Water Control Issue in the United Arab Emirates

Introduction: A Complex Investigation of Water Management Issues

This paper provides a complex overview of the relevant water management concerns in the United Arab Emirates. Moreover, in this paper, the central implication of the key water control problem is analyzed. The suggested solutions and recommendations, which regard the management area, are differentiated.

The fundamental concerns, which determine the regulation of water delivery in the UAE, stem from the recent demographic increase. According to this fact, the demand for water resources is going up quite rapidly as well. The problems, which encompass water management, can be regarded, due to the specific domains, which apply these resources.

The Crisis of Agriculture in the UAE: Irrigation Implications

The United Arab Emirates is the country, which possesses a highly developed agricultural sphere. Thus, due to the beneficial weather conditions, as well as the relative fertility of the soils, the individual and state productions make extensive use of planting. The central problem, which connects water management and Arabic agriculture, is the inefficiency of irrigation. Currently, the plants in the fields of the country receive precipitation through the application of traditional spray irrigation methodology. Due to its use, approximately one-third of the water resources are spent in vain. Specifically, the method of spray irrigation inflicts a high percentage of evaporation. Therefore, in the course of water delivery, 35% of the supplied resources get wasted. Therefore, it is critical to the central authority of the country to take some decisive measures so that to find an alternative way of agricultural irrigation. In this context, the specialists suggest the use of drip irrigation since it directs water straightly to the soil without being exposed to the sun for a long time. Therefore, it does not evaporate (Drip irrigation system  components and their function, 2012).

Private Household Concern: Water Misuse

The second considerable consumer of the water supplies in the United Arab Emirates is the domain of the private household. Naturally, every microsphere of human activity requires water resources. Thus, people need water supplies for the preparation of food as well as the maintenance of basic operational facilities such as air-conditioning system. Therefore, the regularity of delivery manages basic human needs.

The fundamental problem, which brings some serious problems to the household management of water, is the poor quality of tap resources. Due to the negative conditioning and low level of purification of the water pipes, the resources, which are brought into the individual houses, become contaminated and, therefore, can not be consumed. As a consequence, the citizens of the UAE are forced to drink water, which they purchase in the magazines. Moreover, the experts deduced that the water, which is delivered through pipes, can not be used even for irrigation since it can damage the quality of soil and the production. Therefore, a huge amount of water resources is spent for no purpose.

Due to global warming, as well as the peculiarities of the Asian climate, the demand for water among the individual consumers increases annually, which limits the accessibility of bottled water and enhances its price. Thus, it might be helpful for the government to launch an operation of water pipes purification, for the edibility of tap water would increase the amounts of the valuable resource considerably. Furthermore, much water is spent on air-conditioning systems support. Mainly, the systems employ a large quantity of the resources in the form through pumps. Consequently, water management should improve along with the renovation of water conservation techniques as well (Dakkak, 2015).

Industrial Water Management: The Issue of Reuse

The sphere of industry employs water resources in smaller amounts than the other spheres of human activity. Still, a considerable amount of water is wasted for cleaning the industrial facilities and machinery. As a result, a huge amount of wastewater is generated throughout the country. In this context, the concept of water reuse might be relevant, for the resources, which are spent for cleansing can be gathered after the operations are completed. The reused wastewater, then, can be directed to the irrigation centers or allocated for household supply. The most consistent and optimal method of water reuse is desalination, which might be sustained through building special plants, which would withdraw the employed water and turn it into cleansed resources. Currently, the separate cities in Arabic world already managed to employ the strategy and established desalination plants. This particularly regards such urban centers as Dubai and Abu Dhabi (Matlock, 2008).

Nevertheless, the issue of water reuse is doubted and questioned in the United Arab Emirates, for the experts claim that it can inflict some consistent damage on the natural environment. Thus, it is claimed that the brine, which is generated in the course of water purification, is directed to the Arabian Gulf. This tendency, consequently, leads to the contamination of the ocean. In this context, the issue of basement water protection evolves.

Water Basement Cleansing: The Issue of Environmental Protection

It was mentioned previously that desalination plants serve as the sources of river and ocean contamination. The ecologists argue that the quality of water in the Arabian Gulf reduced to the level, on which it can no longer be used for irrigation or household delivery. Desalination functioning is not the only threat for the natural water basements. Thus, it is acknowledged that multiple industrial machines and tanks are illegally entering the Gulf for the purpose of cleaning. The tendency provokes a considerable discharge of gasses and the other contamination subjects into the water. Therefore, it is a challenge for the central authorities to impose a strict control over the process of Gulf entering so that to eradicate pollution (Todorova, 2009).

The Controversy of Irrigation in UAE: Management Proposal

Introduction: The Relevance of the Issue

The proposal outlines the major implications and functions of the irrigation system, which is employed in the United Arab Emirates, as well as the central suggestions as to the water management improvement.

According to the primary estimations of the water delivery in the Arab world, one may conclude that the system of the resource control lacks precision and innovation. Due to the analysis of the water use in the country, it was deduced that the domain of agricultural production belongs to the primary consumer-directed areas. The sphere of plant cultivation is optimal and highly successful due to the territory peculiarities as well as the appropriate climate conditions. The basic problem, which hinders the successful sustention of agriculture, concerns the issue of irrigation. Due to the high level of evaporation, the poor quality of the Gulf water as well as an inefficiency of irrigation facilities, the domain faces considerable losses. Therefore, it was decided to select the issue for the further contemplation with an aim of developing a consistent implementation proposal for the further improvement of the irrigation system.

The Aim of Proposal and Study Design

The primary objective of the work is to provide a complex estimation of the appropriate water management methods, which are applied to Arabian agriculture. In this context, both the traditional and innovative techniques of water delivery are reflected. The overview of the professional literature and the evidence-based studies provides a link between the climate conditions and agricultural needs, which exist in UAE. Thus, the study assists in verifying the advantages and disadvantages of the current water management methods as well as points out the most optimal technique of water delivery treatment, which may be used in the country so that to avoid the resource shortages.

The design of the work constitutes a logical organization of a qualitative research analysis. First, the literature, which serves as a background for the suggestions, is estimated. Second, the general account of the functioning irrigation systems is provided. Third, the supremacy and effectiveness of the drip irrigation technology is approved and justifies as well as some practical illustrations of the efficacy are emphasized. Finally, the recommendations and suggestions as to the further use of the system are specified.

Methodology

The qualitative research employs the method of data analysis. Thus, the description of the basic irrigation systems, which are used in UAE, is sustained on the basis of five evidence-based studies. According to the data extraction results, the optimal irrigation technique is outlined.

Literature Review

The study paper refers to several academic sources as well as some media-based information, which reflect the relevance of the irrigation concern in UAE. Specifically, five peer-reviewed scientific articles and five web-sources are referenced in the work.

The scientific articles reflect the primary evidence, which certifies the efficiency of drop irrigation and its supremacy over the other technologies of water delivery. Thus, the article Soil solarization for weed management in UAE emphasizes the influence of the drip irrigation use on the quality of the cultivated crops. The work Subsurface drip irrigation of row crops introduces some data about the improved system of drip irrigation, which is based under the ground. The evidence-based articles Impact of land disposal of reject brine from desalination plants on soil and groundwater by Mohamed, Maraqa, and Handhaly, Water problem in the UAE mountain areas by Qaydi, and Review future concerns on irrigation requirements of date palm tree in United Arab Emirates by Shahin and Salem provide a general background for the problem. In particular, these studies explain the reasoning of spray irrigation inefficiency as well as underline the principles of farming and climate conditions, which stimulate water scarcity in UAE.

The web resources illustrate the directions for irrigation systems construction. For instance, the reports under the names Drip irrigation design guidelines and Drip irrigation system  components and their function offer an overview of the specifications of drip irrigation pipes usage. The information promotes understanding of the basic advantages of the water delivery facility.

The media releases provide a general understanding of the water management solutions that exist in the Arab world today, which helps to figure out what the primary concerns of water delivery are. The web articles Water profile of United Arab Emirates by Matlock Water management in UAE by Dakkak present a picture of climate environment, which ensures water shortage. The media release Desalination threat to the growing Gulf by Todorova presents information about the threat to the natural water reservoirs in UAE.

Therefore, the cited works provide a solid background for the research design for they reflect the major implications of water management in the Arab world as well as help in focusing on the problem of irrigation.

The Systems of Irrigation in UAE

The methods of delivering water to the Arabian plantations and fields differ in their technology parameters and the specifications of usage. The primary techniques of irrigation include the traditional spray irrigation and the innovative drip irrigation.

The designation of the so-called sprinkler or spray irrigation follows the pattern of the natural water delivery. Thus, it represents a complex system of pipes, which help to distribute water throughout the ground. Ordinarily, the technology of spray irrigation is suitable only for the resistant crops such as tree cultures. However, the experts suggest that the type of water delivery may damage the crops, which are small in size and have a delicate structure. The type of soil is also critical when one selects the methods of irrigation. Thus, it is recommended to apply drip irrigation exclusively to sandy soils. Moreover, it is critical to choose soils, which have high infiltration rates so that the water did not damage the structure of the plants roots (Mohamed, Maraqa, & Handhaly, 2005).

The basic agricultural facilities usually give preference to sprinkler irrigation, for it possesses an extremely uncomplicated design and can be constructed easily and on a regular basis. Specifically, it is comprised of the sources of water pumps, sprinklers, and laterals. Usually, the systems are constructed in such a way so that the pipes remained in close proximity to each other. In this way, there directions overlap, which guarantees the identification of the target areas.

Despite their relative complexion simplicity, the systems of sprinkler irrigation possess specific shortcomings. First, the functioning of such technologies contributes to the consistent waste of the valuable resource. Thus, when the streams of water, which come from pipes, are focused on soil, there is a possibility of waste, for the managers can not control the specific allocations of water that fall on the separate areas. Thus, one may notice the streams of water between the rows, which evolve in the aftermath of irrigation. This tendency signifies that different types of plants need various allocations of water. Therefore, if the crop requires small irrigation, the amount of wastewater, which remains after its irrigation, seems considerable.

Except for water waste, the method of spray irrigation is inefficient in UAE, due to the climate conditions. It is well-known that the weather is quite hot in the Arab world. Therefore, since water is delivered to the plants in a condition of spray, it tends to evaporate quickly. As a result, in the course of sprinkler irrigation, approximately 40 % of water gets wasted.

The second method of providing agricultural crops with water is the underground irrigation. The system of such resource delivery was implemented as a complex web of pipes, which are installed in proximity from plantations or cultures of crops. An underground irrigation consists of pipes, the special preventers, which stop water flows from returning back. The implementation of the technology was quite undertaking in the old times, for the passages for pipes were dug by the specialists.

Today, however, a special pipe-pulling machine is employed. The primary advantage of the system is its susceptibility to regulation and measurement. Thus, the experts may regulate the amount of water, which is supplied through the pipes. Due to it, the crops receive the appropriate nutrition. Still, the method has its considerable flaws. For instance, there is a problem with installing the underground pipes in the mountainous areas, due to the harshness of soil and the scarcity of water reservoirs. In UAE, a huge number of farming centers are situated on the east coast, which is characterized by the mountainous infrastructure. Therefore, the use of the technology is irrational in the given environment (Qaydi, 2012).

Lately, the local and central water management institutions have overtaken the tendency of applying drip irrigation both on the big agricultural fields and household plantations. The system construction is based on the web of pipes with the special taps, through which water is directed straightly to the roots of the crops. The main elements of the system include filters, laterals, emitters, and drippers. The purpose of filtering installations is to provide the consistent cleansing of water. The purification may be conducted manually or automatically. Moreover, the drip irrigation facilities often include additional disk and gravel filters, which provide efficient cleansing of some inorganic materials. Laterals are the small pipes, which hold water before it is emitted into the soil. Finally, emitters and drippers are the automatic components, which sustain water flowing (Drip irrigation design guidelines, 2015).

The primary advantages of drip irrigation are their relative resistance to evaporation since the resources are not exposed to the hot air. Moreover, it is acknowledged that this specific type of water delivery maximizes the effectiveness of soil solarization. This tendency is predetermined by the fact that solarization materials are often damaged through the downward spray precipitation (Al-Masoom, Saghir, & Itani, 2003).

Recently, the innovative method of water delivery, which was called subsurface drip irrigation, was introduced in the United Arab Emirates. This system provides an improved model of water supplying for it can extract moisture even from the deepest parts of the ground. The practical evaluation of the methods functioning revealed that the application of subsurface drip irrigation contributes to the prevention of percolation as well as stimulated the crops growth (Ayars et al., 2000).

Drip Irrigation Installation: Recommendations

The system of drip irrigation provides a foundation for successful agriculture handling today. The practical evidence reveals that the application of the technology in the western regions of UAE increased the efficiency of crop cultivation to 80% in the last five years (Shahin & Salem, 2010). Therefore, the central authorities in the Arab countries have to embrace the method of drip irrigation on the state level so that to enhance the quality of water management.

Today, the government of UAE introduces the system of drip irrigation as the method, through which water is conserved. Still, the application of the technology in the area of farming is still not obligatory. Therefore, today, the organs of water management are responsible for imposing several rules, which regard the renovation of water delivery systems. The basic implementation initiatives include several issues. First, it may be suggested to provide the consistent training for farmers so that to stipulate the knowledge of drip irrigation systems. Moreover, it is critical to show them that the shortage of water delivery can impose some negative effects on the cultivation of crops. For instance, the workers of the agricultural sectors have to be acquainted with the statistic data of cultivation efficiency, which tests the amounts of yield crops that are received through the spray and underground irrigation as well as the amounts of plants that are grown as the follow-up of drip irrigation usage.

The complex comparison may reveal that the fruitfulness of the latter will be much higher than the percentage of sprinkler and underground irrigation results. Moreover, the farmers have to realize that the facilities of drip irrigation are, in fact, much easier I implementation, than their respective counterparts. Thus, they may be regulated from afar, and the systems do not need any preliminary measurements of moisture amount since they allocate water automatically. Second, the authority of UAE has to allocate subsidy for the installation of drip irrigation.

According to the estimations of the general system cost, it is acknowledged that the installation of the pipe-based facility is quite expensive. Thus, the pipes are usually produced of the water-proof aluminum, which is costly. Moreover, big plantations require a huge amount of the materials for every plant has to be grown in proximity to the source of moisture and the distance between them should not be bigger than one meter. Therefore, the independent financing of the irrigation renewal is impossible without the investments that might be allocated by the local and state governments. Finally, it is important to motivate the farmers to embrace the renovation by introducing the system of bonuses and privileges.

Conclusion: Estimating Irrigation Solution

Consequently, this work points out that the system of drip irrigation is the most consistent technology of water delivery, which may be applied in UAE. Due to its alignment with the climate conditions, the facility provides nutrition and optimal growth opportunities to the crops. The problem of the drip irrigation installation represents one of the most critical problems in the area of water management.

References

Al-Masoom, A., Saghir, A., & Itani, S. (2003). Soil solarization for weed management in UAE. Weed Technology, 7(2), 507-510.

Ayars, J., Phene, C., Hutmacher, R., Davis, K., Schoneman, R., & Voil, S. (2000). Subsurface drip irrigation of row crops: A review of 15 years of research at the water management research laboratory. Agricultural Water Management, 42(1), 1-27.

Dakkak, A. (2015). Water management in UAE . Web.

Drip irrigation design guidelines (2015). Web.

Drip irrigation system  components and their function (2012). Web.

Matlock, M. (2008). Water profile of United Arab Emirates. Web.

Mohamed, A., Maraqa, M., & Handhaly, J. (2005). Impact of land disposal of reject brine from desalination plants on soil and groundwater. Desalination and Environment, 182(1), 411-433.

Qaydi, S. (2012). Water problem in the UAE mountain areas: A case study on the east coast farming areas. Life Sciences & Engineering, 2(1), 1-13.

Shahin, S., & Salem, M. (2010). Review future concerns on irrigation requirements of date palm tree in United Arab Emirates: Call for quick actions. College of Food and Agriculture, 2 (6), 12-17.

Todorova, V. (2009), Desalination threat to the growing Gulf. Web.

Smart Water Grids and Water Sustainability

Background and History

Water is arguably the most important natural resource and it is indispensable to maintain life. This resource has been fundamental to the development of human civilisation. Human survival is dependent on the water since people need to drink adequate amounts of water or else they risk to die. In addition to direct human consumption, water is used by industries and to move human-generated waste. As such, water is necessary for the socio-economic development of the society. While humans have always needed water, the deep relationship between mankind and water started when the first permanent human settlements were built.

With the establishment of permanent settlements, humans took up agriculture to increase their food security. Early human settlements were located near freshwater supplies since no efficient water delivery systems had been developed at the time. Over time, humans realised that they needed to develop ways to move water from its source into urban areas. This would reduce the need for having to locate cities in close proximity to water supplies. The ancient Greeks were the first to develop elaborate water delivery systems. These Europeans implemented underground sanitation and water supply system that was able to deliver clean water to the cities while taking away the water produced waste from households. These advances were improved by the ancient Romans who developed aqueducts that supplied water from reservoirs to individual houses. These advances in water distribution contributed to the growth and prosperity of the Roman Empire. The Romans were able to experience social and economic development due to their water engineering projects. By building effective water supply infrastructures, the Roman society was able to thrive despite water scarcity in their geographic location.

No significant advances were made in the water supply systems until the Industrial revolution era of the 18th century. During this significant period in the history of human civilisation, great advances were made in technology. Innovative devices such as the water pump were created making it possible for large quantities of water to be moved to reservoirs and then distributed to the population. The availability of clean tap water contributed to the rapid growth of urban centres during the 19th and 20th century.

Goals and Objectives

For centuries, people assumed that the water resources were unlimited and therefore paid little attention to the water usage. Water is one of the most abundant natural resources, considering the fact that 70% of the Earths surface is covered in this substance. However, most of this water is saline and therefore unusable by humans. It is estimated that only 1% of the planets water reserves are fresh and readily available for human use. This shows that, contrary to common perceptions, water is a scarce resource. Humans must look for ways to improve water use and bring about sustainability. Hodson (2014) admits that a major problem with water sustainability is that this resource is provided cheaply in most developed nations. Due to the low cost of the resource, people lack an economic incentive to control its usage. The government cannot implement a significant increase in the cost of water since the citizens consider the availability of cheap clean water a human right. Technological solutions, therefore, present the best opportunity to improve water use.

Increasing human population and the growth of the industrial sector have intensified pressure on global water resources. The pressure has been exacerbated by the burgeoning of urban settlements all over the world. OShea, Aldridge and Steigerwald (2012) document that urban settlements have increased both in size and number over the past century. While only 20% of people in the developed world lived in urban settlements by the beginning of the 20th century, half of the human population dwells in urban areas today. Mutchek (2014) asserts that urban water systems face sustainability and resiliency challenges and solutions are needed to ensure water security for the urban population.

It can be expected that this pressure will only increase as the human population in cities continues to grow all over the world, therefore increasing the pressure on the already constrained water resources. Without a feasible solution, modern cities will soon suffer from catastrophic water shortages. Inadequate water supplies will damage the socioeconomic development of countries since adequate supplies of clean water are the drivers of modern development.

Policymakers are looking for ways to increase the water supply or decrease consumption in order to ensure water sustainability. One area that should be given attention is the water distribution system. Significant losses occur as the water is being delivered to the consumers. This paper sets out to demonstrate how improved technology has contributed to water sustainability. It will specifically focus on water-smart grid technologies, which comprise of a number of technological solutions working together to facilitate the intelligent management of water resources. The paper will show how smart water grid technology can help bring about sustainability by reducing the amount of water lost during transmission.

Literature Review

A number of authors have addressed the issue of how smart water grids can be used to improve the use and sustainability of water resources. Mutchek and Williams (2014) review the technology elements of smart water grids. They highlight how these systems can be implemented and discuss the potential sustainability and resiliency benefits of using smart water systems. The authors also look at the barriers to the adoption of these technologies in most cities. A number of new water technologies have been invented and implemented to improve water use and promote sustainability. Henley (2013) reviews some of these solutions including smart monitoring which reduces wastage. The article quantifies the waste that currently occurs during water transmission and shows how technology can help mitigate losses. While ICT has been employed in many sectors, its implementation in the water sector is still in its elementary phase. Hajebi, Song, Barrett, Aidan and Siobhan (2012) propose the development of a reference model that can be used to ensure widespread use of ICT infrastructure in water distribution. Such a model would make it possible for more cities to exploit ICT advances in water management. In the same vein, Moon-Hyun (2014) proposes the development of legally-grounded smart water grid policies by advanced countries.

Before new technologies can be implemented, pilot studies are required to demonstrate how this technology works and its potential benefits and limitations. Iseley and Hromadka (2013) discuss the pilot project to implement a smart water solution in an urban neighbourhood in Indianapolis. The project is meant to test the impacts of a new smart water grid system patented by the Global Water Technologies Company. The paper shows how smart grid systems can be used to increase distribution efficiency by using collected data to determine when water pressure can be reduced in reaction to reduced demand. The article by Hodson (2014) studies the implementation of a smart water grid solution in Singapore. The sensor technology employed enables water distributors to identify leaks through the whole mains network. The article demonstrates how using smart water grids leads to water saving.

The current water shortages are the result of increased urbanisation efforts all over the world. OShea, Aldridge and Steigerwald (2012) discuss the urbanisation phenomenon and the impact it is having on water resources. They note that increased urbanisation is putting a strain on water resources and the only way to deal with this is through smart city architecture. Part of the smart city infrastructure is a smart water grid that is composed of sensors for managing the water. South Korea is establishing itself as a global leader in water technology. Due to government efforts, the country has implemented a number of technological solutions to bring about water sustainability. Yewon (2014) discusses the countrys technology-oriented solution to the water issues faced by Korean cities. The author discusses intelligent water management systems implemented by the countries in various cities with significant success.

Analysis and Recommendations

Using smart water grid technologies will have significant impacts on the use of water. Significant quantities of water are lost during distribution. In the United State, approximately 30% of water is lost through leakage while the figure is between 10 and 20% in the UAE (Abu Dhabi Urban Planning Council, 2010). Most of these losses occur since the water supply infrastructure is old. Iseley and Hromadka (2013) explain that the water infrastructure in most countries is many decades old. Many municipal authorities do not feel compelled to replace the ageing infrastructure with modern infrastructure for such a project would be very costly. In addition to this, many policymakers feel that as long as the old water systems are able to deliver water to the destination, there is no need to replace them. However, the ageing and crumbling infrastructure are responsible for the numerous leaks that lead to high losses of water during the distribution process. Without smart grid technology, most cities only identify water leaks in their underground pipes when the pipes fail completely. As long as the losses are modest, they might go on for years undetected. With growing water shortages, cities cannot afford to lose their precious water through pipe leaks.

Smart water technologies can also impact water use by providing greater control over the resource. Smart water technologies can help countries with limited water resources to measure their water consumption and implemented consumption reductions. The reality is that freshwater is not distributed uniformly and while some countries enjoy abundant freshwater resources others, such as the United Arabs Emirates, suffer from acute water shortages. In countries where water scarcity is a reality, the alter distribution network needs to be effectively monitored. The Abu Dhabi Urban Planning Council (2010) notes that smart monitoring technology helps to track the movement of water through the entire distribution system. Through a well-developed monitoring system, a better understanding of the consumption patterns of industrial users and individual households can be acquired.

The first major benefit of smart water grids is that they have led to decreased losses of water through the leakage. Since the systems monitor the pipes and provide real-time data on the water flow, leaks can be identified as soon as they occur. Maintenance units can then be sent to fix the problem within minutes. This leads to a dramatic reduction in water wastage. Water resources are therefore used more productively as a result of this system. In addition to providing fast leak detection, smart water grids improve the efficiency of the current water supply system. OShea, et al. (2012) explain that the technology can be used to implement demand-driven distribution which leads to less stress on old pipes, therefore, increasing their lifespan.

Smart water grid systems have already shown great benefits in terms of water use and sustainability. To begin with, the technology has made it possible for the current static water resources to adequately cope with growing demand (Water Innovations Alliance 2014). The past few decades have witnessed significant increases in water demands. These demands have especially been evident in urban settlements where the population has increased dramatically. Through smart water grids, water resources can be distributed in the most efficient manner. Since there are limited losses in transit, water supplies are able to keep up with the growing demand.

Conclusion

The water resources available to humans are facing significant pressure from increased consumption levels. This paper has set out to demonstrate how smart water grids can help promote water sustainability. It began by showing that modern society could no longer afford to view freshwater as an infinite resource. Instead, people should engender the perception of water as a finite resource which consumption must be effectively managed to ensure sustainability. The various merits of using smart water grids have been highlighted. However, a large scale adoption of these systems has not yet been realised in most cities. In most cases, local authorities cite the lack of adequate funding as the reason for not implementing this technology. Considering the growing water demands of our cities, all development minded citizens should call for the implementation of smart water grids since no price is too high for achieving water security.

References

Abu Dhabi Urban Planning Council, 2010, Sustainable Water Management: Assessment and Recommendations for the Emirate of Abu Dhabi, Columbia University Press, NY.

Hajebi, S Song, H Barrett, S Aidan, C & Siobhan, C 2012, Towards a reference Model for Water Smart Grid, International Journal of Advances in Engineering Science and Technology, vol. 2, no. 4, pp.310-317.

Henley, W 2013, . Web.

Hodson, H 2014, Super-smart grid spies out leaks, New Scientist, vol. 224, no. 29, pp. 20-22.

Iseley, T & Hromadka, E 2013, Indianapolis smart water grid pilot project demonstrates local solution to national sustainable infrastructure problem, Global Water Technologies, Indianapolis.

Moon-Hyun, K 2014, A study on a legal framework of Smart Water Grid, International Journal of Control and Automation, vol. 7, no. 12, pp. 91-100.

Mutchek, M & Williams, E 2014, Moving Towards Sustainable and Resilient Smart Water Grids, Challenges, vol. 5, no. 1, pp. 123-137.

OShea, T Aldridge, T & Steigerwald, B 2012, Advances in Sensor Technology to Improve Individual Contributions to Sustainability, Intel Technology Journal, vol. 16, no. 3, pp. 38-55.

Water Innovations Alliance 2014, The Water Smart Grid Initiative. Web.

Yewon, C 2014, Koreas Smart Water Grid and hybrid desalination technology. Web.

Integrated Sustainable Water Management in the UAE

Executive Summary

In the last three decades, the United Arab Emirates (UAE) has experienced rapid urbanization due to steady economic growth. The expansion of the economy is accompanied by a sharp rise in population, which has put pressure on its water resources. At present, the government has put in place strategies to reduce the population pressure on its scarce water sources by developing a system for managing the supply and demand sides for its resources. This research study aimed at examining the current water management approach and challenges through qualitative and quantitative analysis.

Qualitative data was collected through a structured interview consist of nine respondents drawn from the management level of different UAE water institutions. Quantitative data was derived from official reports from reputable water authorities such as DSC, FEWA, SEWA, ADWEA, and DEWA. The findings indicated a rapid rise in water consumption for the period of analysis, that is, 2005 to 2015 in all sectors. The study relied on the OECD principles of efficiency, engagement, and effectiveness to suggest improvements in water governance. Among the notable suggestions include the integration of technology in production and supply, building public awareness, improving legislative framework on green building code, and collecting non-revenue water among others.

Introduction

The UAE is a federation that occupies an area of about 83,600 km2. The UAE is made up of Abu Dhabi, Dubai, Sharjah, Ajman, Ras Al Khaimah, Fujairah, and Umm Al Quwain Emirates. These Emirates have an expansive coastline of 1318 kilometers where most of the non-conventional and conventional water resources are located. Over the years, urbanization has increased the population pressure and demand for water. At present, more than 70% of the UAE population lives in urban areas (Merabtene, Siddique, & Shanableh, 2016). Specifically, 65% of this population occupies a stretch of 5km coastline. The UAE Water Security Strategy 2036 was unveiled by the Ministry of Energy in 2017 to ensure that access to water during an emergency and normal conditions are sustainable within the internal standards, local regulations, and the nations vision of prosperity.

This strategy has frameworks for reducing demand for different water resources by up to 21% and expand the productivity index of water to $110 per cubic meter. The plan also intends to lower the water scarcity index by three degrees and increase the reuse of treated water by 95% (Lubega & Farid, 2014a). The UAE relies on conventional and non-conventional water resources to meet the ever-rising demand for usable water. Among the notable conventional water, sources are groundwater, falajes, springs, ad seasonal floods. Non-conventional water resources are treated with sewage and desalinated water. The current conventional water resources in the UAE include 3 Mm3/yr from several permanent springs, 20 Mm3/yr from fall discharges, 22 Mm3/yr from seasonal springs, and 109 Mm3/yr from aquifer recharge (Dakkak, 2015). The non-conventional resources are 150 Mm3/yr from reclaimed water and 475 Mm3/yr from desalinated water (Madden, Lewis, & Davis, 2013).

It is projected that future robust development in the UAE might increase the seasonal springs and fall discharges to 40 Mm3/yr (Lubega & Farid, 2014a). The Emirates has an arid climate with lower than 100 mm/year f rainfall, low groundwater recharge rate of less than 4% of the water used annually, high rate of evaporation estimated at 2-3 m/year, and limited reliable surface water (Merabtene et al., 2016). The UAE is a downstream water user sharing her trans-boundary water sources with Oman and Saudi Arabia (Meldrum, Nettles-Anderson, Heath, & Macknick, 2013). The sharp population increase and rapid economic development over the last two decades have resulted in expanded reliance on the primary unconventional water sources such as desalination (Alawar, 2014). The increasing demand has led to the development and expansion of alternative conventional supply measures for water resources such as storage dams, recharge dams, as well as recharge wells (Dakkak, 2015).

At present, groundwater is the primary conventional water source in the seven Emirates. This resource constitutes 80% of all the freshwater supply per year. Other sources of fresh water for the seven Emirates are wastewater re-use at 3% and desalination plants at 17%. The consumption of water in the UAE is for amenity, forestry, agricultural, commercial, industrial, and domestic purposes. At present, the largest water user is within the agricultural sector at 58% annually (Merabtene et al., 2016). The industrial, domestic, and commercial water usage stands at 17%. The estimation of groundwater share is done by the government agencies on the basis of demand and availability of the desalination plant production. This means that the sustainable yield of UAEs groundwater aquifer is dependent on the duration it takes for such aquifer to replenish. However, the ever-rising demand for water in the seven Emirates has put intense pressure on scarce water resources and is currently threatening the quality of production and supply. Thus, it will be essential to effectively estimate the rate of replenishment of water resources in order to create a proactive management strategy for this national resource (Madden et al., 2013).

Since the study is focused on the entire UAE, recharge rate estimations will be linked to recent national practices of using desalinated water for agricultural purposes. This practice was necessitated by the governments hindrance policy for use of groundwater for irrigation in order to recover overexploited storage. Moreover, the hesitancy of individual water users to continuously carry out irrigation using treated water raised a lot of social concerns (Kraft, 2013). As a result, any surplus of treated wastewater is, hence, dumped in desert lagoons imposing additional input to the groundwater storage (Lubega & Farid, 2014b, p. 7). These factors catalyze the immense usage of desalinated water in the UAE irrigation fields, which eventually replenishes the grounder as a source of aquifer input.

The shifting water resources use and production in the last ten years has resulted in substantial fluctuations in the UAE water table to the extent that groundwater level has surprisingly risen considerably in some areas in Al-Ain (Government.ae, 2018. para. 7). The rise in the water table is also associated with other factors such as increasing need for landscaping and farm areas to meet the rapid urbanization needs. Over time, it is estimated that the even grounding urbanization in the UAE might have an effect on the countrys hydrological cycle and lead to variations in groundwater discharge and recharge rates (PJM-ISO, 2013). As a result, there are immense threats looming in the UAE water management such as deterioration of road infrastructure, flooding of houses, damage to construction project foundations, land subsidence, and other long-term environmental degradations associated with contamination of groundwater and soil (Merabtene et al., 2016). This study will review the current situation in integrated sustainable water resources management in order to suggest an ideal approach for addressing any challenges identified.

Background of the Research

The World Economic Forum has identified water security as an evitable resource for sustainable development in a country or region. According to Lubega and Farid (2014a), water security is the ability of a population to safeguard its access to adequate quantities of acceptable useable water for sustaining livelihoods, population well-being, and socio-economic development (p. 8). Moreover, water security addresses the aspect of the integration of a resource management system within an ecosystem for long term benefits (Meldrum et al., 2013). As a segment of water sustainability planning, the UAE government has put in place several strategies to guarantee water security. Since the Arab regions climate is arid, water resources that are portable have become a concern to the UAE government and other members of the GCC (Luomi, 2014). Specifically, the World Bank estimates that the seven Emirates and other Arab countries will become drier in the next few decades besides increased population growth against constant sources of water supply (World Bank, 2016). Moreover, rapid development as the UAE becomes urbanized has increased water consumption, especially for non-oil based firms (PJM-ISO, 2013). This means that the seven Emirates should come up with a strategic plan for addressing the consumption and climate challenges in order to create a sustainable and effective water management system.

Integrated Water Resources Management (IWRM) is a complex concept that has received a lot of attention as a significant instrument for improving the operational framework for existing water resources systems in the UAE (Dakkak, 2015). Despite the fact that this concept has been in existence for close to a century, its effective implementation is laden with challenges associated with the inherent and complex nature of water management systems (Merabtene et al., 2016). Specifically, these systems integrate the scientific, technical social, economic, and political considerations to create a universally acceptable water resources management approach. Specifically, in order to reach a robust integration among all these elements, the management strategy mist be multi-disciplinary to account for all these aspects related to the water system under consideration (Lubega & Farid, 2014b, p. 9).

In this study, the water budget will be used as a tool for describing the hydrologic cycle by summing water resource inputs and outputs of the study area over a specific duration. Since any hydrological cycle is controlled by the mass conservation law, the study will establish if there has been a rise or fall in the water table depending on the variations between the total water outputs and inputs from the current system. Specifically, in the event that the results indicate that the water inputs are less than outputs, the researcher will conclude that there is a decline in the water table and vice versa (Santhosh, Farid, & Youcef-Toumi, 2013). In this study, the components of the water budget that will be examined include inputs such as runoff, precipitation, surface water inflow, groundwater inflow, and diversions (Madden et al., 2013). On the other hand, the output components include water diversions, residential uses, industrial uses, irrigation surface water outflow, groundwater outflow, transpiration, and evaporation.

The UAE is over-dependent on groundwater to sustain the demand for different uses. Over the years, the consumption rate has exceeded the natural recharge leading to an imbalance between outputs and inputs of water in the current system (Lubega, Santhosh, Farid, & Youcef-Toumi, 2014). As a result, groundwater and seawater have deteriorated. Although desalination plants have been set up by the government to take care of any shortfall in the existing conventional water resources, the demand is growing faster than the supply. Specifically, the groundwater resources depletion and even rising demand for water in the UAE has increased pressure on the seven Emirates to create an integrated sustainable water resources management. The current shortages have threatened development sustainability and placed the UAE in the list of countries that are poor in terms of availability of water resources (Mansour, 2017). This research dissertation discusses water resources in the seven Emirates in terms of how the resources are managed, exploited, and future sustainability strategies (Dakkak, 2015). Specifically, the study is focused on understanding the existing challenges in water security governance in the UAE and steps that might be implemented to curb these setbacks in order to sustain water resources management.

Research Problem Statement (Research Questions)

It is imperative for the policymakers and the UAE government to create sustainable strategies for managing its water resources that meet the demand and present and in the future. A proactive management approach for the limited water resources in the UAE requires the creation of awareness in terms of water resource security from which strategic policies are created to continuously guarantee the quality and quantity of available water for consumption (Kraft, 2013). In the UAE context, consumption of water is rising at an alarming rate (Merabtene et al., 2016). Specifically, in the last thirty years, consumption has almost tripled. It is imperative to examine the current policies in place by the government to secure usage, availability, and storage of water resources in addition to how the increasing demand impacts associated costs and availability of different water sources. Moreover, it is necessary to examine the climate and environmental factors in terms of how they influence different water resources within the seven Emirates. This study is designed to establish policy solutions for an effective and integrated water resource management system that guarantees the quality and quantity of available water in the UAE for short and long term sustainability. Therefore, the research questions are:

  1. What policies are in place to secure the usability, availability, and distribution of water resources in the UAE?
  2. What climate and environmental factors influence different water resource availability within the seven Emirates?
  3. What policy solutions should be put in place for an effective and integrated water resource management system that guarantees the quality and quantity of available water in the UAE?

Significance of the Study

The significance of this study is a comprehensive examination of water supply and availability in the seven Emirates in order to comprehend the challenges faced by the UAE government in effectively maintaining a stable, secure, and quality water supply for the population and industries. The proposed research will also attempt to explore quantifiable solutions for possible challenges in water resources management at present and in the future as a result of the ever-increasing demand levels, pollution, and climate changes.

Research Aims and Objectives

Since the proposed research aim at examining the integrated sustainable water resources management in the UAE, several research objectives were created to address the above research questions. Specifically, the research objectives are;

  1. To establish the current system of water security management within the UAE
  2. To identify the current and future challenges in the integrated sustainable water resources management from a risk perspective
  3. To discuss the existing policies by the UAE government aimed at addressing water security in the seven Emirates
  4. To recommend improvements that the UAE government might adopt to create an effective integrated sustainable water resources management system

Research Assumptions and Limitations

Since limited research has been carried out to establish the effectiveness of the current water resources management in the UAE, the proposed study may not give an accurate picture since it relies on available data that might not be updated. This means that the findings of this research may only present best practices from other regions that might not be effectively integrated within the UAE scenario. Thus, the UAE government or any other relevant agency within the expansive water resource management field might find the study complex, especially when the proposed recommendations are poorly integrated into the current water resources management system (Lubega et al., 2014). The UAE government or any other agency will have to associate the current and future projections highlighted in the study to establish an appropriate and systematic water management approach for sustainable consumption.

Thesis Organization

Week 1: Research Commencement

This stage of the research study involves a proactive analysis of different research topics from which the researcher has to pick one topic and define the rationale for the choice. In this case, the researcher chose the topic of Integrated Sustainable Water Resources Management in the UAE because there is a lot of literature besides being relevant to the research on sustainable water consumption for effective resource governance and security. This stage took approximately one week to accomplish.

Week 2 & 3: Choosing the case study

Choosing the case study regions within the seven Emirates is expected to be challenging, considering the fact that the researcher is targeting all the regions within the UAE, that is, coastline and the mainland. The researcher will have to decide on the most appropriate research approach. Moreover, the researcher has to choose relevant research variables to ensure that the scope of the study is well addressed. It is estimated that this part of the research will take at least two weeks to accomplish.

Week 4 & 5: Background research

Since the topic has several past literature materials, the researcher will not have many challenges in creating the research background. The role of the researcher at this stage will be to merge different literature materials to the research topic to determine the direction to follow during the actual research. It is estimated that it will take at most two weeks to accomplish this part.

Week 6, 7, & 8: Conducting the literature review

This stage will be the most demanding, considering the fact that the researcher will have to carry out empirical and theoretical literature. The researcher will then relate the existing literature to the case study topic. Among the sources of information that the researcher will explore are academic journals, course notes, reports on the UAE water resources management system, and books.

Week 9, 10, & 11: Conducting interviews, collecting data, and analyzing data

This stage will also be very demanding since the researcher will have to balance different tools for carrying out surveys such as questionnaires and direct interviews to present sensible findings of the topic. The research will have to scrutinize data collected to ensure that the analysis makes scientific sense by adhering to ethical principles of carrying out social research. The research will also have to design the research questions and test them for comprehensiveness and relevance. The researcher will have to apply different data analysis tools to make sense of the raw data collected. At the stage, the researcher will ensure that proper coding and transcription is done to achieve desirable results. This stage will take the longest time, probably three weeks since primary research and data analysis are time-consuming.

Week 12 & 13: Research conclusion

After the analysis stage, the researcher will identify the themes that have emerged to offer an appropriate interpretation of the findings. The researcher will have to compile the outcome of the study and determine whether the research hypothesis has been proven or not. This section will also involve the submission of different attachments related to the research. This stage will be completed within two weeks (see chart 1).

Research timeline.
Chart 1. Research timeline. (Source: Self-generated).

Summary

In summary, chapter one has developed a research background, research objective, rationale, questions, and justification. These concepts will guide the section of the case study in establishing integrated sustainable water resources management in the UAE.

Literature Review

Introduction (Search Description/Conceptual Framework)

This section of the research study will review the scholarly publications and documents related to the thesis topic: integrated sustainable water resources management system in the UAE. The notable areas integrated into the literature review include water resource management, sources of water in the UAE, current challenges, and regional water usage breakdown index among others.

The conceptual framework is angled on the current water management system in the UAE as related to current challenges, government policies, and necessary improvements to expand on the aspect of integrated sustainability in the water management approach (Lubega et al., 2014). As discussed in the first chapter, the UAE government has combined processes, mechanisms, and institutions to exercise administrative, economic, and social control over the available water reprocess. The terms water resources governance will be used to denote a management approach or system in place to develop and control water infrastructure in the UAE from production, supply, and rejuvenation of the sources (Merabtene et al., 2016). The conceptual framework is drawn from good water resources management through the integration of two ideal water governance models by the OECD and USAID (see table 1 and figure 1). The OECD principles were used to review the evidence related to the UAE integrated water resources management system.

OECD water management principles.
Figure 1. OECD water management principles. (Source: Alawar, 2014).

Table 1. Conceptual framework modeled from the USAID and OECD water governance approaches. (Source: OECD, 2015).

USAID water governance framework OECD Water governance framework
Description Founded by the government of the United States of America, the USAID has a comprehensive framework for managing water resources in a sustainable manner. Abbreviated as OECD, the Organization for Economic Co-operation and Development provide ideal principles of water governance for its members
Application The USAID water governance framework functions on five factors of participation, transparency, rule of law, integrity/accountability, and responsiveness The OECD water governance framework functions on principles of effectiveness, trust, and engagement, and efficiency
The USAID model operates on the functions of building water sector capacity, strategic planning, allocation of water resources, and regulating the usage. Through an integrated water governance cycle, the OECD water management principles are managed through four stages, which are the formulation of policies and strategies, implementation, monitoring, and evaluation (Odhiambo, 2017, p. 2478).

Based on the OECD principles, the analysis and recommendation in the proposed research will integrate the variables of effectiveness, efficiency, and engagement or trust (Morillo et al., 2014). As part of the conceptual framework, the variable of effectiveness will be used to evaluate the policies and processes defining sustainable water resources management policies against set targets over a period of time in the UAE (Al-Otaibi, El-Sadek, & Al-Zubari, 2013). This variable will integrate the sub-principles of role and responsibility setting, the inclusive scale for managing water resources, policy coherence within the player sectors, and capacity adaptability (OECD, 2016).

The second variable of efficiency will be used to examine the benefits of effective governance in a sustainable management approach to the current water system. The research will also examine the current strategies put in place in the UAE to maximize sustainable water management benefits at low cost under the sub-principles of producing and sharing data and information, mobilizing and allocating water finances efficiently, effective implementation of regulatory frameworks, and promoting innovative practices (OECD, 2015, p. 11). The last variable to be considered within the proposed conceptual framework is engagement or trust to examine how the relevant water management authorities build public confidence and promote inclusiveness among stakeholders (Santhosh et al., 2013). This variable will be examined using the OECDs sub-principles of mainstreaming integrity and transparency practices, promoting stakeholder engagement, encouraging water governance frameworks and promoting monitoring and evaluation of water policy and governance (OECD, 2015, p. 12).

Global Water Resources and Sustainability

Over the years, concerns for sustainable water resources across the globe have increased as governments and other international bodies put in place policies for effective management systems. The leading policymakers for global water resources sustainability are the United Nations and the World Bank (Meldrum et al., 2013). These institutions have classified each region across the globe as either having adequate water supply or at a threat of unsustainable water resources. Global water resources sustainability integrates administrative, political, and economic authority to proactively manage different sources and effectively supply them for consumption in an environmentally friendly manner (Lubega & Farid, 2014a). It involves a holistic combination of processes, mechanisms, and institutions of governance to have full control of how water is produced, supplied, consumed, and sustained (Mansour, 2017).

This means that water resources governance at the global level combines a series of elements such as statutes, including policy mandates; administrative rules and guidelines; and institutionalized rules and norms (Alawar, 2014, p. 25). Water resources governance across the globe is not limited to individual government interventions, but a collection of policies managed with obligations of private and public organization partnerships. According to Santhosh, Farid, and Youcef-Toumi (2014), an effective water resources governance is important for guaranteeing a balanced mix in the social, economic, and environmental outcomes of any integrated water management system (see figure 2). Good resource governance is instrumental in producing effective and sustainable outcomes (Svendsen, 2014).

For instance, an effective water resources management approach should integrate accountability, inclusiveness, transparency, participation, responsiveness, and predictability for the system to serve its purpose in the short and long term (Odhiambo, 2017). According to Alawar (2014), water governance is the range of political, social, economic, and administrative systems that are in place to develop and manage water resources, and delivery of water services, at different levels of society (p. 25). At the global level, water resources and sustainability are organized into formulated and well-developed policies with a primary objective of sustaining any development of any water management system. Implementation of these policies involves primary stakeholders and actors for the process to remain effective (Santhosh et al., 2013). In relation to the proposed study, the research intends to integrate the water governance principles of the United Nations, World Bank, and Organization for Economic Co-operation and Development (OECD) to review the current situation in the UAE from the perspective of integrated sustainable water resources governance.

Sustainable water resources management priority indicators.
Figure 2. Sustainable water resources management priority indicators. (Source: Meldrum et al., 2013).

Water Resource Management

The United Nations Development Programs report of 2013 on water resources in the Arab region notes that a myriad of factors is associated with restricted progress in water governance such as unclear and overlapping responsibilities, inefficient institutions, insufficient funding, centralized decision-making, limited public awareness, and ineffective regulations and enforcement (UNDP, 2013, p. 1). Siddiqi and Weck (2013) conceptualized effective water resources governance as putting in place social learning and adaptive governance systems that are adequate for managing the social-ecological in the event of an abrupt change. For instance, recent changes in the global weather patterns have openly highlighted the weaknesses and challenges in the present water resources management systems.

Moreover, the lack of an effective and multiagency water resources governance approach across the globe has magnified these challenges in the backdrop of an existing scarcity concern (Santhosh et al., 2014). Therefore, it is critical to comprehend the significance of sustainable water resources governance in the events of global climatic variations as well as scarcity concerns in the Arab regions such as the UAE (Svendsen, 2014). According to Dakkak (2015), in order to effectively alter the existing water resources governance, governments of the day should incorporate societal and social learning in any management system. Specifically, social learning ensures that government bodies, interested parties, and the general public are brought on board before a major policy is implemented (Mansour, 2017). For instance, social learning needs might be hampered when the management of water resources is contracted to a private institution (Al-Otaibi et al., 2013).

Water resources management is incomplete when the aspect of water security is not addressed. According to Al-Otaibi et al. (2013), water security is dependent on the global climatic change, availability of natural water resources, and socio-economic scenario (p. 89). A combination of these factors facilitates the actions of any institution mandated with the responsibility of managing an integrated water resources system (Santhosh et al., 2013). Water security or management can be achieved through a systematic decrease is predictable and non-predictable negative impacts while increasing positive actions within the current and future socio-economic development initiatives of a region (Susskind & Zaerpoor, 2017).

Water resources management is dependent on the political goodwill of a region and its availability. Within the Arab region, water security and management have been a major concern for the last four decades in nations such as Egypt, the UAE, Syria, and Iraq among others (Siddiqi & Weck, 2013). These regions have experienced a myriad of water resources security challenges due to inadequate quality and quantity of water, which affected their capacity to meet their development plans and resulted in social unrest (Al-Otaibi et al., 2013, p. 24). In the GCC bloc, there is a general high dependency on a single water resource that is shared among the members, which sometimes becomes the reason for conflict (Al-Otaibi et al., 2013, p. 28). The sustainability and availability dimensions of water resources management examine the security of a steady supply of water for consumption. In the GCC bloc, most of the water supply originated from desalination plants (GCC, 2015). Guaranteeing effective water resources management would ensure that reservoirs are adequate to fill any supply gap in the event of insufficient water resources from desalinated plants for a prolonged period of time. According to Al-Otaibi et al. (2013), water resources management is a multidimensional concept that recognizes that sufficient good quality is needed for social, economic and cultural uses while, at the same time, adequate water is required to sustain and enhance important ecosystem functions (p. 29).

The primary themes associated with water resources management are availability or quantity, vulnerability or hazards, human needs, and sustainability. The theme of availability is associated with water management assessment indices on water shortages and stress. Evaluations measure the level of water stress as a ratio of water availability and use against the estimated impacts of demand-driven scarcity. The second index examines water shortage or crowding by quantifying the number of persons sharing a unit of a water resource (Siddiqi & Weck, 2013). This means that sufficient water supply is the ideal unit for measuring water security (Madden et al., 2013). The second theme of vulnerability or hazard is discussed by UNESCO as advocacy for systems and infrastructure involving the protection of water resources from drought, flooding, and other related hazards (Santhosh et al., 2013).

This theme also addresses the concerns of water contamination as a result of human factors such as terrorism in the current volatile political climate in the Arab region. As part of water resources management under this theme, engineers are mandated with the task of using ordnances, guards, and gates to create a secure water infrastructure (Svendsen, 2014). The theme of human needs covers human development, food security, and access concerns (Odhiambo, 2017). Thus, an ideal human needs theme is a condition occurring when the required quality and quantity of water supplied is efficient, affordable, and meet the long and short term needs (Susskind & Zaerpoor, 2017).

The United Nations Development Program report has summed these needs as any aspect of human development pertaining to the management and use of water resources. This theme also proposes integral safeguarding of water and human security as part of the ecosystem for sustainable balance (Santhosh et al., 2014). The last theme is defined by Alawar (2014) as water security at any level from the household to the global arena means that every person has access to enough safe water, at affordable cost, to lead a clean, healthy and productive life, while ensuring that the natural environment is protected and enhanced (p. 26). To effectively address this theme, it is important to examine the variables of protecting the ecosystem, secure food supply, basic needs, risk management, and wise water valuation or governance.

Main Water Sources in the UAE

Water resources in the UAE are categorized into conventional and non-conventional sources. Conventional sources are dependent on rain volume and include falajes, groundwater, flash floods, and springs. Non-conventional sources comprise of treated wastewater and desalinated water. Previously, the UAE depended heavily on conventional sources but other alternatives such as non-conventional desalinated water have been added to the supply grid (see charts 2 and 3).

Water sources in the UAE.
Chart 2: Water sources in the UAE. (Source: Self-generated).
Water production per source.
Chart 3: Water production per source. (Source: Meldrum et al., 2013).

The surface runoff source is a conventional water resource with temporary and limited availability due to high evaporation and low rainfall rates. The estimated surface source in the UAE is 0.15 billion m3 per year. The government has constructed 114 dams with a capacity of 31152 million gallons across the seven Emirates to collect and protect flooded water, which is then used to recharge groundwater. In the next 20 years, the Ministry of Environment and Water has plans in place to build 68 more dams to hold 26400 million gallons. There are several springs in the UAE such as Khatt, Maddab, and Bu Sukhanah among others that are also conventional sources. Until ten years ago, falajes were the primary arteries of water sources in the eastern region of the UAE. However, many of these falajes are now dry due to prolonged drought and excessive pumping of groundwater (Santhosh et al., 2014).

The main conventional water source in the UAE is groundwater that is produced by SEWA. Some of the notable groundwater aquifers are the limestone aquifers in the north and east, fractured ophiolite rocks in the east, the gravel aquifers flanking the eastern mountains from the east and west and the sand dune aquifers in the south and west (United Nations, 2013, p. 29). At present, the largest fresh groundwater reservoir in the UAE is located in piedmont plains alluvial deposits within the eastern mountains called the eastern and western gravel aquifers. However, the increasing pumping activities have affected groundwater in several locations due to salt-water intrusion. Since most of the groundwater salinities high to low brackish, their use is limited to agriculture (Lubega et al., 2014).

Hydrochemistry of groundwater source varies and consist of calcium bicarbonate, sodium chloride, and magnesium sulfate among others (Al-Otaibi et al., 2013). Over the years, the estimated total annual groundwater production has gradually decreased from 35557.25 million gallons in 2000 to 20033.93 in 2015 (Government.ae, 2018). SEWA produced 9907 million of groundwater in 2000, but the production dropped to 9407.3 million gallons in 2015 (see table 2). Through a groundwater dependency management policy, SEWA has managed to reduce this dependency from 47.22% in 2000 to 33.22% in 2010 (Alawar, 2014, p. 27).

At present, groundwater dependency is decreasing substantially as the UAE switched to non-conventional sources such as treated wastewater and desalinated water. However, groundwater usage is still high as compared to the annual recharge rate and production. When this trend persists, it is projected that there will be a deficit in reservoirs for groundwater and it has to be covered by the expensive desalinated water production (Susskind & Zaerpoor, 2017). The substantial variation between recharge points and groundwater abstraction is associated with increasing demand for water in the UAE due to economic development and population growth (Santhosh et al., 2013). Moreover, the expanded agricultural practices accounting for more than 70% of groundwater consumption is also associated with increased demand. At present, the persisting groundwater deterioration and reduction is a hindrance to the sustainability of this water source in the UAE.

Table 2. Water sources percentages. (Source: Clean Energy Business Council, 2014).

Source Quantity (MCM) Percentage (%)
Groundwater 1,850 43.7
Treated water 615 14.5
Desalinated water 1,750 41.4
Surface water 16 0.4
Total 4,231 100

The seven Emirates are supporting existing deficits in conventional water sources with non-conventional alternatives such as desalination of brackish and seawater. By the end of 2006, the government had built more than 36 desalination plants across the seven regions (Farid, 2015). For instance, some of the notable plants include Al-Hamriyah, Abu Mussa, Kalba, and Sharjah Layyah which use reverse osmosis and multi-effect distillation. The production of desalinated water across the UAE has increased over the years. For instance, the volume of desalinated water produced in the seven Emirates increased from 134,412.8 million gallons in 2000 to 277,942.14 million gallons in 2013. Specifically, SEWA was able to increase its production of desalinated water from 11,075 million gallons in 2000 to 18,438.54 million gallons in 2013 (Domonkos, 2014).

Dependency on desalinated water has equally increased from 52.78% in 2000 to 69.22% in 2013. In the last five years, the UAE government has invested more than AED 3 billion in desalinated water plant development or improvement projects since this source is one of the most reliable and sustainable. Another important water source is treated wastewater, which is a non-conventional resource. This source is categorized by the UAE government as a supportive or back up to the water used form agricultural activities, which take up to 705 of all groundwater production. At present, treated wastewater accounts for8.9% of total annual water production (Al-Otaibi et al., 2013). Since conventional water resources experienced unpredictable shortages, the production of treated wastewater in the UAE is steadily increasing annually by about 10% since this source can also be used for domestic purposes (Farid, 2015).

There are more than 34 wastewater treatment plants in the UAE with an estimated capacity of 42.438 million gallons every day. Expansion of treated wastewater production is related to water availability shortage, which is a serious risk to the agricultural sector (Chowdhury, Mohamed, & Murad, 2016). At present, more than 70% of all treated wastewater is consumed through irrigation and landscaping. The ever increasing treated wastewater production has been necessitated by water shortages that might seriously affect the agricultural industry (Farid, 2015). The wastewater treatment process in the UAE involves preliminary treatment, secondary treatment, tertiary treatment, sled treatment, and pumping to storage tanks (Mamoon & Rahman, 2017). Generally, great efforts have been made by the UAE government to address the water scarcity challenge through the utilization of conventional and non-conventional water sources. However, the challenge of persistent scarcity is still grappling the UAE water management system. Therefore, this research will attempt to recommend strategies for improving the water resources management system to guarantee better optimization of any management policy or plan for sustainable functionality.

Water Resource Management in the UAE

The several Emirates regions have hyper-arid to arid climate with infrequent rainfall and high temperatures. During summer, the average temperature is about 45 degrees Celsius, and humidity of 97%. On a daily basis, the average rate of evaporation is 8.2 mm with the sunshine of about 9.8 hours. Annually, the mean rainfall is 120mm (Government.ae, 2018). The seven Emirates have noticed the significance of conserving water resources as a foundation for policy-based sustainable development at present and in the future. Since the UAE region is endowed with marine, coastal, and terrestrial ecosystems, the government has put in place national legislation focused on addressing environmental issues such as sustainable water resource management (Mamoon & Rahman, 2017). Notwithstanding the arid climate, the UAE has an expansive and thriving farming industry propelled by modernized and mechanized irrigation using water resources from desalination plants, wastewater treatment points, and groundwater aquifers (Santhosh et al., 2014). As result, it is not possible for the UAEs agricultural industry to expand as large tracks of land can now be farmed. At present, more than 100,000 hectares of land are cultivated and irrigated annually to produce vegetables, fruits, and fodder among others (Government.ae, 2018).

Every year, the total demand for water in the UAE is increasing gradually. The demand currently stands at 4.5 billion cubic meters (BCM) every year while the UAEs renewable freshwater resources are about 150 million cubic meters per year (Todorova, 2014). Therefore, it is estimated that when the current demand rates and pattern persists for the next five to ten years, the annual water demand is projected to double about 9 to 10 billion cubic meters, which is double the current rate (Mamoon & Rahman, 2017). Specifically, the greatest increase is expected to come from the rising urban demand for commercial, industrial, household, public facilities, and institutions due to commercial and population growth (Domonkos, 2014).

Moreover, forestry and agricultural water demand are also expected to decrease relative to current values as a result of depleting groundwater resources, unless treated wastewater or desalinated water resources are used as alternative sources (UNDP, 2013, p. 9). The rising need for desalination could be attributed to oil discovery since revenues from these natural resources are used by the UAE to invest in water resources management system and other economic development initiatives. These investments have resulted in increased economic development accompanied by an influx of workers, which has expanded water consumption over the last two decades. Saif (2014) notes that desalination needs will rise in the future. Fortunately, the government has invested heavily in this area, which is an indication of forethought and awareness in planning for future integrated sustainable water resources management.

The UAE has also put in place a proactive Water Conservation Strategy (WCS) created in 2010 under the Environmental and Water Ministry (Todorova, 2014). The WCS has frameworks for systematic and sustainable water resources management in the UAE up to the year 2021 (Gelil, 2013). These frameworks are accompanied by eight strategic initiatives such as developing an integrated water management approach, improving natural water resources management, developing a national agricultural policy to conserve water, managing efficiently desalinated water, rationalizing water consumption, developing water pricing and subsidy policies, and better managing wastewater (Government of Abu Dhabi, 2014, para. 13). However, despite these actions and activities, the UAE government has never issued a comprehensive report discussing progress in achieving WCS initiatives.

Water Consumption in the UAE across Different Sectors

Water consumption in the UAE varies from one sector to another, with the agricultural industry taking the largest share of 60% while the domestic sector consumes 25%. The industrial sector takes a 9% share while commercial and municipal segments take up to 31% (see table 3 and pie-chart 1). Despite accounting for about 1% of the total UAE GDP, irrigated agriculture is the primary water user with an annual average of 60% of all produced water. 39% of this share is consumed in productive agriculture while 11% is used in landscaping and greening (Gelil, 2013).

The rest is utilized in forestry. 40% of total water consumption in the UAE is used in municipal/commercial and industrial sectors. Irrigation water is often used wastefully since most farmers still use the furrow and flooding techniques in cultivating high-water-uptake crops with low yield value (Clean Energy Business Council, 2014). In the recent past, the government has come up with improved technologies that are more efficient than the traditional flooding approach such as drip irrigation, which is expected to reduce the wastage by up to 35% (Todorova, 2014). Since 70% of the UAE population lives in urban areas, the rapid urbanization projects and massive real estate construction has increased the municipal and commercial usage to 31%. Lastly, the UAE industrialization initiatives utilize at least 9% of annual water production (Government.ae, 2018).

Table 3: Water consumption per sector from the year 2002 up to projections in 2050. (Source: Government.ae, 2018).

Year 2002 2005 2010 2015 2020 2025 2050
Household (MCM) 830.7 1,045.5 1,571.9 2,363.2 3,274.6 4,923.2 6,646
Industrial (MCM) 332.9 381 477.1 597.3 715.1 895.4 1,791
Agricultural (MCM) 2,340.6 2,753 3,637.8 4,865.5 6,207.1 8,561 8,561
Total (MCM) 3,504.2 4179.5 5,686.8 7,826 10,196.8 14,379.6 19,138
Water consumption share per sector.
Pie-chart 1. Water consumption share per sector. (Source: Farid, 2015).

Regional Breakdown of Water Use and Sustainability Index in the UAE

Regional water usage across the seven Emirates varies from one area to another, depending on population, size of the agricultural sector, and urbanization. At present, Abu Dhabi Emirate has the highest annual consumption at 4,323 MCM because it has larger agricultural land in addition to intense urbanization projects. This is followed by Dubai at 1,234 MCM per annum (Todorova, 2014). The third position is occupied by Sharjah at 897 MCM and Ras Al Khaimah at 675 MCM. The Emirates of Ajman, Umm Al Qaiwain, and Fujairah annual consumptions are 259, 567, and 643 MCM, respectively (Al-Zubari et al., 2017). In terms of regional consumption, the coastal region consumers 69% of the annual water produced as compared to the mainlands 31% usage.

Challenges in Water Resource Management in the UAE

The seven Emirates face a myriad of challenges related to water resource management. Within the GCCs Unified Water Strategy (UWS) framework, the UAE has not been able to effectively meet the five these under this strategy such as development and sustainability of water resources, efficient and equitable water resources utilization, enhanced municipal water supply security, effective water governance and awareness, and economic efficiency and financial sustainability (World Economic Forum, 2016, p. 17). Against the GCCs UWS target of wastewater usage at 60%, reduction of water consumption per capita to 250 liters per day, and increasing efficiency of irrigation to 60% by 2035, the UAE is lagging behind in some of these benchmarks. For instance, the average irrigation efficiency in the UAE is estimated between 45% and 55% (Gelil, 2013).

Moreover, the UAE has not effectively integrated strategies for gaining cumulative savings associated with costs and volumes for desalination production, municipal wastewater, and general water supply, and other energy requirements. The GCC-UWS report indicated that the water resources governance across the region is scattered between different authorities and not managed through a focused approach (Government of Abu Dhabi, 2014, para. 9). This means that the UAE has not been able to achieve integrated and effective water resources governance through the creation of a water-oriented culture within the seven Emirates (Todorova, 2014). Despite the existence of several policies and strategies for water resources management, the UAE still lags behind in its standards, data, legal framework, and regulatory controls in the use of its aquifers. Moreover, Saif (2014) notes that the UAE has not formulated a balanced water demand and supply management.

What the Government is doing

Water resources are managed in the UAE through government-appointed institutions that are governed by stringent laws. The Federal Electricity and Water Authority (FEWA) provides water services to Emirates located in the north such as Al Fujairah, Umm Al Quwain, Ras Al Khaimah, and a section of Sharjah. At the regional level, there are authorizes in Sharjah, Abu Dhabi, and Dubai that service the water needs of their Emirates. For instance, Abu Dhabi Water and Electricity Authority (ADWEA) serves Abu Dhabi Emirate, Dubai Water and Electricity Authority (DEWA) serves Dubai Emirate while Sharjah Electricity and Water Authority (SEWA) serves Sharjah Emirate (Gelil, 2013). These institutions operate under several water management legal frameworks borrowed from international and local best practices (Todorova, 2014).

Since the UAE is a signatory to a series of international environmental conventions, the current legal frameworks include Kyoto Protocol, UN Convention to Combat Desertification, and UN Framework Convention on Climate Change (World Economic Forum, 2016). At the regional level, the water resources management laws in the UAE integrate the Kuwait Regional Convention on the Protection of Marine Environment and Pollution and the Convention on the Conservation of Wildlife and its Natural Habitats in the GCC bloc (Al-Zubari et al., 2017, p. 13). At the state level, the government has passed several decrees and laws to facilitate effective water resources management. For instance, the Federal Law No (24) 1999 on development and protection of the environment addresses environmental protection, assessment, monitoring, management of discharged polluted water, protection of drinking water quality from storage tanks, handling of dangerous substances, and natural reserves (Malek, 2013, para. 5). The stakeholders within the UAE water resources management are government (Emirate and federal levels), society (media, the general public, and environmental organizations), and business (investors, industrial, financial, and individual parties) (Al-Zubari et al., 2017).

The government of the UAE has been at the forefront of promoting sustainability and conservation by creating open access to awareness campaigns, online consumption calculators, statistical information, and public participation. These strategies are integrated into supply and demand management techniques (World Economic Forum, 2016). Under the supply management strategy, the UAE government has been proactive in research to find alternative technology for effective desalination processes that can save on costs and improve sustainability (Malek, 2013). Since 80% of the UAEs potable water is from desalination plants, the government has been experimenting with alternatives that have lower energy use. Several policy approaches have been created to manage the supply aspect of water resources management. According to Al-Otaibi et al. (2013), the UAE government has put in place a four-scenario narrative to be accomplished by 2050.

This strategy integrates Markets First, Policy First, Security First and Suitability First scenarios (Al-Otaibi et al., 2013, p. 31). The Market First scenario emphasizes strategic economic growth, irrespective of the cost implications. Through the internalization of technological advancements for the development of the UAE economy, it is expected that environmental and natural resources such as water will deplete, thus, increasing health risks (Chowdhury et al., 2016). In order to avoid this situation, the government has opted for a public-private partnership in water resources management in order to lower the economic burden while attracting investments in the sensitive water resources sector (United Nations, 2013). The Policy First envisages public participation, constitutional review, and transparency in water resources management (Malek, 2013).

This scenario puts emphasis on environmental protection and the well-being of the UAE citizens. The Security First scenario envisions appropriate budgetary allocations directed towards water governance from environmental, economic development, and social perspectives (Al-Zubari et al., 2017). However, the current investment in research and development for other non-conventional water resources in the UAE targets private companies. The Sustainability First scenario aims at addressing the solutions to current challenges in water resources management in the seven Emirates. Specifically, this scenario recommends the integration of long-term strategic planning through heavy investment in training, capacity development, and educational programs (Clean Energy Business Council, 2014). For instance, the UAE government has increased its investment in research and development over the last 20 years to attempt to solve water problems such as unpredictable supply, climate change, and contamination of the network (Government of Abu Dhabi, 2014).

The Sustainability First and Policy First approaches in the UAE have resulted in quick and positive progress without economic development compromise. These technological advancements achieved through continuous research and development and proactive government investment in the current water resource infrastructure has created a relatively stable integrated water resources management system (Chowdhury et al., 2016). The UAE government has also been proactive in managing water resources demand through the employment of strategies designed to lower the demand while increasing supply.

According to Saif (2014), the government has given demand management more attention than supply management to minimize new and unplanned investments in water infrastructure. For instance, the UAE is currently using 60-90% of its groundwater resources for agricultural needs (World Economic Forum, 2016). Out of this quantity, it is estimated that more than 45% of these water resources go to waste due to poor farming practices (Government of Abu Dhabi, 2014). As a result, the government has increased research and piloting of better irrigation strategies to increase food security while sustaining water usage (Clean Energy Business Council, 2014). In managing the demand side in water resources strategy, the UAE government has been working on several technical efficiencies associated with water usage such as smart meters, consumption regulators, and tax breaks for effective large-scale water users (Al-Zubari et al., 2017). The government is also promoting water conservation through increasing access to public awareness and participation.

Conclusion

The literature review has extensively acknowledged the significance of sustainable water resources management within the UAE. The topic is wide and should be given a scientific approach in order to address matters of priority in water resources use and sustainability in the short and long term, especially in policy governance and planning. The challenges in the current integrated sustainable water resources management system should be solved in the UAE, especially considering the ever-rising population and increasing demand for water. Although the government has put in place policies and measures for balancing the water supply and demand management through its Water Conservation Strategy, the benchmarks for tracking progress and effectiveness are not clear.

Although the governments actions are positive steps towards formalized water resources management, there are still challenges in the effectiveness and efficiency aspects of these policies. The literature review has identified several challenges that the UAE government has to deal with to secure its water resources. The identified literature gap is the non-existence of reports highlighting and tracking the progress of the current water resources management initiatives. Therefore, it is difficult to quantify the performance of these strategies. This research paper will attempt to address this gap by examining the progress and possible recommendations for creating a proactive integrated sustainable water resources management system for the seven Emirates making up the UAE. The recommendations will also facilitate the improvement of effectiveness, efficiency, engagement, and trust in water resources governance.

Methodology

Introduction

This section of the paper will examine the method to be applied in collecting data and analyzing the results. Since this study is focused on a specific region, which is the UAE, the researcher will apply a research survey for an approach to gather primary and secondary data through quantitative and qualitative data analysis. The choice of quantitative and qualitative analysis was informed by the need to properly facilitate proper understanding of attributes related to water resources management as influencing its sustainability (Sherif, 2018). From the research survey of twenty respondents, mainly managers and supervisors of the UAE water management institutions, the research will analyze the results in order to identify the current policies, strategies, and challenges as part of sustainability governance (see appendix 1). The application of this approach is necessary for facilitating the identification of different statistical patterns emerging from the collected data as related to the variables of study (Mason, 2017). The collection of water consumption data of the UAE for quantitative analysis was carried out from reliable government and scholarly sources.

Research Design

The research design approach was semi-structured interviews targeting managers in the UAE water management institutions such as the Federal Electricity and Water Authority (FEWA), Abu Dhabi Water and Electricity Authority (ADWEA), Dubai Water and Electricity Authority (DEWA), and Sharjah Electricity and Water Authority (SEWA). This approach was combined with quantitative data collected from secondary sources. The rationale for a mixed research design was informed by the need to emphasize qualitative results supported by published government data on water consumption to expand statistical accuracy (Sherif, 2018). Since the proposed study is dynamic, subjective, and focused, the researcher used a mixed-method to accommodate several tools of analysis and minimize the potential margin of error.

Research Questions

The researcher adopted 9 open-ended questions that were relevant to the study objectives. These questions were pretested for accuracy and relevance to the conceptual framework and aims of the entire research study (Bryman & Bell, 2015). The final list of proposed questions is summarized below:

  1. In your opinion, which factors have the most impact on the current UAE water resources management approach?
  2. Which regions or parts of the UAE are often most affected by water shortages risks?
  3. Which sector in water consumption is exposed to the greatest risk of water shortages, in terms of industrial, agricultural, and domestic users?
  4. In your view, is there a correlation between the increasing population in the UAE and policies in place to govern water resources?
  5. How does climate change impact UAE water governance and sustainability?
  6. Which water resource management challenges should have short terms and long term solutions?
  7. How is your organization addressing or planning to handle these challenges or factors?
  8. What opportunities and challenges have been identified in addressing these challenges?
  9. Would you recommend a specific policy to be implemented to ensure the sustainability of the current water resources management?

The researcher also used a probing question to capture personal insight, especially in the answers that were entirely based on personal opinion (Mason, 2017). With the intent of capturing the insider perspective, the interviews were focused on the water and electricity ministry. This means that the open-ended questions were adequate in exploring the what, how, and why aspects of the research topic.

Setting and Sample

The researcher began by compiling relevant themes captured in the literature review on water resources management best practices and current state in the UAEs seven emirates. This was followed by compilation and probing of the interview questions. The researcher then pre-tested the questions by having a short interview with two officials to confirm their reaction and relevance of the proposed interview questions (Sherif, 2018). The responses from the pilot study were used to generate the final list of questions. The setting for conducting the interviews was mainly at the Federal Electricity and Water Authority (FEWA), Abu Dhabi Water and Electricity Authority (ADWEA), Dubai Water and Electricity Authority (DEWA), and Sharjah Electricity and Water Authority (SEWA) institutions.

The sample consisted of nine respondents drawn from officials and heads of the water management institutions, especially from the police department. This sample consists of experienced persons who understand the water resource management situation in the UAE besides being directly involved in decision and policy formulation. Moreover, the sample group has an expansive knowledge of the procedures being implemented by the government to address issues associated with water consumption and conservation (Bryman & Bell, 2015). The nine sample respondents currently work in the same field and understand the functional interaction at the institution and ministry levels. Conducting interviews for top management echelons of the UAE water resources institutions ensured that inferences made by the researcher could be compared to policy structuring and context of the same (Mason, 2017). The researcher also collected official water usage and policy target data from these institutions in addition to requesting the interviewees to submit any data they had at the moment.

Data Collection

The researcher made an official request to interview the respondents and expounded to them the nature and scope of the study using a sample 10-item sample questionnaire (Sherif, 2018). The activities of the interview process and their meaning were explained to give the respondent enough time for preparing responses. This means that the policy practices and opinions of the respondents were the research subject matter. The researcher ensured that the responses were captured and transcribed to give a description of the research questions in the context of water consumption and conservation data available (Mason, 2017). Moreover, the researcher took field notes to highlight impressions for a more focused and continuous evaluation of the responses. Each interview question was transcribed independently to enable the researcher to highlight critical points and identify a trend (Bryman & Bell, 2015). Through a proactive and holistic approach, the researcher was in a position to grasp all the primary themes from the interviews and published data.

Data Analysis

Both qualitative and quantitative data analyses were performed by the researcher. The qualitative analysis was based on the interview results that were tabulated to identify a common trend (see appendix 1) (Bryman & Bell, 2015). Quantitative data analysis involved reviewing published water conservation and consumption data from Federal Electricity and Water Authority (FEWA), Abu Dhabi Water and Electricity Authority (ADWEA), Dubai Water and Electricity Authority (DEWA), Sharjah Electricity and Water Authority (SEWA), and Competitiveness and Statistics Authority. The data captured was for a period of ten years, that is, from 2001 to 2015. The researcher organized the collected published data into sector-wide consumption, authority wide consumption, and population growth.

This set of data was selected because it would facilitate a proactive analysis of challenges in water resources management and general consumption sustainability (Sherif, 2018). For instance, population growth rate data were used to analyze the impact of population expansion on the consumption of water resources. Generally, increasing growth in population is expected to put pressure on the consumption of water besides increased expenditure to meet demand. Moreover, the sector and authority wide sets of data were collected to examine the rise or fall in water consumption and create a trend for future projections. The collected published data indicated that consumption of water resources has increased steadily in the last ten years, especially in agricultural and domestic sectors (Mason, 2017). The rationale for using two sectors in the analysis was informed by the segregated nature of data from other consumption sectors.

Assumptions in the Study

The first assumption was that published data across the seven Emirates are nearly normal, in terms of a trend over the ten-year period (Mason, 2017). The same trend is assumed for responses from interviews since the targeted respondents are policymakers. Specifically, the research will overly rely on the two sources to come up with scientific inferences. Another assumption is that the respondents will give accurate information that can be transcribed into a data set for establishing any existing trend (Bryman & Bell, 2015).

Limitations of the Study

Since substantial data was collected from qualitative interviews, there is a possibility of bias besides inaccurate data on water consumption. The sample space only consisted of nine respondents, thus, the research might end up with common approaches or views to the questions (Bryman & Bell, 2015). Under quantitative data, the collection of accurate water consumption data for the agricultural sector was difficult since some authorities did not have updated information. Therefore, the researcher was unable to compare the existing and past rates of water consumption.

Delimitations of the Study

The researcher will subject each response to qualitative data to ensure consistency and dependability. For instance, each response to the ten questions by a respondent will be coded to reduce generalization bias (Bryman & Bell, 2015). Moreover, the researcher has adequate training on professionalism and will remain neutral in presenting results. Thematic and content analyses will also be closely observed to ensure that findings fall within the context of the study (Sherif, 2018). In order to minimize biases associated with quantitative data, the research will use official water consumption data from government institutions and only refer to other sources to confirm the existing trend.

Conclusion

The researcher used a mixed research design approach to integrate quantitative and quantitative data analysis. The qualitative research involved direct interviewing a sample space of nine respondents who are a senior manager at the UAE water resources management institutions. The quantitative research was carried out through a collection of published data on water consumption in the UAE for a period of ten years. The small sample space might result in biases from limited insight. However, the research will probe and code each question to guarantee consistency and accuracy in presentation and analysis. The rationale for selecting a mixed research design was informed by the need to establish the current insight in water management policies and relate them to the trend from secondary data over a period of ten years.

Research Findings

Introduction

This section presents the results from the interviews and secondary data. Specifically, the section summarizes key factors that were identified as having an impact on water resources management in the UAE. In addition, this chapter examines the demographic and other characteristics of the participants.

Findings

For the qualitative data, the interview response rate was 100%, that is, all contacted participants answered all questions asked by the researcher. Moreover, the respondents were cooperative and cautious to explain their answers as was expected by the researcher. As summarized in table 4, the demographic characteristics of the respondents were diverse and observed scientific sampling requirements.

Table. 4. Demographic attributes of the respondents. (Source: Self-generated).

Demographic Data
Respondent groups Number Percentage (%)
Male respondents 7 77%
Female respondents 2 22%
Responsibility within the organization
Departmental head 5 55%
Manager 4 45%
Years of experience in water institution
10 years and above 6 66%
20 years and above 3 33%
Experience in water policymaking and implementation
10 years and below 4 45%
10 years and above 5 55%
Level of expertise education
Diploma 0 0%
Bachelor Degree 2 22%
Masters Degree 5 56%
Ph.D. Degree 2 22%

Apart from the gender imbalance in the selection of the participants due to t patriarchal nature of the UAE society, other variables met all the requirements and indicated that the respondents are very experienced in water management policies as confirmed by many years of experience and advanced level of professional education. The respondents identified five key factors as having the greatest impact on the current water resources management at the UAE. These factors are climate change, water source, population growth/consumption, and sector-based consumption. The respondents identified several policies and initiatives in place to tackle these negative effects of these factors such as improved technology, improved efficiency in the water network, and changing public perception on conservation among others.

All the respondents agreed that climate change is a threat to water management initiatives in the UAE since it affects the water cycle. For instance, interviews A, B, D, F, and J associated the less rainfall, higher temperatures, rise in sea level, extreme weather, and high evaporation rates to changes in the climate. The respondents further noted that since climate change is a natural condition, it is challenging to tackle its effects since their occurrence is unpredictable. All the respondents agreed that climate change has increased water demand, especially in the agricultural sector, which is the heaviest consumer. For instance, interviewees C, E, G, H, and I noted that the increasing temperatures have increased evapotranspiration, evaporation, and consumption. Respondent J further added that climate change may increase water shortages, especially when the demand and supply sides of water resources management cannot be balanced.

Respondent A raised a concern on the need for modern and cheap technology in the desalination processes since extreme climate changes might reduce the quality of desalinated water. However, interviewee E was positive that rising temperatures might actually increase rainfall since high evaporation is good for the hydrologic cycle. The respondents agreed that climate change will reduce the intensity and quantity of rainfall in the UAE. The secondary data confirmed this opinion. For instance, in the last two decades, the average rainfall has dropped from 120mm/year to 80mm/year (Chowdhury et al., 2016). Respondent H explained the impact of reduced rainfall as lowering groundwater recharge in addition to increased leaching of harmful agricultural chemicals into the water system. Interviewee B noted that the rising sea temperatures have created an ideal environment for algal bloom, which is associated with an increase in toxins in the seawater by reducing oxygen levels. This situation may negatively affect desalination plants performance by blocking the desalination machines membranes. However, the respondent added that the UAE has advanced desalination plants that are not affected by the algal bloom.

Water distribution infrastructure and sources identified by the interviewees include conventional and non-conventional resources. Interviewee H indicated that Abu Dhabi Emirate faces the highest water shortage risk in the UAE since it depends on natural groundwater, which has been overexploited. Although groundwater is no longer a source of drinking water, the agricultural sectors irrigation activities are supported by this resource. Interviewees E, F, G, and J noted that other regions exposed to water shortage risks are shorelines of the UAE because of high saltwater intrusion levels. Respondents A, C, E, and G indicated that the northern and eastern parts of the UAE have higher rainfall per annum and currently the main feeders of many water reservoirs. According to the government data, drilling of groundwater has increased by almost 70% in the last 20 years. For instance, in the late 1980s, usable groundwater could be reached after drilling 250 to 300 feet. However, at present, drilling has to go deeper than 900 feet to tap groundwater (Government.ae, 2018). All the respondents agreed that abundant seawater is the primary alternative in increasing water supply in the UAE. The government data confirmed this view as indicated by the extensive installation of desalination plants over the years (see figure 4).

Seawater desalination capacity from 1970 to 2014.
Figure 4. Seawater desalination capacity from 1970 to 2014. (Source: Saif, 2014).

Interviewee C and J indicated that the entire UAE water supply network is sustained by desalinated water from the sea. As part of the water security strategy, the government of the UAE has committed $15.78 billion to upgrade distribution and desalination plants for the next 6 years (Government.ae, 2018). As captured in figure 5, the increased investment is expected to inject at least 200 MCM in the current water supply network.

Desalination plants that are to be upgraded in the next six years.
Figure 5. Desalination plants that are to be upgraded in the next six years. (Source: Government.ae, 2018).

The secondary data from government publications indicated a sharp rise in population and general water consumption despite declining supply due to climate changes. The data over a period of more than ten years, that is from 2005 to 2015 indicated a sharp rise in water demand in the UAE in the three major sectors, that is, agriculture, domestic, and commercial users (Chowdhury et al., 2016). Due to the decentralized data management approach, the researcher could not get data from some domains or years from the government reports (Todorova, 2014). However, the data collected were adequate for establishing a trend and addressing the research questions comprehensively. Interviewee C noted that the estimated annual demand for water is 4.5 BCM which is 150 MCM higher than the current production capacity. It is further projected that the demand might double in the next 15 years, especially if the current population growth rates persist (Gelil, 2013).

Specifically, the interviewees noted that commercial, domestic, and agricultural sectors are projected to have the highest increase in demand for water. The Ministry of Energy and Water (MoEW) has forecasted that the UAEs current pursuit of economic growth will only be realized through adequate and effective water resources management (Government.ae, 2018). As illustrated in table 6, the population growth rate has increased steadily in the last ten years, that is, from 2005 to 2015 from 4 to 9 million (Government.ae, 2018). The interviewees associated the rapid increase in population with a rising demand for water and other government services. Water consumption has also increased steadily between 2005 and 2015 from 250,000 MIG to 389,000 MIG (Chowdhury et al., 2016). Interviewee H was worried by the high per capita consumption of water in the UAE, which is three times the average worldwide usage of 630 liters/capita. The interviewees noted that the erroneous levels of consumption should be bridged through government initiatives to promote water conservation and proper usage culture. The respondents further agreed that there is an urgent need to improve the current water management system in the UAE.

Population growth in the UAE from 2005 to 2015.
Table 5. Population growth in the UAE from 2005 to 2015. (Source: Government.ae, 2018).

Conclusion

The findings from secondary and primary data confirmed that the UAE government is facing challenges of sustainability in water resources management due to rapid population growth, climate change, high cost of desalination, wastages, and depleting water sources. The respondents suggested improvement in water production and supply network through the integration of new technology. Moreover, the respondents recommended that the government should attempt to change the public culture of wasteful water usage and create a strong policy network for ease of enforcement.

Discussion

Introduction

This chapter relates the findings to best practices as part of a policy initiative to improve water resources management in the UAE. This section relates the results of the study to current challenges in water resources management in an attempt to present alternative supply and demand governance that integrates the elements of trust/engagement, efficiency, and effectiveness.

Summary of Findings

As expounded in the literature review, the research study framework was based on examining the water resources management in the UAE and current challenges using the OECDs resource governance principles, which are engagement, effectiveness, and efficiency. The qualitative part of this study drew several inferences as suggested by the nine interviewees. Specifically, the interviewees identified climate change, increasing population, wastages, and rapid industrialization as putting pressure on water management sustainability. The respondents suggested a paradigm shift in water management approach through integration technology, change of public wastage culture, and focused policy to guarantee sustainability. In specific terms, the integrated sustainable water resources management system in the UAE should include the principles of efficiency, effectiveness, and engagement.

The effectiveness principle institutionalizes policies and processes defining proper sustainability goals targeting all water governance levels. This principle entails meeting and implementing set targets through a policy-oriented establishment of clear roles for stakeholders and water governance using appropriate scales. The framework should be coherent for all the sectors for ease of enforcement. For instance, a comprehensive capacity building plan could address challenges associated with end-user wastages to increase water sustainability.

The interviewees suggested that water governance should be centralized for ease of managing data as opposed to the current fragmented approach, which is delimiting the effectiveness of the UAEs Water Conservation Strategy (WCS) through increased inefficiencies. Since the respondents noted that integration in the management of water resources would balance the demand and supply domains, a policy laden approach would make the process efficient and optimal to reduce the persistent shortages. For instance, a strategic water reserve was identified by interviewees C, D, H, and I. It is apparent that the UAE government has rolled out several strategies and initiatives to address sustainable water governance. At present, the nation is a party to several international and regional protocols encouraging long-term water resources sustainability.

The efficiency principle in an integrated water resources management examines the benefits of optimal supply and demand management at the least cost to the UAE society. In order to achieve this principle, the interviewees recommended sharing of information and data through a centralized communication network, efficient allocation and mobilization of finances, heighten research innovation, and proactive building of regulatory frameworks. As noted in the OECD principles, centralized data management in water governance would reduce fragmentations associated with inefficiencies. For instance, interviewee H proposed a digital water resources atlas for the entire UAE to fasten tracking of problems and their solutions.

Moreover, there is a need for expanded investment in the water infrastructure to curb the current shortage and align production to demand through the use of new technologies. The interviewees agreed that desalination is a very expensive project because of direct and indirect costs to the environment. Therefore, using the new technology would increase the level of efficiency. This principle is complete with relevant and comprehensive legislative and regulative frameworks are integrated as proposed by all the interviewees. These frameworks will address extraction, production, supply, and usage within standard global consumption per capita. Respondent J confirmed that the government is implementing most of the GCC initiatives on water resources sustainability, despite budget constraints. However, the consumption data indicated that more need to be done to meet the demand of the ever-growing population against depleting water resources.

Within the principle of building trust and engagement, the respondents noted that the UAE government. For instance, respondent B, C, D, F, and I opined that safeguarding stakeholder inclusiveness and building public assurance through promoting proactive engagement and transparency in water resources management may improve on sustainability. Moreover, respondent A stated that the current water management frameworks should be enforced to manage trade-offs among end-user sectors. For instance, respondent H suggested increasing water prices to encourage conservation through reduced consumption. This means that a simple reduction in the demand or per capital consumption management would lower pressure on the supply side. In addition, the findings indicated that the UAE government does not have any comprehensive report on the progress of its water management initiatives. This has made it difficult for water institutions to evaluate and monitory existing water policies.

Conclusion

This chapter has related the literature review findings to research study inferences. Under the proposed OECD water governance principles, it is apparent that the UAE government is attempting to integrate efficiency, effectiveness, and engagement in water resources management through policies, plans, and initiatives. However, there is a need for an expanded, inclusive, and demand management approach to lower pressure on the supply side. Moreover, new technology and increased investment in the water infrastructure may seal the current shortage while guaranteeing long term sustainability.

Conclusions, Recommendations, and Suggestions for Future Research

Recommendations

Enforcing green building codes for water efficiency

The UAE government should consider expanding the existing Unified UAE Water Strategy to ensure that the green building codes are enforced for water efficiency. The unification will ensure that the UAE conforms to GCCs Unified Water Security Strategy. Moreover, government agencies will be empowered by a more focused enforcement policy with a clear legal framework (Madden et al., 2013). The green building codes could be institutionalized across the water management authorities and other relevant government bodies into a coherent policy to avoid the current challenges in enforcement such as poor coordination among stakeholders.

The green building codes could be centralized during enforcement to improve water efficiency (Singh & Singh, 2014). For instance, it would be appropriate to open offices across the seven Emirates to enforce the codes with their headquarters in Abu Dhabi. This will avoid the scattered approach and internal divisions among enforcement agencies. From the data gathered, FEWA recorded an annual shortage of 4,000 MIG (Lubega et al., 2014). Through the effective endorsement of the green building codes, this shortage could be reduced substantially and may evenly end over a longer period of correct mapping (Dawlabani, 2013).

Promoting the use of Treated Sewage Effluent (TSE) for irrigation

To reduce the high water consumption rate in the agricultural sector, there is a need to roll out a comprehensive, inclusive, and incentive-laden campaign for the use of Treated Sewage Effluent for irrigation as opposed to clean water. This initiative should be backed with common legislative and regulatory frameworks for ease of enforcement. For instance, the water resources management stakeholders such as private institutions, semi-government authorities, water institutions, and ministry could partner to spearhead a national campaign that is done at the regional level, especially in agricultural areas (Battor & Battour, 2013). The farmers could be motivated to use treated effluent in irrigation instead of desalinated water to lower the cost of farming from the end-user perspective. At the same time, the burden of production of desalinated water will reduce once farmers embrace the new irrigation suggestion (Eman, Ayman, & El-Nahas, 2013). When implemented, the UAE will be in a position to meet the GCCs Unified Water Strategy aim of building awareness across the level of water consumption sectors.

Updating the countrys infrastructure to include smart metering systems and modern desalination plants

The UAE has a robust economy with one of the highest rates of urbanization in the world. The commercial and municipal water consumption has been rising to serve the expanding demand. In order to sustain the supply and demand sides of water resources management, there is a need for updating the current water infrastructure through the use of reliable, efficient, and effective modern technology (Harrison, 2018). For instance, the integration of smart meter technology might reduce wastages associated with leakages due to end-user negligence.

The smart meters could also empower the end-users to track their consumption periodically and to be in control of how much water they consume (Al-Ansari, 2015). Moreover, the smart meter can detect uneven flow or leakage in the water system (Chowdhury et al., 2016). As a result, the government will be in a position to accurately manage consumption while minimizing wastages that are threatening the current water management approach (Harrison & Wicks, 2013). Moreover, it is necessary for the UAE government to invest more resources in new technologies for water desalination plants to reduce the high costs associated with running these production factories. The new technology in desalination and general supply network will substantially improve the efficiency and effectiveness of the entire water network (Guiso, Sapienza, & Zingales, 2015).

Collect the non-revenue water

As part of inclusive engagement and building trust in the water resource management approach, there is a need to implement the collection of non-revenue water as part of the incentives and recognition of efficient users (Daft & Marcic, 2016). These initiatives should be aimed at encouraging individuals and institutions to reduce their usage and be part of the conservation movement as positive contributors to reducing the cost of water production and supply (Chowdhury et al., 2016).

Awareness for the public to change the mindset

Improved information dissemination in building awareness among the general public is needed to change the wasteful water consumption mindset. The relevant authority should put in place initiatives for building engagement and trust among the UAE population. For instance, government agencies should improve on their current efforts in disseminating information on water consumption and the need to increase green living as part of conservation strategies (Abusa & Gibson, 2013). Private and public organizations could partner to provide nationwide consumer education programs and initiatives. These campaigns should integrate multilingual, simplified, illustrated, and visible messages directed at building awareness in the UAE (Battor & Battour, 2013). Through this approach, the relevant water management bodies will improve the value and importance of water conservation to reduce end-user wastages.

Conclusion

The aim of this study was to comprehend the current strategies in water resources management and the challenges faced by the stakeholders in sustaining these operational frameworks. The seven Emirates making up the UAE have more or less similar climate ranging from hyper-arid to arid with scarce natural water resources. The scarcity is further complicated by the high evaporation rates, even increasing demand and harsh environmental conditions. As established in the study, the dependency rate on desalinated water is very high at over 70% of total production per annum. The researcher examined current water management strategies for these water resources and initiatives the federal and regional governments have put in place to secure the quality, efficiency, access, and sustainability of the conventional and non-conventional water sources.

The study has discussed the impact of climate change and population growth on UAEs water governance in addition to existing challenges. Specifically, rapid population growth, agriculture, and commercial activities were attributed to the increasing pressure of the UAE water resources. Literature review evidence indicates that the UAE government is at the forefront in attempting to address water management concerns through the Water Conservation Strategy and several short and long-term initiatives in the form of strategic plans per Emirate. The qualitative data collected from primary interview research confirmed that the government has put in place initiatives aimed at promoting public inclusion and continuous water resources use training for different user sectors and segments. However, these policies, strategies, and initiatives are not adequate for the creation of integrated sustainable water resources management for the UAE.

The research study has made several recommendations to the relevant authority to ensure trust, effectiveness, and efficiency in the water resources management system. These suggestions include enforcing green building codes for water efficiency, promoting the use of Treated Sewage Effluent (TSE) for irrigation, updating the countrys infrastructure to include smart metering systems, collecting the non-revenue water, and building awareness for the public to change the mindset. However, it is significant for the UAE federal and regional governments to continue implementing the Emirates-specific and state Unified Water Strategy besides reducing subsidies on water through increasing tariffs.

Moreover, there is a need to develop coherent policies to integrate the water management authorities from a central data center. These proposed initiatives should be merged into an appropriate technology to advance the supply and demand control water resources system. When implemented, these recommendations will ensure that the UAE government is able to cap average water consumption, which is currently four times higher than the rate of consumption in the entire world. The inferences from this study contribute to the analysis of challenges in the water resources within the UAE and could be used to create a policy framework. The proposed recommendations could be integrated into the United Arab Emirates 2036 Water Security Strategy to ensure the aspects of suitability, efficiency, inclusiveness, quality, and access are achieved in the demand and supply sides of the water resources management.

Suggestions for Future Research

This research examined all the domains related to water resources management for the entire UAE. The study also generalized the water resources and sources for all the seven Emirates. This makes the findings general and might not address unique water resources management needs for a specific region. Therefore, further research should be carried out to examine specific domains that are unique to each of the seven Emirates in order to draw inferences that match the water resources and sources. For instance, a study on the management of treated wastewater or desalinated water plant governance could make the findings more specific. Moreover, further studies should be carried out to compare the water resources policies and management across the seven Emirates using the framework of unitary versus federal states.

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Appendix 1: Summary of Interview Data

Primary Themes Respondent Code Raw Interview Data
Regions affected most by water shortages Respondent A Since nearly 99% of all water resources in the UAE are from desalination plants, the entire UAE is at risk of water shortages. However, the Northern region is at the highest risk.
Respondent B The country is right in the middle of a desert. Every part is exposed to water shortage risk.
Respondent C Areas that over relied on wells and springs are the most exposed to water shortages since these sources are depleting.
Respondent D The interior region has less rainfall as compared to the eastern and northern regions.
Respondent E The depleting fresh water sources and ever declining rainfall exposes the entire UAE to water shortage risks, especially the coastal regions.
Respondent F The desert climate exposes the UAE to high evaporation rate that takes up to 3% of water sources.
Respondent G The groundwater sources are predicted to deplete by 2050, exposing UAE to further shortages, especially when nothing is done to find alternatives.
Respondent H Water shortages are minor since the UAE has not even started using its water reservoirs.
Respondent I Abu Dhabi is the most exposed region to water shortages since most of its groundwater sources are salinized and most reservoirs exhausted.
Challenges in water resources management and the government should do Respondent A UAE has the highest per capita water consumption, which is three times that of the worlds average usage. There is a need to integrate water conservation and proper usage culture.
Respondent B Agricultural sector uses up to 60% of the total water supplied, despite the low productivity plants. This should change and farmers should switch to treated affluent for irrigation.
Respondent C A lot of wastage occurs in the supply network due to old technology. Smart meters and modernized water network might reverse this trend.
Respondent D The entire water management network is disintegrated and managed by many entities, thus a lot of inefficiencies. There is a need to merge these organizations into a centralized management and data network for efficient response to any water management challenge.
Respondent E The ever increasing water demand has compromised conventional water resources and put a lot of pressure on the production and supply sides. There is a need to research for more efficient and cheaper alternative for water treatment. Moreover, the algae bloom might affect quality of water in the long run if high temperatures persist. The government could consider investing resources in research and development of modern, advanced, and efficient production cycle.
Respondent F There is an urgent need to promote conservation in domestic and agricultural sectors due to high wastages in irrigation and human consumption. Moreover, poor water supply network has increased incidences of water pollution and spills along the pipeline. Improved technology will solve this.
Respondent G Mismanagement of water resources due to disintegrated approach to governance is affecting the supply and demand side of water usage. The government should consider creating a centralized management system, such as a state water atlas for ease of governance.
Respondent H Desalinating water is a very costly affair and is laden with many negative environmental impacts. Moreover, usage of water is around 650 liters per household, which is very high and unsustainable. There is a need to invest in advanced desalination technology in addition to public engagement to change the wastage culture.
Respondent I The climate change has negatively impacted water security in the entire UAE. The high temperatures, low rainfall, intense evaporation, and overexploitation of water has put immense pressure on the UAE water management policies. There is a need to change the management policies to integrate systematic, focused, and endorsable laws for ease water governance.
What the government is doing Respondent A There are laws and regulations to ease management.
Respondent B The government has invested billions in desalination and research.
Respondent C Several campaigns across the UAE are in place to sensitize farmers and other users on the need for conservation.
Respondent D The government has a comprehensive water management plan under the vision 2036 besides other regional plans.
Respondent E A lot of resources have been invested in research to conserve and efficiently manage the production and supply sides of water management.
Respondent F There are policies in place, improved investment in water infrastructure, and integration of modern technology.
Respondent G The government has put up extensive water management plans besides increased investment in new modern desalination plants across the UAE
Respondent H The government is a party of several regional and international water conservation conventions, which are used to benchmark progress and authenticity of local management policies.
Respondent I The government has improved its investments in water management infrastructure in addition to reducing wastages through a behavioral change campaign. Moreover, there are several policies and plans in place for short and long term management plans to guarantee sustainability in production, supply, rejuvenation, and consumption of water resources.

Potable Water Supply in the Gulf Region

Background of the Topic

The supply of potable water has long been an ongoing issue, especially for areas characterized by an arid climate. It is an important element in the growth and development of a region, and the creation of a solution to the given problem could be considered the main priority. For this reason, the countries of the Gulf region devote great attention to the investigation of this issue. The tendency toward rapid growth in the region and the associated increase in population has been laying a foundation for the further deterioration of the water supply and the increased significance of the issue (Water crisis n.d.).

The long-term character of the problem has resulted in numerous investigations of the question aimed at discovering alternative ways to provide countries with freshwater and guarantee appropriate living conditions for the people residing in the area (Muhalhal 2014).

The situation is further complicated by the fact that water resources are also used by the agriculture sector to grow crops needed for the population. Thus, the use of alternative sources of freshwater, along with innovative ways to reuse or desalinate seawater or underground water, has become extremely topical for fast-growing regions characterized by problems with the water supply (Water, Environment, Social and Rural Development Department 2005). Therefore, the paper is focused on investigating the option of using TSE water to irrigate residential yards to save potable water, and possibly collecting stormwater for reuse as another potential solution to the problem mentioned above.

Problem Statement

Delving into the peculiarities of the Gulf region and problematic water supply, several issues need to be raised. First, the demand for water has increased by 140% in the region over the past decade (Houry 2011). This demand is associated with the evolution of industry along with population growth. Second, the state of the water supply remains unchanged. The natural water supply in the area is very poor, and the question of potable water is becoming especially topical (Voss et al. 2013). The states receive scanty rainfall, while the evaporation rates are high, exceeding 300mm per year (Raouf 2009).

Thus, water supply is a significant problem. The needs of a constantly growing population and developing industry should be satisfied to guarantee the further evolution of the region. To solve this problem, different approaches are being adopted and implemented. For instance, the Gulf states currently produce 60% of the worlds desalinated water because of a lack of other water sources (Al-Farra 2015). At the same time, 85% of all groundwater, as well as desalinated water, is devoted to the agricultural sector in the region (AlRukaibi 2010). If the current rate of economic development continues unchanged, the depletion of groundwater reservoirs appears inevitable; already, the first signs of alteration can be discerned (Malek 2015). Considering all these factors, an efficient and innovative solution to this problem should be suggested to guarantee the preservation of the regions prosperity and high quality of life.

Goals and Aim

In this regard, the main aim of the suggested paper is to investigate the exploration of alternative water sources to decrease the dependence on natural water resources and preclude the depletion of groundwater reservoirs. Therefore, the author emphasizes a focus on researching opportunities for using TSE water in irrigating residential yards as a way to save potable water and the collection of stormwater as another solution. The given aim preconditions the introduction of the following objectives.

First, it is important to determine the possible impact that the suggested approach will have on the problem of the water supply for the Gulf region, its agricultural sector, and peoples needs. Second, it will be necessary to identify opportunities and a comprehensive idea of the potential actions that will be needed to implement the solution mentioned above (Rosenberg 2008). Third, it is vital to determine the potential costs involved in using TSE water in irrigating residential yards, as well as the benefits it might render if implemented. Finally, assessing the theoretical results of the suggested approachs exploration and the impact, it might have on the state of water resources in the region must be pursued. In general, the paper is focused on a comprehensive investigation of the issue and the effect the suggested solution may have on agriculture and the conservation of potable water.

In this regard, the current state of the water problem in such cities as Dubai (the UAE), Jeddah (Saudi Arabia), and Manama (Bahrain) will be assessed and used as the background for the research. The possible solution will also be applied to the functioning of these entities.

Methodology

The goals mentioned above precondition the use of a specific methodology that can help investigate the issue. First, a relevant literature review will create a theoretical framework for the discussion. Second, qualitative methods will be used to assess TSE water composition and determine the possible sphere of its use. Third, quantitative tools will be explored to determine the benefits the adoption of the approach will bring to the Gulf region and the water savings that could be achieved. For this reason, using a mixed approach that incorporates both qualitative and quantitative methods is recommended.

Reference List

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Sustainable Strategies in Water Quality Control

Environmental Problem

According to an international environmental watchdog, freshwater is the lifeblood of the planet. The same non-government organization made the assertion that no one can survive without it. Freshwater is mankinds source of food, health, and energy. Access to freshwater sources is the main reason for the establishment of civilizations. In the present time, urban centers require a sustainable supply of freshwater to ensure socioeconomic development. It is therefore important to learn how how to apply sustainable strategies in water quality control.

Promoting Positive Behavior 2 Strategies

There are numerous strategies that governments and local organizations can implement in order to enhance the impact of water quality initiatives. First, the importance of quality control must be disseminated through the education of the younger generation. The second strategy is to establish local initiatives that in turn will monitor the quality of water in a certain area.

With regards to the first strategy, it is important to touch the hearts and minds of the next generations leaders and policy makers. Present problems with regards to ineffective policies are usually the result of ineffective policies generated by uninformed policy makers. The root cause of the problem can be traced back to influential leaders occupying key positions in government. It may be difficult to change their mindset with regards to their view regarding water conservation. However, it is easier to influence next generations leaders concerning their roles in water conservation and water quality control. It is important that children and teenagers understand their individual roles in transforming the environment.

Educated people will undoubtedly contribute to the creation of policies that will safeguard rivers, ponds, lakes and storage reservoirs. However, their contribution will go beyond the political sphere. They will not only contribute to affect the political aspect in the struggle to improve water quality control measures. They are going to transform water quality control through the creation of new technology, and the development of ideas that will directly impact efforts in water quality control initiatives. They are the inventors and radical thinkers of the future.

They have the capacity to think unconventionally. They have the capacity to develop new ways on how to solve a particular problem. More importantly, they have the capability to try something new without fearing the consequences of failure. Consider the impact of innovators like the creators of Google and Facebook. If the same kind of innovative thinking can be applied to solve water quality control problems, then, the future looks bright for the natural environment.

With regards to the second strategy, it is important to consider the importance of mobility, and the capability to directly cause positive change on a specific area. It is foolish to wait for the government to act on water quality control issues affecting a local area. It is easier to mobilize support, and to affect change using the resources, and manpower of a local group.

It is therefore practical to encourage the creation of groups that will safeguard freshwater sources. If the source of water is the nearby river system, then, it is best to create an environmental watchdog that is based on the same area. The members of the group can effectively monitor the changes of the natural environment. Their efforts will help supply critical information to local officials with regards to problems that require their attention.

A non-government organization dedicated to the conservation of freshwater sources in the area has an emotional connection to that particular locality. At the same time, they have more incentive to safeguard freshwater sources in their area as compared to a group that is located several miles away. However, the non-government organization that is tasked to enhance the initiative in improving water quality control measures must be educated regarding recent technologies associated with monitoring the quality of freshwater sources in the area. They must realize that monitoring is the application of fundamental scientific methods of observation of the environment (Krantzberg, 2010).

Positive and Negative Consequences

Members of the local population must experience tangible positive consequences with regards to their conservation efforts. It is not enough to merely encourage the members of the community to help in the environmental work needed to save a river system, or secure the integrity of groundwater sources. They have to see and experience the benefits of their actions.

For example, coordinated effort in pressuring manufacturing facilities to treat the byproducts of their factories before it is released to the nearby river has significantly reduced the amount of hazardous material dumped into a freshwater source. Residents of the said area must see the revival of the river through hard data regarding fish population, and other natural resources connected to the said river system.

A positive feedback can inspire people to action. It will help inspire the next generations leaders and innovative thinkers to join the struggle against environmental degradation. However, one of the most powerful forces that compel people to action is the realization of impending danger. They need to now that past actions has contributed to the destruction of something that they consider of great value. It is therefore imperative to educate people with regards to the impact of certain practices that caused the destruction of freshwater sources. They must realize that their refusal to participate has made it extremely difficult to monitor business practices, and man-made activities that caused the pollution of rivers and streams.

Technological Advances

Modern construction methods enable human beings to create structures that have made life easier for urban dwellers. However, the construction of mega-structures has tremendous negative impact on pollution levels, watershed areas, and public water supply. The absence of effective measures in controlling the environmental impact of construction, sediments, and other pollutants created an irreversible effect on freshwater sources.

The technology utilized to construct departments stores, urban housing, and skyscrapers is the same technology that is needed to construct a water delivery system to provide freshwater supply to residents in populous urban centers. The technology used to deliver water is the same technology that destroys the main source of water. However, technology can be utilized to improve efforts in protecting freshwater sources. A good example is Information Technology.

Information Technology is being harnessed to enhance traditional water monitoring strategies. Information Technology helps improve monitoring activities, especially if one will consider the complicated nature of monitoring that includes: sampling, laboratory analysis, data management, data analysis, reporting, and use of the resulting information in management decision making (Younos, 2002).

Environmental Policies

Environmental policies create a legal imperative with regards to the importance of conserving freshwater. The absence of applicable and relevant environmental policies relegates the discussion of water conservation to an ethical issue. For example, global warming is an important issue. However, for many years no one paid attention to its significance until the government started to initiate policies that elevated its importance in the eyes of the general public.

As a result, the creation of policies that established legal sanctions on certain activities has made global warming a national issue. The same thing can be said of environmental policies that put pressure on businessmen, developers, and local officials to seriously consider the long-term effects of their actions (Pharino, 2007).

Environmental policies are not only effective in creating a legal imperative to keep unscrupulous businessmen wary of their decisions. Environmental policies can help establish good practices that ensure the implementation of long-term strategies that has a positive impact on local freshwater sources. For example, there are statewide permits like storm water permits for urban areas under 100,000 people, industrial uses, and construction (Hancock, 2009). The permits are pragmatic steps in compelling people to contribute in their own little way to reduce their impact on the environment.

Environmental policies encourage the creation of water sensitive planning and design. For example, in the state of Maryland, Prince George County implemented policies with regards to the creation of bio-retention structures. It is an example of an integrated landscape-based micromanagement tools for storm water management. The absence of this type of policies has resulted in excessive flooding in urban centers all over the world (Pitt, 2007). At the same time, the inability to control storm water has resulted in environmental degradation that has exacerbated the effect of natural calamities.

Environmental policies are effective if it is based on scientific research. Therefore, policy makers must not only develop policies based on its impact on stakeholders. Policies must be crafted based on long-term effects. It is therefore imperative to go beyond data collection. It is important to establish a culture of monitoring within a local area. Coordinated action must result in the creation of policies that will develop sustainable strategies in improving water quality control.

References

Krantzberg, G. (2010). Advances in water quality control. New York: Scientific Research Publishing.

Hancock, D. (2009). Clearer structure, cleaner water. Washington, D.C.: Diane Publishing.

Pharino, C. (2007). Sustainable water quality. New York: Springer.

Pitt, R. (2007). Construction site erosion. PA: Desetech Publication.

Younos, T. (2002). Advances in water monitoring research. CO: Water Resources Publications.

Water Quality and the Water Board Scenario

Water quality

Water quality and shortage is one of the major crisis faced by many nations. In most nations there are cases of frequents droughts and famine because of climate change. Addressing the issue of water quality issue is a concern for many nations. This is because not all waters are healthy for human consumption. Certain standards and measures needs to be observed to ensure that water provided is of good quality for both animal and human consumption.

The Water Board scenario

In the scenario where a given community is facing water shortage and a given water, board proposes to erect a water recycling plant, several factors should be considered. As a member of this water board one first needs to find out the level of quality of water and its source before the eruption of the drought, the clear cause of water shortage, impacts of water shortage and all other relevant information needs to be gathered. A rapport should be created where the water board holds meetings with the relevant communities and other relevant bodies to discuss the issue of water shortage and quality. Every member of the affected community should be involved in project right from the initial stages to avoid any obstacles to the project arising in future. Concerning the issue of constructing a water recycling plants, the water board should be very smart to handle and respond to issues arising from different parts of the concerned community. Some of the issues and questions that may be raised by the community include, where will the recycling plant be erected? How many people can this recycled water serve? How safe is the water recycled for drinking? Will water provision be available throughout? The board should be prepared to answer such and other relevant questions raised by the community.

The members of this water bodies should also seek approval to build the proposed water recycling plant from different relevant bodies that affects the viability of this plant. Some of these important and relevant authorities include the public health body. This government body may pose several questions to the water board proposing to build a water recycling plant that have to be addressed for approval of the plant. Public health is majorly concerned with the health status of its public members, the health of services provided to the public by various bodies and the impacts of projects to the community. This health authority may raise questions like, what are the impacts of the general impacts of the project during and after construction stages. What are some of the measures that the board is intending to apply to mitigate these impacts? Will the recycled water be healthy for both animal and human consumption? All these questions and many others should be addressed by the board for approval of the project and avoid any future arising issues that may affect the effectiveness of the proposed project.

References

Friis, R. (2012). Essentials of environmental health. Sudbury, MA: Jones & Bartlett Learning.

Moeller, D. W. (2005). Environmental health. Cambridge, Mass: Harvard University Press.

Morgan, M. (2003). Environmental health. Belmont, CA: Thomson/Wadsworth.

Water Scarcity Problem in Sub-Saharan Africa

Water shortage is a major problem in the world. Ironically, water is the most abundant natural resource in the world. Since the world has water in abundance, it is necessary that more be done to address the shortage of clean water. For instance, just 1% of world water can be accessed. It is necessary that countries focus on harvesting 98% of abundant water. Several studies have been done to explore ways of desalinating seawater for use. However, little has been done to implement it in various parts of the world. Evidently, the cost of desalination has been an obstacle to the proposed utilization of oceanic water (United Nations 1).

Given the high population growth expected in the coming decades, it is important that the world take the issue of water shortage seriously. All along, countries have shown little concern for water-related issues. In fact, Sub-Saharan Africa suffers from the worst water shortage in decades. Moreover, available water sources are not safe for drinking due to pollution. Waste disposal is a major concern in these countries. This has polluted water in the countries, especially in rural areas. Developing countries need to implement ways of collecting water during rainy seasons for use in dry seasons. This can be done by digging dams as water reservoirs. In addition, they need to facilitate water treatment to ensure that people access clean water. In essence, they need to first utilize available water efficiently before exploring ocean water (Web of Creation 1).

Developed worlds have moved ahead in their steps to utilize salty water. In fact, desalination has been tested in Australia, Israel, and the United States, among other countries. Israel is already utilizing desalinated water for its activities. In addition, it has been shown that over time, the cost of desalination reduces. In essence, the world can access safe drinking water for all. The world is facing a water crisis since most rivers either have reduced in density or have turned to seasonal rivers. Water catchment areas have also been exhausted. Still, water tables have started to fall. Research indicates that more than 70% of water is utilized for irrigation. This proves the point that the food supply has contributed greatly to the water shortage. For instance, nearly 40% of grain harvest comes from irrigated land. In essence, this begs the question of whether we are creating a food bubble economy (United Nations 1).

In addition, nearly twenty percent of water is utilized in industries. This leaves just 10% of water for domestic use. It is also estimated that nearly 4.8 billion of water is flushed down the toilet in the United States alone. This shows that efficient water use is still required to help address the water shortages. Moreover, other avenues such as desalination, among others should be considered to relieve pressure on freshwater sources. Water levels in freshwater lakes have seen a tremendous drop. For an instant, Lake Victoria, the second-largest freshwater lake in the world has experienced a significant drop in water levels over the past century. It is necessary that stakeholders consider alternative water sources for both irrigation and industrial use. This would relieve the exhaustion of freshwater sources, which can be treated and used for domestic purposes. A question that may arise is whether desalination can be economically viable for irrigation purposes. Moreover, stakeholders should consider recycling industrial water for irrigation (Web of Creation 1).

Works Cited

United Nations. 2013. Web.

Web of Creation. 2009. Web.

Water and Soil Resources Issues in the Middle East

Water Scarcity in the Middle East

The political and communal discontent of the individuals in the Middle East has taken the attention away from the continuing trials facing the Middle East. A tough amalgamation of swift populace growth, redundancy, and deficiency are aggravated by water scarcity  conceivably the most obstinate of existing longstanding problems (Dolatyar and Gray 114). A report on water scarcity generated by a team of external intelligence agencies expects that the probability of fight over the liquid resource will intensify in the next one or two decades. The report dwells on the importance of the water scarcity issue for the Middle East.

The latter is perhaps the most disadvantaged area of the world when it comes to liquid resources. Water scarcity will produce even more conflicts in the future if the issue is not addressed. Nevertheless, these issues offer the countries in the Middle East the prospect to team up and reinforce consensual and multidimensional bonds (Dolatyar and Gray 120). In other words, to make the most of the opportunity that has been restrained by the intelligence estimations. Proper management of existing liquid resources in the area will be central in evading adverse externalities connected to declining water supplies. The fact is, transcontinental nature of the most important Middle Eastern water sources requires cooperation on an international level.

High Evaporation Rates

The issue of high evaporation rates arises from the origins and causes of water supply conflict in the three chief transnational bodies of water of the Middle East. These include the Jordan-Yarmuk, the Tigris-Euphrates, and the Nile. The high evaporation rates inherent in the Middle East are the consequence of descending air, southerly location, and northeast airstreams. Only three countries  Iran, Turkey, and Lebanon  have a precipitation level acceptable for the populace needs.

Their natural rocky features seize the precipitations due to the westerly airstreams in wintertime. As a consequence, substantial fragments of all neighboring countries are exposed to water scarcities (Dolatyar and Gray 131). Moreover, due to high evaporation rates, rainfall is unbalanced. High evaporation rates are contributing to the water resource conflicts by reason of an increasing number of residents, financial progress, higher standards of living, technical innovations, radical disintegration, and mediocre management of water resources. High evaporation rates also sparkled immigration to the Jordan-Yarmuk area (Sowers and Weinthal 620).

More than half of the Middle East populace lives in city areas where residents consume up to 12 times more water than the residents in rural locations. Water is unexploited in irrigation structures and massive dams with artificial lakes where evaporation arises.

Increasing Plant Cover, Preventing Soil Erosion and Loss of Soil Nutritients

The necessity of incorporating practices to condense nutrient loss is one of the crucial aspects connected to agriculture in the Middle Eastern nutrient decrease approach. The evaluation performed in combination with the policys elaboration split the efficient nutrient decrease methods into three different groups  nitrates and phosphates supervision, land usage, and erosion control. The evaluation also recognized advantages, disadvantages, and established projected costs for the adoption of this practice. Numerous nutrition reduction practices would appear in the Middle Eastern countries that take into consideration the distinctions of existing practices.

There are several practices that have been confirmed to have the utmost potential to make a momentous influence on cutting the loss of nitrates and phosphates contained in the water (Chenoweth et al. 20). These practices are valid for the majority of areas in the Middle East. Land usage decisions substantially modify the dynamics of nitrogen and phosphorus by altering the vegetative cover. These methods also contain constant energy crops, nibbled grasslands, and soil withdrawal. Erosion control methodologies allow effective removal of nitrates and phosphates from liquid waste emissions. These techniques include drainage water supervision, swamplands, bioreactors, and precipitation control.

Prevention of Respiratory Disorders

Particulate matter is a common air contaminant that is made up of a blend of solid and fluid elements deferred in the air. Particles can either be discharged directly into the atmosphere or be produced in the air from gassy precursors such as oxides of nitrogen, ammonia, and non-methane unstable organic composites. It is assessed that around 5% of deaths connected to heart diseases and 7% of lung cancer deaths are bound by particulate matter worldwide.

Primary particulate matter and the precursor vapors can have both synthetic and natural origins. One of the ways to prevent respiratory disorders connected to the particulate matter would be to implement thermal overturns that make air conditions exceedingly susceptible and help to stop polluting particles from being discharged. There are numerous practices intended to reduce the adverse impact of air pollution (Sowers and Weinthal 613).

These measures vary from supervisory actions (severer atmosphere quality control, restrictions for discharges from several sources) and organizational transformations (energy-saving techniques, the substitution of means of transport, and land use development) to personal behavioral transformations (for instance, driving electric cars or using different energy sources at home). The advantages of this preventive strategy are obvious, and it is highly recommended to implement it in the Middle Eastern countries as soon as possible.

Works Cited

Chenoweth, Jonathan, Panos Hadjinicolaou, Adriana Bruggeman, Jos Lelieveld, Zev Levin, Manfred Lange, Elena Xoplaki, and Michalis Hadjikakou. Impact of Climate Change on the Water Resources of the Eastern Mediterranean and Middle East Region: Modeled 21st Century Changes and Implications. Water Resources Research 47.6 (2011): 16-34. Web.

Dolatyar, Mostafa, and Tim Gray. Water Politics in the Middle East: A Context for Conflict or Cooperation? Basingstoke: Macmillan, 2012. Print.

Sowers, Jeannie, and Erika Weinthal. Climate Change, Water Resources, and the Politics of Adaptation in the Middle East and North Africa. Climatic Change 104.3 (2011): 599-627. Web.

Sustainability: Domestic Water Usage

Hot water usage rate per day is very high and expensive. This is attributed to a lot of power that is consumed when heating 41 gallons of water I use daily. Based on the results obtained, the most of water is used on showed and dishwashing. What drives me to use water is the desire to be clean and protect myself from microbes and diseases caused by these organisms.

Thus I can be classified as an above average water user. Much of the hot water is used when cleaning and washing, with the shower making up to 43% of the 41 gallons and washing clothes making up to 29%. It is important that I use less water on laundry and shower as it will be economically sustainable and will saves the environment and energy sources for future generations.

Households in many developed countries constitute approximately one third of the total water and energy consumption. Most people in these countries have washing machines and bathrooms that consume much water and energy. Much of the water usage is associated with cleanliness practices such as washing clothes and showers that are culturally or socio-technically dynamic. This practices lead to high energy and water consumption in many households that in turn affects the overall global climate. For years, utility companies and authorities have intensified campaigns in an attempt to conserve energy and water. Instead, there has been a rising trend in laundering and showering over the past few decades (Gram-Hanssen 20).

From the quantitative analysis carried out, teenagers have been found accountable for a significantly high consumption of household water and electricity compared to the adults. The standing rationale for their traditional routines is associated with the desire to avoid smelling and odor and transition from childhood to adults. In connection with cleaning activities, washing machines are run at least twice a day. This implies high energy consumption by the household laundry machines (Gram-Hanssen 19).

Parents have been found to control their childrens bathing and shower habits through the way they think and act until when they reach a school age. At teenage age, they become very concerned about their body cleanliness and take shower frequently disregarding their parents opinion. Young people lead lifestyles that associate them with a particular group of teenagers who have a specific standard of cleanliness. The female teenagers shower regularly and change clothes often to maintain a certain level of cleanliness.

There is a connection between economic, cultural and social status of families, thus there is difference in behavior between the higher and lower classes. For instance, poor families in the community learn to save the little water that they have by taking shorter showers that are not frequent.

Parents have high influence on the cleaning habits developed by their children, but as children grow up to the adolescent stage, these habits tend to change as people changed their environment and now their cleaning habits are influenced by school mates and friends. Basically, their cleaning habits are predominantly influenced by their social environment.

This is the period when the processes of self-expression and self-construction are underway and teenagers need regular confirmation of self  identity. This exerts peer pressure from friends and classmates to maintain cleanliness matters (Gram-Hanssen 21).

Many people are aware of the relations existing between water and energy consumption and the world environment and economy. There is no direct influence of environment or economy on cleanliness habits. Water and energy are the most utilized commodities by teenagers. This is attributed to the teenagers transitional nature as they are transformed from children to adults. This can help in understanding the difficulty in changing cleanliness practices. Parents care about the environment, but they are afraid to table discussions touching on changing house hold habits that waste water and energy. They fear that this might trigger conflict with their teenagers, like telling them to take shorter showers or doing it less frequently (Gram-Hanssen 22).

As much as the research findings in Denmark are concerned, there is a relationship between standards of cleanliness, age and culture. Well, compare these results with the US results which are quite similar.

From the check sheet on domestic water use, it is evident that much of the water is used during taking shower. Hence, more energy is consumed on heating bathing water. The environmental implication of this practice is exhaustion of energy resources that are already strained. If the quantity of water used during showering and washing can be reduced, it would help to move towards sustainable development.

I can be willing to change my behavior and use lesser water while taking shower provided that my cleanliness standards are maintained at acceptable levels. This would reduce my electricity bills and save the worlds precious energy resources that continue to be used unsustainably.

Works Cited

Gram-Hanssen, Kirsten. Teenage consumption of cleanliness: how to make it sustainable? Sustainability: Science, Practice, & Policy. 3.2 (2007): 1523. Print.

The Consequences of Using Tap and Bottled Water

Written by Cynthia R. Haller, the article Walk, Talk, Cook, Eat: A Guide to Using Sources presents a dialogue between a student Marvin and a professor. Marvin is interested in the topic of water pollution and intended to compare the consequences of using tap and bottled water. To research this issue, he needs credible sources. In the article, Walk, Talk, Cook, and Eat, I was impressed by the professors response to Marvin: you might think about using sources such as walking, talking, cooking, and eating (Haller 195). Using the word walking, the professor means searching for the required information, while talking is a dialogue with the authors of the sources. Cooking is implementing the information in the paper to achieve new conclusions, and eating implies allowing the sources to change the perspective. This comparison appears to be an illustrative example, of how to apply sources in a paper correctly.

Therefore, the article appeared to help understand how to conduct research appropriately and write a high-quality paper on its basis. It supplied a precise explanation, which is highly likely to prevent the most common mistakes in writing assignments. In addition, the methodology is easy to be understood by a reader, as it is presented in the form of a conversation between a student and a professor. Thus, the article provides a solution for numerous students, who are puzzled by the requirement to apply sources for their assignments. I would use the method of Walk, Talk, Cook, Eat for completing the writing tasks in my course, as it is a useful guide, on how to make appropriate research for papers in various fields.

The provided materials on finding and applying sources present a helpful guide and cover all the details of this process. I have got acquainted with the criteria of reliable and informative sources, which can be applied in various fields. All the articles and books should match the following requirements: currency, relevancy, authority, accuracy, and purpose (CRAAP Test). Moreover, it is crucial to follow the rules of formatting while implementing a source in a paper. Each course should have correct citations and be included in the list of bibliography (Annotated Bibliography).