarcity. Turton (1999a) emphasises that the need to
understand the social dynamics of water scarcity, and how various societies cope with
this scarcity, is critical. He goes further and, states that a deeper knowledge of these
social dynamics of water resource scarcity is of strategic significance to governments
(ibid, 1999a).
3.1 Environmental Capital and Growth:
The relationship between economic development and environmental capital has been the
concern of development studies. Since the early 1970s, at least, there has been a
growing concern about the impact of economic growth on the natural environment. Two
5 Quoted recently in Sulivan (1999:1)
22
main arguments/views have evolved: that Ôgrowth is badÕ for the environment; and
Ògrowth is goodÓ for the environment (Barrett, 1996).
The Ògrowth is badÓ view was propounded in the Club of Rome report, The Limits to
Growth (Meadows et al., 1972). The Club of Rome predicted that if the world
continued to develop, and use its environmental capital at the same rate as it had in the
past, pollution and natural resource degradation would increase exponentially until the
limit to growth is reached, with the result being a total collapse. To avoid Doomsday,
the Club of Rome argues economic growth should be carefully monitored and even
constrained. This argument is based on the well known Malthusian population theory.
The view emphasises that developing states and societies use, and sometimes abuse,
natural resources in their trajectory to develop.
The Ògrowth is goodÓ view maintains that a high standard of living will provide the
resources needed to stop and, even reverse, environmental harm (natural resource
reconstruction). Furthermore, growth provides reasonable and clean technologies that
reduce environmental damages. It also fuels the social institutions needed to create such
technologies, thereby leading to effective environmental improvements. Recent research
has demonstrated that some forms of environmental degradation initially rise, but
eventually decline with increase of per capita income (ibid, 1996). The World Bank
(1992) cited that growth need not lead to natural resource degradation. These two
conflicting views are combined and clearly delineated in the environmental KuznetÕs
inverted U curve in Figure (4) below.
23
In Figure (4) to the left of the peak, and at a relatively low income level, relatively low
value is placed on natural resources and a clean environment compared with the value of
a higher standard of living. At this low income level, increases in economic growth result
in increased natural resource degradation and abuse. However, after a threshold level of
income per person is reached, natural resource degradation effects will be reduced
(Barrett, 1996; Cypher et al., 1997).
3.2. The Concept of Social Adaptive Capacity: stating the obvious
ÔVerily never will God change the condition of a people
until they change what is in themselvesÕ
(Holy QurÕan, 13:11)
Different social entities have different abilities to adapt to and to cope with natural
resource scarcity. This explains why, although facing almost the same resource scarcity,
The peak
Economic development (growth)
Nat
ura
l re
sou
rce
deg
rad
atio
n
Figure 4. Environmental KuznetÕs Curve, showing the relationship betweeneconomic development and natural resource degradation.
24
different social entities are on different development trajectories. Social entities that lack
the ability to make the necessary adjustments to cope with natural resource scarcity, can
be regarded as lacking a very valuable social resource. Ohlsson (1999) calls this social
resource the Ôadaptive capacityÕ of a society. Therefore, if the existence of a natural
resource scarcity, such as water, is regarded as being a Ôfirst-order scarcityÕ, lack of
Ôadaptive capacityÕ can be regarded as a Ôsecond-order scarcityÕ (Ohlsson, 1999; Turton,
1999a). The ability of a social entity to find the social tools with which it can deal with
the consequences of the Ôfirst-order scarcityÕ is just as significant as the water resource
deficit (Turton, 1999a:8). Some societies can be in short supply and have Ôsocial
resource scarcityÕ. ÔSocial resource scarcityÕ, in turn, can lead to Ôsocial stressÕ that is
usually incorrectly attributed to, by the prevailing discourses, the Ôfirst-order scarcityÕ
(Turton, 1999a).
The Ôadaptive capacityÕ of a social entity can, therefore, be defined as the ability of that
particular society, firstly, to develop alternative options to cope with natural resource
scarcity, and secondly, to accept these alternatives as being legitimate (ibid, 1999a).
ÔAdaptive capacityÕ contains two unique elements:
• The structural element which is the institutional, intellectual and technical capacity
that is involved in water strategies formulation.
• The social element, containing perceptions which have derived from belief systems.
It is what is in the ÔheartsÕ and ÔmindsÕ of the people and, it is not easy to change
Ôunless people change what is in themselvesÕ.
25
3.3 ÔAdaptive capacityÕ, ÔCoping strategiesÕ and ÔViolent conflictsÕ:
The relationship between Ônatural resource scarcityÕ and the Ôadaptive capacityÕ of a
social entity has already been demonstrated. It was shown that social entities with a
high level of Ôadaptive capacityÕ has the ability to generate more Ôcoping strategiesÕ or
Ôcoping optionsÕ than social entities with a limited source of Ôadaptive capacityÕ, as
depicted in Figure 5(a). ÔCoping strategiesÕ can be therefore defined as the Ôelements of
adaptive capacityÕ. They are responses to stimuli. This would suggest that in the face
of increasing Ôresource scarcityÕ the number of available options or Ôcoping strategiesÕ is
decreasing6. The relationship between the Ônatural resource scarcityÕ and the Ôrange of
coping strategiesÕ is depicted in Figure 5(b).
With increasing resource scarcity, the number of available Ôcoping optionsÕ minimizes.
This may lead to eruption of Ôviolent conflictsÕ. In the context of water as an element of
6 Personal conversation with Turton 1999
Figure b.
Natural Resource
Cop
ing
stra
tegi
es(R
ange
of
copi
ng o
ptio
ns)
Cop
ing
stra
tegi
es(R
ange
of
copi
ng o
ptio
ns)
Adaptive Capacity
Figure a.
Figure 5. The relationship between the Ôadaptive capacityÕ and Ôthe range ofcoping strategiesÕ (a)., and between Ônatural resource scarcityÕ and Ôthe rangecoping strategiesÕ (b).
26
social stability, this leads to Ôwater induced conflictsÕ (Homer-Dixon, 1996). ÔWater
induced conflictsÕ can be between states (water wars) or can be internal conflicts.
ÔWater induced conflictsÕ are more likely to happen when there are less Ôcoping optionsÕ
available. While a concept like Ôvirtual waterÕ - water embedded in crops - provides
viable options that Ômiraculously and silently avoid the apparently inevitable
consequences of water deficitsÕ, for example, water induced conflicts (Allan, 1997a;
Allan, 1997b). The concept of Ôvirtual waterÕ can be regarded as an essential strategy to
increase the Ôcoping optionsÕ for social entities, especially states. Figure (6) below
demonstrates the relationship between Ôcoping strategiesÕ and the probability of
eruption of Ôviolent conflictÕ.
Moreover, Ôinternal water-induced conflictsÕ are highly linked to what is described as
Ôresource captureÕ. ÔResource captureÕ is the process by which powerful social groups
shift resource-distribution in their favour over time (Homer-Dixon & Percival, 1996,
Pos
sibi
lity
of
Vio
lent
con
flic
t
Coping strategies (Range of coping options)
Figure 6. The relationship between the range of Ôcoping strategies Õ availableand the probability of the eruption of Ôviolent conflictsÕ. The less the ÔcopingoptionsÕ available, the higher the possibility of Ôviolent conflictÕ eruption.
27
Turton, 1999b). Resource capture leads to ecological ÔmarginalizationÕ of some social
groups, and therefore results in conflicts. ÔResource captureÕ results from water
strategies that are ÔallocativeÕ in nature, and fuelled by resource scarcity.
28
CHAPTER IV. REMOTE SENSING AND GIS.
4.1 Introduction
This chapter will address the issue of information for water use and water policy
making. Yemen is an information scarce country. The purpose of this section will be to
show how remote sensing and GIS can provide information about water resources which
can be of vital importance to decision makers, and thereby, enhances the quality and the
makeup of the Ôstructural componentÕ of the social Ôadaptive capacityÕ.
In this study remote sensing and GIS are used to:
- Assess water resource conditions in rural area of TaÕiz.
- Detect the change of water use patterns by detecting the change in irrigation.
- Calculate the amount of water needed for cultivation.
- Estimate future use of water.
- Model groundwater aquifers and their recovery.
4.2 Remote Sensing & GIS: Basic Principles
Remote sensing is the science of acquiring, and measurement, of information on some
property/ies of a phenomenon, object, or material by a recording device not in physical,
intimate contact with the feature(s) under surveillance; techniques involve amassing
knowledge pertinent to environments by measuring force fields, electromagnetic
29
radiation, or acoustic energy employing cameras, lasers, radio frequency receivers, radar
systems, sonar, thermal devices, seismographs, magnetometers, gravimeters,
scintillometers, and other instruments (Lellisand & Keifer, 1994; Mather, 1993;
Aronoff, 1989; http://rst.gsfc.nasa.gov).
Different sensors are mounted on-board different satellites utilizing various parts of the
electromagnetic spectrum. For natural resource sensing at local scale, high spatial
resolution images are needed in order to be able to detect small features. Sensors such as
Thematic Mapper (TM), (28.5 by 28.5 meters), and Multi-Spectral Scanner (MSS) (80
by 80 meters) are commonly used. One of the main advantages of remote sensing is that
information about natural resources in inaccessible areas can be collected without much
effort. Also, information about critical natural resources in very politicised
environments, such as water in Yemen, can be collected without being in direct contact
with that environment and, hence reduce the risks.
Studies of natural resources need high spatial, temporal, and radiometric resolutions in
order to detect these resources. This results in massive data sets in image formats. In
order to process these data efficiently and to achieve accurate results, other data sets,
such as vector and descriptive data, need to be incorporated in the analysis. These facts
lead to the need for technical solutions (Allan, 1986). Such technical solutions can be
found in models provided by information systems such as Geographic Information
Systems (GIS). The GIS is a computer-based information system for the capture,
input, storage, analysis, modelling, manipulating, retrieval and presentation of spatial
information (Burrough, 1986; Green et al., 1993, Aronoff, 1989). Although remote
30
sensing and GIS technologies have developed separately, recently they have been more
and more integrated with each other. This is noticeable since a lot of GIS software can
incorporate raster images (Allan, 1998).
4.3 Data, Software and Equipment:
For the purpose of this study, satellite images acquired by the Thematic Mapper (TM)
sensor on board Landsat 4 & 5 were used. The spatial resolution of TM images is 28.5
meter by 28.5 meter. TM bands used in the study are shown in Table (1) below.
Band No. Band Name Band Width
(µm)
Characteristics
1 Blue 0.45-0.52 Good water penetration, strong
vegetation absorbency.
2 Green 0.52-0.60 Strong vegetation reflectance.
3 Red 0.63-0.69 Very strong vegetation detection (since it
is highly absorbed by vegetation).
4 Near-Infrared 0.76-0.90 High land/water contrast, very strong
vegetation reflectance.
5 Mid-infrared 1.55-1.75 Very moisture sensitive.
6 Mid-infrared 2.08-2.35 Good geological discrimination.
Table 1. TM Bands used in the analysis and their characteristics.Source: (Lillesand & Kiefer, 1994).
The data used in this study were used in a study carried out by Dar Al Yemen
Hydroconsultants in 1996 and funded by the UNDP. The main objective of Dar Al
Yemen study was to provide information about water resources in the area. The
31
processing of the remotely sensed imagery was carried out by the SOAS Department of
Geography, University of London.
The software used for the analysis are: Arc/Info for Unix, Arc/Info for NT, and Erdas
Imagine 8.3.1 for the main analysis. Arc View 3.1 and Surfer version 6 were used for
presentation.
4.4 Surface Analysis:
A Digital Elevation Model (DEM) is an ordered array of numbers that represents the
spatial distribution of elevations above some arbitrary datum in the landscape
(Burrough, 1986). Figure (7) represents a DEM for the study area created from contour
lines digitized from a topographic map. First a Triangular Irregular Network (TIN) was
created from the contour lines. The TIN divides the surface into small adjacent non-
overlapping triangular planes that capture the terrain characteristics. A DEM was
derived from the TIN. Different types of hydrological information were derived from
the DEM, these are: slopes, aspect, drainage network, and watersheds. Aspect is the
down-slope direction from each cell to its neighbour. Furthermore, the DEM was used
to eliminate the topographic effect in the TM images. The topographic effect is the
difference in illumination due solely to the slope and aspect of terrain relative to the
elevation and azimuth of the sun. The net result is an image with more evenly
illuminated terrain (Erdas Imagine on-line help, 1997). Figure (7) below shows different
derivatives that were created from the DEM.
Also, the DEM was used for visualisation purposes by creating a three-dimensional
perspective view to help understand the nature of the topography of the area, the flow
32
directions of the wadis, and the pattern of irrigation. Figure (8) is a three dimensional
representation of the study area.
33
Figure 7. The DEM creation, and the different hydrological and topographical informationthat was derived from it.
DEM
Shaded ReliefDrainage Network
Watershed Slope TopographicallyCorrected Image
Contours TIN Aspect
34
Figur (8) Digital Elevation Model, Wadi Al Hayma
A 3-Dimensional View from the Southwest Corner of the study area, Wadi Al Hayma.
Metre
35
4.5. Method of Approach:
4.5.1 False Colour Composite:
In order to detect the change in irrigation, and hence water use pattern, two sets of T M
images, acquired in dry winter season (23rd January 1986 and 13th January 1995)., were
used It is assumed that during the dry winter season, all green cover in the wadis is
irrigated cropping. The presence of vegetation in winter is used as an indicator of
irrigation.
For visualisation purposes and to give a sense of the pattern of change in irrigation, false
colour composite images were created and viewed for 1986 and 1995 (Figure 9). Band 2
(green band), band 3 (red band) and band 4 (Near Infrared (NIR)) were respectively
assigned the blue, green and red colour guns of the display monitor.
Because near infrared (band 4) is highly reflected by vegetation and the red (band 3) is
highly absorbed by vegetation for photosynthesis process, vegetation appears red in
this false colour composite images (Lillesand & Kiefer, 1994). False Colour Composite
technique is a means to utilize the reflective characteristics of three bands and analyse
the information for the three of them simultaneously. Vegetated areas are more
Figure 9. False Colour Composite 1986 & 1995. Red : NIR. Green : Red band. Blue: Green band.
36
detectable in the False Colour Composites than looking at each single band individually.
Figure (10) shows the False Colour Composite Images (with NIR assigned to grren
colour) draped on the DEM.
Figure 10. False colour composite images for 1986 & 95 draped on theDEM.
False ColourComposite:
RED: Red band.GREEN: NIR band.BLUE: Green band.
N
1986 1995
37
4.5.2 Normalized Difference Vegetation Index (NDVI):
The NDVI is designed to detect vegetation, and simultaneously minimizes the effects of
soil background brightness and atmospheric ÔnoiseÕ. It has the ability to eliminate
topographic effects and variations in the sun illumination angle and other atmospheric
elements such as haze (Lillesand & Kiefer, 1994; Idrisi manual, 1997). The Index is
based on the spectral characteristics of the near infra red (NIR) and the red bands.
NDVI = (δNIR - δRED) / (δNIR + δRED)
Where δ = reflectance
Green vegetation has high NDVI values. The NDVI is commonly applied to humid
tropical areas or to arid and semi-arid dry areas. In the dry areas soil moisture is very
low, and vegetation can stand out clearly in the dry-soil background.
Since the study area of TaÕiz is classified as semi-arid area, and its topography is
mountainous, it has been suggested that the use of NDVI is very appropriate to detect
vegetation.
To detect the change in the extent of irrigated land in Wadi Al Hayma, between 1986 and
95, two NDVI images for 1986 and 95, were derived from TM Nearinfrared and Red
bands using the above formula. The two NDVI images were then thresholded
(reclassified) to distinguish between vegetated and non-vegetated areas in each year.
38
Thresholding is a technique used to segment the input image into two categories, one
exceeds the threshold and the other falls below the defined threshold (Lillesand & Keifer,
1994). Figure (11a) below shows the two derived NDVI images. The thresholded,
reclassified, images are shown in Figure (11b).
The reclassified NDVI images were then overlaid on top of one another and draped on
the DEM as shown in Figure (12). The result allows the distinction between irrigated
areas in each year.
1986 1995
Figure a.
Figure b.
Figure 11. NDVI images, light grey batches represent vegetation (a), andthe thresholded (reclassified) NDVI showing cultivated areas only (b).
39
40
Irrigated in 1986
Irrigated in 1995
Irrigated in 1986 & 95
N
1986 1995
Figure 12. The reclassified NDVI images for 1986 & 95 draped on the DEM.A northward shift in irrigation is noticeable.
41
4.5.2.1 Analysis of the Result:
The images show a dramatic shift in irrigation from the southern part of the wadi to the
upper northern regions. The northwards shift has taken place since the groundwater
aquifer in the southern part dried up. Farmers moved uphill searching for water bearing
Tawilah Sandstone soil (see Figure 3).
To get quantitative results areas irrigated in each year, 1986 and 1995, were calculated
using the thresholded images and GIS facilities. The analysis shows an increase in the
amount of irrigated area by approximately 64% between 1986 to 1995. This is shown
in Figure (13).
Assuming that 80cm depth of irrigation water is applied in the dry season, the amount
of water needed to irrigate the above calculated areas can be estimated as shown in Table
(2) below.
5.9
9.7
0
24
6
8
10
sq km
1986 1995
Change in Irrigated Area 1986-95
Irrigated Area
Figure 13. Irrigated areas in km2 1986-1995, calculated from TM images.
42
Year 1986 1995
Water needed 4,720,000 m3 7,760,000 m3
Table 2: The amount of irrigated water needed in Wadi Al Hayma 1986 & 1995.
The increase in the irrigated areas between 1986 and 1995 suggests that the drying up of
the Lower Al Hayma can be attributed to unsustainable water pumping by the local
farmers, as well as to the pumping of the water by the pipeline for the city supply
(Handley, 1999).
4.5.3 Land-use as an Indicator of Water-use:
Land use and the way that land is utilized is a good indicator of water use patterns. To
estimate the total amount of water consumed/needed in the area, a land-use map for the
larger Upper Wadi Rasyan catchment was made. The map was compiled from satellite
imagery interpretation and field observations. The GIS work, the calculation statistics
from the spatial data, and the map design was carried out by the author. The land-use
map is shown in Appendix A, at the appendix at the end of this document.
4.5.4 Groundwater and aquifer modelling :
To understand the physical causes of the water crisis in Al Hayma and why the aquifer
failed and dried up, one needs to understand the physical characteristics of the aquifer
43
and how it functions. Also, one needs to include the different interrelated parameters
that have played a role in the lead-up to the current situation.
The modelled area, Wadi Al Hayma, was divided into a mesh of cells of 200 by 200
metres each. Each cell was assigned a unique ID number. Using the GIS facility in
ARCVIEW software and, by overlaying the grid on the image showing the difference in
irrigation between 1986 and 1995, as shown in Figure (14) below, the irrigation
properties in 1986 and 1995 for each cell were identified. The analysis is based on the
principle that all water inputs to individual cells must equal the outputs plus the
infiltration to the groundwater aquifer and, the evaporation plus the change in storage
(Handley, 1999). This could be expressed as the following water-balance equation:
Rainfall + Run-on = Outflow + Evaporation + Abstraction for City Supply ±
Change in storage.
Where run-on and outflow have surface and sub-surface components, and evaporation
also includes evapotranspiration, change in storage is the net result of sun-surface inflow
and outflow. The change in storage is measured through hydrographs.
A number of models have been developed to simulate the water balance equation so as
to reproduce the historical trend (Handley, 1999). Table (3) summarises the functions,
inputs and outputs for each of these models. Where satellite images were used it is
highlighted.
44
45
Function Inputs OutputsRunoff Model - Daily data from 1983 to 1995.To generate runoff volumesto Al Hayma.
Airport Daily Rainfall,SCS Land Use Types
Daily flows from tributaries andflanks to be applied to centralwadi course and edge areas of AlHayma (as mm)
Evaporation Model - Daily data from 1983 to 1995.To estimate the amount ofwater required by each cropfrom abstraction above andbeyond that provided byrainfall and runoff and, wherewater input from the lattertwo exceeds demand, toestimate the infiltration.
Airport daily mean dryand wet bulbtemperatures, sunshinehours, Airport andUsayfra wind run. z-dand crop heights. Outputfrom Runoff model.
Net infiltration and abstractionfor locations receiving centralspates, flank spates and justrainfall for the appropriatecropping pattern (m3 per 100mx 100m grid square per season.Dry season Oct-Feb, wet Mar-Sept)
Steady State Groundwater Flow Model (GWVistas/Modflow) 1976 pre-developmentcalibrationTo match groundwater headsin 1976 as an essentially pre-development steady-statecondition and compare runoffindicated by the groundwatermodel with that by the runoffmodel.
Aquifer geometry,hydraulic conductivity,subsurface tributary andoutlet constant heads,net recharge derivedfrom evaporation model.
Calibration of flows and heads
Transient Water Balance Model a)To run a mean rainfall year(1987) five times,incrementing drawdowns toexamine whether the scenariobeing considered couldapproach matching theobserved hydrographs.
Satellite imagedetermined irrigationareas for 1986. Outputfrom evaporation modelfor 1987.
Calibration of hydrographs.Assessment of flows.
Transient Water Balance Model b)To match the completeobserved hydrograph recordfrom 1983 to 1995
Satellite imagedetermined irrigationareas for 1986 and 1995.Output fromevaporation model for1983 to 1995.
Calibration of hydrographs.Assessment of flows.
Recovery ModelTo predict how long it wouldtake the aquifer to recover toapproximate pre-development levels if the citycontinued to abstract as in1996 and there was noirrigation.
Satellite imagedetermined irrigationareas for 1995. Outputfrom evaporation modelfor 1987.
Predictive hydrograph
Table 3: Summary description of the function, inputs and outputs of each of themodels used by Handley. Satellite imagery usage is highlighted.Source: Handley (1999)
46
4.6 Results and Analysis:
Leggette et alÕs (1977;8-18) estimation of 8 Mm3/yr of water, to be abstracted to the
city, as an effective end to irrigated farming, was considered a Ôreasonable objectiveÕ for
abstraction from Wadi Al Hayma and Miqbab. The modelling carried out by Handley
suggests that if the relatively undeveloped situation of 1976 is taken as a starting point,
three sustainable yields of Al Hayma should be considered:
i) 2.7 to 1.7Mm3/yr if abstraction for the city is not to detract from agriculture,
ii) 4.2 to 3.0 Mm3/yr if no outflow from Miqbaba is to occur,
iii) 5.9 to3.8 Mm3/yr (that is 4.8 Mm3/yr ±20%) if irrigated farming were to cease.
The last option matches the impact assumed by Leggette et al., (1981) but is only 60%
of their Ôreasonable objectiveÕ of 8 Mm3/yr.
Actually, farmers increased the irrigated area in Al Hayma after 1976. Figure (15) below
demonstrates the abstraction for both irrigation and the city.
The modelling suggests it would take nine years for the Al Hayma basin to recover if
abstraction for the city remained at the (low) 1995 level, and if irrigated agriculture
ceased (Handley, 1999).
47
4.7 Conclusion:
The hydrological model derived by Handley (1999), provided with remotely sensed data
and assisted by GIS, has shown that the consultants ÐLegette et al., (1977)- got their
estimates wrong. Their estimation was comprised of:
• Wrong assumptions and false data for their modelling.
• Poor logic, since they stated that the total quantity available for export to the city
was 9 Mm3/yr ±20%. They proposed an abstraction of 10 Mm3/yr (of which 8
Mm3/yr from Al Hayma and Miqbaba). Common sense would suggest a maximum
total of 7 Mm3/yr from the whole area including . Al Hayma and Miqbaba.
Abstractions from Al Hayma - Miqbaba Aquifer : Scenario 2
0
1,000,000
2,000,000
3,000,000
4,000,000
5,000,000
6,000,000
7,000,000
1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995
m3
/ ye
arAgriculture
City Supply
Figure 15. Abstraction from Al Hayma Ð Miqbaba Aquifer 1983-95.Source: Handley (1999b)
48
• End of irrigation: it is not good assumption and politically inconceivable. The
farmers continued abstraction from the aquifer.
Although the city of TaÕiz abstracted less than the design capacity estimated by Legette
et al., every year, however, in reality that proved to be too much. In other words, the
aquifer did not have the estimated capacity.
49
CHAPTER V. ANALYSIS OF THE SOCIAL ENTITIES IN WADI AL HAYMA:
ADAPTATION TO WATER SCARCITY:
5.1 Coping Strategies:
In a social science study, one needs to consider the unit of analysis. For instance, the
unit can be an individual, which is the domain of psychology. It can be a social group,
and this is the domain of anthropology. It can also be a number of social groups
together, and this is the domain of political science or political geography7. In this
analysis two distinct social entities are present:
• The local tribal people of Wadi Al Hayma, who are basically farmers from
communities with centuries of experience of managing water.
• The government represented by the water authority and their WDM policies.
The reason for this distinction is that the two entities show different interests.
Water scarcity in Wadi Al Hayma is one of increasing severity. This implies that the
number of available coping options decreases accordingly. Local people adopt various
strategies in the face of increasing water scarcity. The main water-related events,
stimulants, and local peoplesÕ responses, in other words Ôcoping strategiesÕ, are as
follows:
7 Turton (1999), Personal e-mail dated 12 Jul 1999.
50
• International and cross-border migration and the Ôvirtual waterÕ resulted from it,
1975 - 1990
• Hydrological mission and investment in pumping equipment, 1976 - present.
• The Gulf War and more investment in pumping equipment, 1990 Ð 1991.
• Moving up the wadi to exploit sources, 1984 Ð present.
• Internal migration, 1985 Ð present.
• Resistance by local people and confrontation with Government.
5.1.1 Cross-border migration and Ôvirtual waterÕ:
Steffen (1979) estimated the private transfer of money to Yemen by emigrants in the
year 1976/77 at 4.5 billion Y Rials ($1 billion). In the years that followed, it was
estimated to be more than 5 billion Y Rials (Schoch, 1982). Most of the remittances
were invested in constructions, such as house building and roads, in transportation and
other facilities. Most of the emigrants were from the rural population. However,
investment in agriculture did not get high priority at that time (Schoch, 1982). This is
because: investment in well-pumps for irrigation was always a high risk, especially in
mountain areas, since no ground-water surveys had been carried out which had
guaranteed successful water yield. Also, because of the sharp decline of labour available
for the labour-intesive rainwater harvesting technique for agriculture, due to labour
migration.
51
A very interesting point mentioned by Schoch (1982) is that, Òof main importance are
the investments in qat and imported consumer goods, including foodstuffs like meat,
fruits, wheatÉetcÓ, which is a form of Ôvirtual waterÕ (Allan, 1997). Therefore,
groundwater aquifers were maintained and kept in a steady state (i.e. increasing the
options for local people). This is illustrated in Figure (16b) below as an upward shift in
the line showing the relationship between water scarcity and the Ôrange coping
strategiesÕ available (the red line). Figure (16b) is a modified version of Figure (16a). In
Figure (16b) the red line is for local people while the green one is for the government.
The Yemeni government, however, subsidized the food imports, which meant a loss of
foreign currency in the form of import taxes, in addition to the inflation of the Yemeni
Rial. This loss is illustrated in Figure (16b), by a downward shift in the governments
curve (the green line) indicating a decrease in the coping options available for the
government. However, to achieve Ôfood securityÕ and Ôfood self-sufficiencyÕ, the
Yemeni government banned certain food imports, for example, fruit imports banned in
1983, and started to investigate the groundwater aquifer. This marked the start of the
hydrological mission phase.
5.1.2 Hydrological Mission:
In 1976, investigations of the groundwater aquifers in the TaÕiz area carried out by the
government, and the Al Hayma aquifer was proven to have significant potential8. The
main objective of the investigations in Al Hayma was to supply the city of TaÕiz with
8 Handley (1999), Personal conversation.
52
water. The engineers and scientists had neglected to inform the farmers and stakeholders
about the purpose of these investigations. Consequently, local people grew suspicious
of government intentions. Also, the farmers started to become aware of the potential of
the groundwater as a water source for dry winter irrigation. They reacted by drilling
wells, and more investment went into agriculture to safeguard their land and water
resources. Similar responses to the hydrological mission have been observed in the
SaÕdah area, northern Yemen (Lichtenth�ler, 1999). This has led to the exploitation of
groundwater and the exacerbation of the water scarcity situation, and hence local people
have lost out on coping strategies. At the same time, although temporally, the
hydrological mission raised the governmentÕs expectations and appeared to increase their
coping options, as demonstrated in Figure (16b).
5.1.3 More Irrigated Qat :
One of the coping strategies adopted by local people in the face of water scarcity was
increasing qat cultivation. Qat is a bush-like tree that produces a narcotic leaf widely
used by Yemeni people as a stimulant. It grows successfully in altitudes of 1200 - 2400
meter above mean sea level, with annual average temperatures of 16-22 C., and between
400-2000 mm precipitation. It was brought to Yemen from Ethiopia in the first half of
the 13th century AD.
The early 1970s witnessed an increase in qat cultivation in Yemen. This was not only
because of its high returns, but also because it proved to be one of the better options
during the drought years that started in 1967, and lasted for seven years (Lichtenth�ler,
53
1992). Farmers, including those in Wadi Al Hayma, rely on qat cultivation as a major
element in their livelihood and sustenance for the following reasons:
• Qat is a drought resistant tree and a hardy plant, which tends to be dormant in
periods of prolonged water shortage. Its water requirement is low compared to
other crops cultivated in the area.
• Harvesting can be controlled, and returns spread out over many months. Qat yields
after four years, and the leaves of the tree are picked twice every year. However,
the tree produces new leaves as soon as it receives water. Therefore, it allows the
farmer to exercise much more control over harvesting and marketing than with other
crops (ibid, 1992).
• Qat does not require high inputs such as fertilizers and pesticides. In fact, Yemeni
farmers do not use fertlizers for qat, since they believe that fertilizers spoil its taste
and lower its quality. Stories have it that even locusts do not touch the tree
(Lichtenth�ler, 1992). Commercial pesticides are not used due to fears that it might
be harmful to health. Instead, qat trees are usually dusted with dust twice a year, 15
times a year in the case of grapes, to keep insects off.
• Qat grows in poor soils and it protects the soil from erosion.
• Qat can be interplanted with other crops in the terraces. In the TaÕiz area, qat is
occasionally interplanted with maize and sorghum. In addition, since the
government banned fruit imports in 1983, farmers have started planting fruit in qat
fields (Lichtenth�ler, 1992; Lichtenth�ler & Turton, 1999). Some Yemenis also
54
believe that mixing other crops and trees with qat helps minimize weeds, and
protects against erosion.
• Qat trees can be productive for up to fifty years. This adds to the economic value
of the tree. The net profit can be as high as 24 times that of sorghum and 3.5 times
that of coffee. Furthermore, the tree provides fodder for some animals, highly
valued firewood, and some shade in a country that has lost most of its forests.
• Qat is a very lucrative and valuable cash crop. It generates areas of employment for
a wide range of people in the rural population.
From the above points, one can conclude that qat and the revenues from it play an
important role in rural development and infrastructure construction in Yemen
(Lichtenth�ler, 1992). For instance, people in small villages situated on inaccessible
mountain slopes, using hand tools, build roads which connect them to qat markets in
order to sell their crops.
Furthermore, the actual water requirement and consumption of qat itself appears to be
less than government official claim. This might be because of the fact that qat
encourages production and consumption of local grains and vegetables. Additionally,
since it is a perennial tree, qat protects the soil from erosion for other seasonal crops,
such as vegetables. In other words, most of the water is consumed by the crops either
interplanted with qat, or qat encourages their cultivation. For instance, in Wadi Al
55
Hayma it was observed that in winter, potatoes are interplanted with qat9. In the TaÕiz
area, 12% of the irrigation water is used for qat, 30% for maize, 20% for sorghum/millet,
and 8% for potatoes in the major wadis (UN/DDSMS, 1997: xix).
Most of the investments in agriculture were directed towards qat cultivation. As a
result, 80-90% of new well drilling in the southern highlands of Yemen, including the
study area) primarily has been carried out for qat irrigation (Lichtenth�ler, 1992). The
above details indicate how qat cultivation is considered a very viable livelihood coping
strategy for the local people in Wadi Al Hayma. It demonstrates an increase in local
peopleÕs coping strategies, depicted as an upward shift of the red line in Figure (16b).
However, this dramatic increase of groundwater-irrigated qat cultivation by local people
was based on the assumption that there was an unlimited source of groundwater in the
aquifer10. The increase in the extent of the irrigated area for qat cultivation in Al Hayma
was not very welcome to the government, for whom Wadi Al Hayma was considered
the promised future solution for the city of TaÕizÕ water crisis, as shown in Figure (16b)
If the government were to stop qat cultivation, however, suitable alternatives should be
found/created, before taking any action, which would substitute for this poor urban
peopleÕs very vital source of sustenance. Whatever the alternative is, it should be
applied gradually with carefully formulated long term planning.
5.1.4 Water Pipeline to the City:
9 Handley 1999, personal conversation
56
The number of wells drilled by the NWSA to supply the city with water has exceeded
thirty (Ward and Moench, upub, cited in Handley, 1999). A pipeline has been built to
transport the water directly to the urban area of TaÕiz. The authority managed to
convince the shaikh of Lower Al Hayma, the late Shaikh Sadiq, to agree to the drilling of
deeper wells. Out of the deal, the shaikh got three deeper drilled wells for his family.
The NWSA wells reached a maximum depth of 100 to 120m.
The pumping for the city started in 1982, and four years later local peopleÕs shallow
dug wells, in Lower Al Hayma, had almost dried up. The water level in the aquifer was
dramatically depleted because of the unsustainable pumping of water exceeding the
sustainable yield of the aquifer. In 1987, the new wells drilled by NWSA, as part of an
Ôemergency drilling campaignÕ, reached a maximum depth of up to 500m. The
government would not allow local farmers to deepen their wells, yet not surprisingly
shaikh Sadiq managed to get one of these new deeper wells (Handley, 1999).
The laying out of the pipeline for the city of TaÕiz water supply has had a negative
impact on the water resources in Wadi Al Hayma and the local farmers. This implies a
decrease in the coping options for the local people as shown Figure (16b).
However, by ÔcapturingÕ the water resources and ÔreallocatingÕ them from the
agricultural sector to industry, the government thought that would increase the options
available for itself, Figure (16b). Nevertheless, with the adopted Ôallocative efficiencyÕ
10 Allan (1999) Personal conversation
57
or the Ômore jobs per drop optionÕ strategy (Allan, 1999) there are always some
Ôpolitical pricesÕ that have to be paid.
5.1.5 The Gulf War 1990-1991:
The position adopted by the Yemeni government through its support of Iraq in the Gulf
War had a big negative impact on the economy of Yemen. Most of the Yemeni people
who used to work in the oil-rich Gulf countries were made redundant from their jobs and
were forced to return to Yemen. This resulted in the loss of remittances and the
devaluation of the Yemeni Rial. As a consequence, many of the traders in Yemen were
forced out of business. Both the returnees and the ex-traders turned to the only other
source of livelihood available Ð irrigated agriculture. The effect of this has been the
redirection of significant amounts of capital into investment in pumping equipment.
This in turn had a very detrimental effect on the groundwater aquifer and helped in its
depletion. Resultantly the coping strategies for both the local people in Wadi Al Hayma
and for the government were reduced (see Figure (16b)).
5.1.6 Shift to the Upper Al Hayma:
As a consequence of the depletion of the groundwater aquifer and the drying up of their
shallow wells, farmers in the Lower Al Hayma have shifted their irrigated farming up the
wadi to explore the water-bearing sandstone, the Tawilah Sandstone, to the north of the
graben (see Figure 3).
58
The shift can be clearly detected in the Landsat TM images (Figure 11 ). In the images it
is evident that most fields irrigated in 1986 have been abandoned, with a few exceptions,
in 1995. Due to the Lower Al Hayma experience, the shaikhs of the Upper Wadi Al
Hayma have refused to negotiate any proposed well drilling by the government for the
city supply in their territories. This has encouraged farming practices in the area which
result in intensification and extensification of agriculture in the Upper Al Hayma.
59
5.1.7 Internal Migration:
As a result the drying up of farmersÕ wells in Lower Wadi Al Hayma, some of the
farmers, especially young men, abandoned farming and went to work in the city of TaÕiz
or in other urban centers. The demise of irrigated farming in the area was a Ôpushing
factorÕ for local farmers to migrate to other areas, and urban centers to look for
alternative livelihoods and other sources of sustenance. The majority of the immigrants
work in big factories in the city as labour.
5.1.8 Resistance by Local People and Confrontation with the government:
Based on their experience with what has happened in Lower Wadi Al Hayma, local
people have lost trust in the government and its promises. Also, some have lost trust in
their shaikhs. This is accompanied by a clear realisation that they are losing out on a
very vital natural resource - water - which is ÔcapturedÕ by the government by force.
People in the upper Wadi Al Hayma started to become very suspicious of any drilling in
the area. In June 1992, some locals from the Habir area, north Al Hayma, disconnected
one of the governmentÕs wells. The government reacted by bringing twenty trucks of
soldiers, from TaÕiz military camp, to the area on standby and helicopters were brought
in for reconnaissance. The situation was resolved by a forced agreement of co-operation
by the locals (Handley, 1999).
Further drilling in Habir was again met by resistance from local people in 1993. All the
shaikhs in the TaÕiz area were called to attend the presidentÕs speech in SanÕa, in which
60
he threatened the shaikhs that, either through use of traditional customs or by violence
they would have to co-operate with the drilling in the area (ibid, 1999).
In April 1995, six exploratory wells were started in Habir, and local people pushed the
drilling workers off the site. Three shaikhs were imprisoned because they did not want
to give promises of co-operation to the government, as they knew of their peoplesÕ
mistrust of the government. They were released after they had been forced to sign an
agreement of co-operation, and a government compensation package for the locals was
included in the agreement (ibid, 1999). In January 1996, the government failed to pay
part of the compensation, the drilling was stopped by local people and the violence
started again. Two women were seriously injured when one of the soldiers opened fire
at the protesters.
Other areas in TaÕiz started to resist government well drilling. For instance in 1995, a
drilling was halted by 5,000 armed men from Wadi Warazan who suspected it was for
abstracting water for the city of TaÕiz. The actual purpose of the drilling was to collect
information for a dam feasibility study. The situation was resolved after the governor of
TaÕiz had ensured that no drilling for the city supply would be carried out and, no dam
would be built (ibid, 1999).
5.2 The Pattern:
The diagram in Figure (16b) shows that the overall patterns of change of available
Ôcoping strategiesÕ for local people and the government mirror-image each other.
61
Increases in the range of local peopleÕs coping strategies are considered destructive and
minimizing by the government, and vice-verse. This indicates the following:
• That there are different contradicting perceptions about water and its use, the
governmentÕs perception and local peopleÕs perception.
• There are different interests for the government, which tries to meet the required
demand of the urban area, and the local farmers who struggle to adapt to water
scarcity in the area.
• There is a huge cleavage between the two social entities.
• The government and the local people work in isolation of each other.
• Yemen represents a case of a society that experiences severe Ôsecond order
scarcityÕ, that is, Ôadaptive capacityÕ is lackingÕ, as well as Ôfirst order scarcityÕ
62
Original linedepicting waterscarcity & copingstrategiesrelationship
Local People
Government
Migration & Ôvirtual waterÕ 1975
Hydrological missions 1976
Pumps for more qat
Water pipe to TaÕiz 1982
1
2
3
4
The Gulf War 1990
Shift upwards the Wadi
Resistance & confrontation
5
6
7
Figure 16. The modified relationship between water scarcity & coping strategies.Figure (a) shows the original relationship. Figure (b) shows how some events havemodified this relationship in the case of Wadi Al Hayma. The red line is for localpeople, the green one is for the government.Note: This is not a quantitative graph. It is not to scale. The two axises show relative ranges of abstract(unquantifiable) variables. The main purpose of this diagram is to show the mirrored symmetricalperceptions of the two social entities involved in the crisis, as perceived by the author.
TIME1975 1976 1982 1990 1995
51 2 3 64 7
Water Scarcity
R
ange
of
copi
ng s
trat
egie
s
Figure a.Figure b.
Ran
ge o
f A
vaila
ble
Cop
ing
Stra
tegi
es
Water Scarcity
63
5.3 Conclusion:
So far we have discussed three points. Firstly, we have examined the model through
which the water crisis in the TaÕiz area can be analyzed. The model suggests that if a
society has sufficient Ôadaptive capacityÕ in the face of water scarcity, water resources
reconstruction can be achieved. The model is shown as a monument of which the two
main supporting pillars are the Ôsocial componentÕ, what is inside the hearts and minds
of local people, and the Ôstructural componentÕ, institutions and government, of the
adaptive capacity (Figure 1). The existence of ÔfeedbackÕ and ÔsupportÕ between these
two components is an important factor. Secondly, the importance of accurate estimates
of water resources, and how they are useful in strategic planning has been examined. In
Chapter 4, the potentials of remote sensing and GIS techniques to provide such
estimates were explored. Thirdly, in Chapter 5, the social dynamics of the two main
social entities forming the main actors, involved in water scarcity in the area, local
people and the government, and how their responses mirror-imaged each other and
involved very different impacts and reactions (Figure 16b), were reviewed.
It is evident that because of the socio-political environment that exists in Wadi Al
Hayma and the TaÕiz area, water Ôresource reconstructionÕ is unlikely to take place
unless the socio-political structure changes. In this chapter, the social and institutional
reasons that have led the situation in Wadi Al Hayma to reach the position that they
have will be examined.
64
5.3.1 What is Missing?
5.3.1.1 Lack of ÔFeedbackÕ and ÔSupportÕ:
As mentioned above, Figure (16b) indicates that there is a cleavage between the local
people and the government. This cleavage has led to the absence of balance between the
two main components of the Ôadaptive capacityÕ of the whole society. This
cleavage/gap, in the context of Yemen, is caused by the absence of the ÔfeedbackÕ and
ÔsupportÕ shown in Figure (1). The absence of feedback and support has caused the
two components of Ôadaptive capacityÕ to be developed in isolation from each other
(Turton, 1999a).
5.3.1.2 Legitimacy Crisis:
ÔSupportÕ is the backing up of the regime by the governed. It is either given or withheld
as a result of some actions (ibid,1999a). Support for a government is highly dependent
on the governmentÕs legitimacy. Governments gain legitimacy, for instance, through a
general election (given legitimacy), or otherwise by trying to strengthen the feedback
process of their actions. In the context of this study, it is obvious that the lack of
legitimacy is evident. The authorities do not have enough support to implement such
costly and socially stressful strategies. In other words, the government faces a
legitimacy crisis as well as water crisis. By paying the shaikh of Lower Al Hayma,
shaikh Sadiq, with some wells helping him achieve Ôresource captureÕ, the authority tried
65
to buy his support and thereby attempted to make its actions and strategies legitimate.
However, the actions had led to the reverse result.
Furthermore, perceptions are of vital importance for the support and gaining of
legitimacy for the government. If the regime and the governed share the same
perceptions about the water resource use, including the presence of other factors, the
regime might then gain some support. The main facto, which needs to be present, is the
ÔfeedbackÕ process from the government. To gain support for its water management
policy the government should provide some ÔfeedbackÕ to the governed. This could be
in the form of sharing information about water resources with local people, and through
adapting and enhancing local strategies. Techniques such as GIS and the state of the art
remote sensing technology are ways of capturing accurate information quickly, and on
such information, decision-makers can base their decisions and can formulate water
strategies. Therefore, if used correctly, it can be of great support to the Ôstructural
componentÕ of the Ôadaptive capacityÕ. However, if such information is not shared with
local people, and local people are not clearly informed, in the absence of feedback, of the
water resource condition, these valuable data will not be of any use and, end up in a pile
of files in a government office.
The lack of feedback is evident in the case of Wadi Al Hayma. Local people were not
informed about the water resource conditions at all. Also, they were not informed about
the purpose of the drilling. Moreover, obviously local people did not know, and do not
know, that Ôan effective endÕ to irrigated agriculture in Wadi Al Hayma was a
Ôreasonable objectiveÕ for abstraction from the area to the city of TaÕiz (Leggette et al.,
66
1977). This lack of feedback by the government can be understood in terms of
MigdalÕs (1988) Ôstrong society and week statesÕ analysis, that is, where state
institutions are not strong enough to ensure that sharing information with local societies
will not cause political and social stresses. The situation in Wadi Al Hayma, and the
governmentÕs circulation of misinformation, clearly indicates Yemen as typifying this
concept of a Ôstrong society and weak stateÕ.
67
CHAPTER VI. CONCLUSIONS.
Social frameworks are research tools to measure and assess complex social issues. They
are offered to simplify otherwise complex social issues. The social dynamics of water
scarcity are exceptionally complex. Various societies have different abilities to cope
with water scarcity. Ohlsson (1999) calls this ability the Ôadaptive capacityÕ of a
society.
The social framework, model, provided by Turton (1999a) is used to analyse the water
crisis in the TaÕiz area, and the social implications are examined in this framework. The
model suggests water resource reconstruction can be achieved by Water Demand
Management (WDM) strategy, if the society has enough Ôadaptive capacityÕ. The
model identifies the two components of a societyÕs Ôadaptive capacityÕ, the structural
component and the Ôsocial componentÕ. It emphasises that for WDM to be effective,
both social and structural components/aspects should be considered and have to be
balanced with each other. Therefore, there should be feedback and support between the
two components.
The study has shown that for the concept of Ôadaptive capacityÕ to be applied
effectively, one has to consider the scale at which a society is identified. Local people
in Wadi Al Hayma, as a small social entity, adapt differently to the government, while
the shaikh in Lower Al Hayma, through means of resource capture, has adapted
differently to the local people. Therefore, it is a matter of social integrity, which is a
function of societal perceptions.
68
Furthermore, different reports assessing the water resources of the TaÕiz area have been
produced, however, they are flawed due to a lack of hydrological data. Analyses and
recommendations based on flawed hydrological data can have detrimental effects on the
water resources.
Furthermore, the study shows that remote sensing and GIS techniques can provide
quick accurate data on which water management strategies can be based. In other words,
they can improve the quality and the make up of the Ôstructural componentÕ of the
Ôadaptive capacityÕ. Such information should be shared with local societies through a
feedback process.
Wadi Al Hayma has evinced that where there is a lack of feedback from the government
to local people, circumstances will not improve where the community, as in the TaÕiz
area does not trust a non-legitimate government.
69
BIBLIOGRAPHY:
Abdo, J. M. (1997), The Water Crisis of Yemen: Sizing the Problem, Offering Solutions.
In YEMEN TIMES newspaper, 40, vol, VII. 6-12 Oct. 1997.
Allan, J. A. (1986). How Few Data Do We Need: Some Radical Thought on Renewable
Natural Resources Surveys. Symposium on Remote Sensing for Resources
Development and Environmental Management, ITC, Enschede.
Allan, J. A. & Karshenas, M. (1996a). Managing Environmental Capital: The Case of
Water in Israel, Jordan, the West Bank and Gaza, 1947 to 1995, in Allan, J.A. & Court,
J.H. (eds.) Water, Peace and the Middle East: Negotiating Resources in the Jordan
Basin. I.B. Taurus Publishers: London.
Allan, J. A. (1997a), ÔVirtual WaterÕ: A long Term Solution for Water short Middle
Eastern Economies. Paper presented at the 1997 British Association Festival of Science,
Roger Stevens Lecture, University of Leeds.
Allan, J. A. (1997b), Virtually no Water. The Middle East, 1997: 15.
Allan, J. A. (1998). Environmental Remote Sensing. Lecture notes. SOAS.
Allan, J. A. (1998b) Productive efficiency and Allocative Efficiency: Why better Water
Management may not Solve the Problem. Agricultural Water Management.
70
Allan, J. A. (1999). Global Systems Ameliorate Local Droughts: Water, Food and
Trade. Paper presented at the Exploratory Workshop on Drought and Drought
Mitigation in Europe, 1-3 March. Space Applications Institute, Joint Research Centre,
Ispra, Italy.
Aronoff, S. (1989). Geographic Information Systems: a management perspective.
WDL Publications, Ottwa.
Barrett, S. (1997), Environment and Growth. London Business School. London.
Burrough, P. A. (1986). Principles of Geographical Information Systems for Land
Resources Assessment. Clarendon Press. Oxford
Cypher, J. M. & Dietz, J. L. (1996), The process of Economic Development.
Routledge: London.
Dresch, P. (1989). Tribes , government and History of in Yemen. Clarendon Press,
Oxford.
ERDAS IMAGINE On-Line Help, Copyright ©1982-1997 ERDAS, Inc.
Evans, T.E. (1997). Water Resources Ð The Need for Regional, Continental and Global
Assessments Ð An African Perspective. In Kay, M., Franks, T. & Smith, L. (eds.)
Water: Economics, Management and Demand. London: E & FN Spon
71
Falkenmark, M. (1989). The Massive Water Scarcity Now Threatening Africa Ð Why
isnÕt being addressed?. Ambio, Vol. 18, No. 2. Pp. 112 Ð 118.
Green, D. R.; Young R. H.& Cousins S. (1993). Landscape Ecology and Geographic
Information Systems. Taylor & Francis: London. New York. Philadelphia.
Gun, A. M. vander & Ahmed, A. A. (1995). The Water Resource of Yemen. A
summary and Digest of Available Information, Report WRAY-35.
Handley, C. D. (1999) Unpublished PhD thesis. SOAS, University of London
Handley, C. D. & Dottridge, J. (1997). Causes and Consequences of Extreme Water
Shortage in TaÕiz, Yemen. School of Oriental and African Studies (SOAS), London.
Homer-Dixon, T. F. (1996), Environmental scarcity and violent conflict: Briefing
Book. American Association for the Advancement of Science.
Homer-Dixon, T.F. & Percival, V. (1996). Environmental Scarcity and Violent
Conflict: Briefing Book. American Association for the Advancement of Science.
Http://rst.gsfc.nasa.gov
Http://www.yementimes.com.
72
Idrisi Manual, (1997). Idrisi Version 2 for Wwindows. Clark University Labs. U.S.A.
Leggette, Brashears & Graham (1977). Hydrogeologic Investigation for Well Field
Development in Al Hayma Basin. YAR, report for NWSA. Yeman.
Lichtenth�ler, G. (1992). Qat Cultivation in Yemen: Its Effect on Agriculture, Rural
Economy and Society. SOAS, University of London.
Lichtenth�ler, G. & Turton A. R. (1999). Water Demand Management, Natural
Resource Reconstruction and Traditional Value Systems: A case Study from Yemen.
Occasional Paper No. 14. Water Issues Study Group, SOAS, University of London.
Lillesand, T. M. and Kiefer, W. R. (1994). Remote Sensing and Image Interpretation.
John Willey & Sons, Inc. USA.
Mather, A. P. (1993). Computer Processing of Remotely-sensed Images.John Wiley &
Sons : New York.
Meadows, D. H.; Meadows, D. L.; Randers, J., & Behrens, W. III (1972). The Limit
to Growth. Earth Island Ltd. London.
Merret, S. (1997). Introduction to the Economics of Water Resources: an International
Perspective. UCL Press. London.
73
Merret, S. (1998). The Regional Water Balance Statement: A new Tool for Water
Resources Planning. Occasional Paper No. 3. Water Issues Study Group, SOAS,
University of London.
Rees, W. (1996). Ecological Footprints of the Future. People and the Planet Vol. 5,
No. 2, 1996.
Reisner, M. (1993). Cadilac Desert: The American West and its Disappearing Water.
Revised Edition. New York: Penguin.
Schoch, R. (1982), Land-cover Studies and Crop Acreage Estimates from Arial
Photography and Satellite Imagery. Vol 5. Department of Geography, University of
Zurich. Switzerland.
Steffen, H. (1979). A contribution to Population Geography of the Yemen Arab
Republic. Beihefte des T�binger Atlas des Vorderen Orients, Serie B, Vol. 39,
Wiesbaden.
Sulivan, S. (1999). Nothing is Stationary, all is Change. Political Ecology Group,
SOAS, University of London.
Turton, A. R. (1999a). Water Scarcity and Social Adaptive Capacity: Towards an
Understanding of the Social Dynamics of Water Demand Management in Developing
74
Countries. Occasional Paper No. 9. Water Issues Study Group, SOAS, University of
London.
Turton, A. R. (1999b) Water Scarcity and Social Adaptive Capacity: Towards an
Understanding of the Social Dynamics of Managing Water Scarcity in Developing
Countries. Paper presented at Stockholm 1999.
UN/DDSMS (1997). Hydrological and Land-use Studies in TaÕiz Region (Upper Wadi
Rasyan Catchment) (TCD CONTRACT NO: YEM/93/010-3). Volume (1): Main
Report. Dar El-Yemen Hydroconsultants & SOAS.
World Bank report (1997). Yemen: Towards a Water Strategy and Agenda for Actin.
Report No. 15718-YEM.
World Bank (1992). World Development Report 1992, Oxford: Oxford University
Press.
Winpenny, J. T. (1997). Demand Management for Efficient and Equitable Use. In Kay,
M., Franks, T. & Smith, L. (eds.) Water: Economics, Management and Demand.
London: E & FN Spon.
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