Global Warming Archives

Building An Intelligent Drainage System to Prevent Urban Flooding

Apr 24, 2024

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OMRON is Building An Intelligent Drainage System to prevent urban flooding worldwide; regions prone to frequent typhoons and heavy rainfall experience heightened flood risks. Even Dubai’s freak rain, whether through cloud seeding or otherwise, could be of some interest

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Building An Intelligent Drainage System to Prevent Urban Flooding

24 April 2024

In recent years, the escalation of extreme weather phenomena worldwide, fueled by ongoing global warming, has exacerbated climate disasters such as flooding.

Across the world, regions prone to frequent typhoons and heavy rainfall experience heightened flood risks. Many cities struggle to cope with sudden heavy precipitation due to deficiencies in their drainage infrastructure, resulting in problems such as waterlogged streets and flooded subway stations. Residents suffer from many inconveniences, including risks of property damage and injuries.

As a global leader in the field of automation, OMRON has long been committed to creating”innovation driven by social needs” through automation to empower people. In response to the pressing issue of urban flooding, OMRON is actively exploring innovative solutions to preserve the ecological balance of the earth and promote sustainable development of society.

Navigating the Urgency of Urban Drainage

According to recent statistics, flooding has affected 52.789 million people in China throughout the year, resulting in direct economic losses totaling 244.57 billion RMB.

In order to mitigate flooding impacts, the Chinese authorities advocate for accelerating the establishment of a comprehensive urban drainage and flood prevention system that emphasizes ‘source reduction, pipeline discharge, integrated storage and drainage, as well as emergency response protocols.’

Leveraging its three-decade presence in China, OMRON aims to contribute to flood prevention in Chinese cities by establishing a comprehensive intelligent urban drainage system, drawing upon its expertise in the field of automation.

Exploring the Causes of Waterlogging

To address the drainage and flood prevention challenges in City H, OMRON made collaborative efforts with relevant departments to ensure alignment on the construction of an effective drainage system.

OMRON started with the tunnel industry based on its mature business operation and technical expertise in the field. Through extensive technical discussions and consultations with design institutes, owners, and partners, OMRON identified the urgent need to prevent and reduce urban tunnel flooding through enhancing the intelligentization and digitalization of urban tunnels and supporting drainage pumping stations.

Creating ‘Tools’ to Strengthen Integration

During the construction, OMRON conducted in-depth research to achieve data sharing, early scientific warning, and integrated multi-party management of the intelligent drainage system.

“However, in China, there are limited proven cases of urban intelligent drainage systems.” As the head of the Smart City Division, Zhu Liuqiao was under pressure. “Our team not only had to fully communicate with multiple stakeholders, but also encountered technical challenges such as solution formulation, software development, and hardware development.”

Zhu Liuqiao continued, “But we were not discouraged. Everyone brimmed with confidence and responded actively. Leveraging our expertise in presenting professional proposals and rich experiences in project innovation, we facilitated multiple discussions with stakeholders and reached a consensus on the approach to resolving the issues.” The primary challenges in software design stem from the large number of devices and the absence of standardized interface protocols in intelligent drainage systems. “We engaged in extensive discussions and repeated technical testing with partners to ensure the stability, reliability, and security of the intelligent drainage system.” In terms of hardware, the team supplemented third-party system hardware, established selection principles, and conducted multidimensional evaluations of system requirements, finally enabling the successful development of the urban intelligent drainage system. “Now, all our efforts have paid off, and everyone is filled with excitement!”

During the implementation of the intelligent drainage system, OMRON fully leveraged its strengths in sensing, control, AI, and other technologies, offering core technical support for the urban tunnel management platform through data services and value creation. To mitigate and prevent future disasters in City H, OMRON has implemented the following measures to tackle the existing challenges of low integration and decentralized management in the drainage system:

Platform scheduling and remote coordination allows the intelligent management of the drainage system, enabling real-time monitoring of drainage facilities and timely response to problem-solving, thereby improving overall efficiency.
Through measures such as energy conservation, emission reduction, optimization of resource allocation, OMRON has achieved a 30% reduction in operating costs, resulting in improvements in economic efficiency and environmental protection.
Automated management of 51 drainage pumping stations in City H has been accomplished through the utilization of automation control and remote monitoring technology, thus optimizing human resources while improving operation efficiency and management standards.
A comprehensive monitoring and warning system provides full-scale supervision of the urban drainage network, promptly detecting and alerting potential risks and hazards to safeguard the safety of residents and their property.

Intelligent Drainage Management Platform Built by OMRON

Ushering in the Era of Smart Cities

The project aims for City H to become ‘intelligent’, ‘green’, ‘efficient’, and ‘safe’, promoting a more scientific approach to urban flooding prevention management while greatly reducing operational costs. Intelligent management systems have been implemented in urban tunnels and drainage pumping stations alongside continuous early warning monitoring to enable precise flood prevention measures. By utilizing OMRON’s technology and scientific early warning, Cities like City H have successfully transitioned from automated management to intelligent and digital management in urban infrastructure construction to achieve efficient flood prevention.

Urban Tunnel Drainage

Reflecting on the successful application of OMRON’s Intelligent Urban Drainage Solution in City H, Zhu Liuqiao, head of the Smart City Division, commented, ‘OMRON is committed to helping cities achieve intelligent and sustainable drainage management through innovative technologies and comprehensive solutions. We strive to not only address current challenges but also lay the groundwork for future urban development. We hope that our efforts in effectively addressing challenges such as climate change and environmental protection will make our city a better place to live.’

The development of intelligent urban drainage system is an ongoing journey that requires continuous exploration and innovation. In the future, OMRON is dedicated to implementing its new long-term vision ‘Shaping the Future 2030’ and adhering to its corporate philosophy of ‘Contributing to a Better Society’. OMRON will continue to optimize intelligent urban drainage solutions and applications, promote sustainable development of cities, and improve people’s lives.

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The Looming Climate and Water Crisis in the MENA region

Apr 19, 2024

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The Looming Climate and Water Crisis in the Middle East and North Africa

By Mohammed Mahmoud

19 April 2024

Source: Getty

Summary: Addressing water scarcity and improving water management will be immensely important for ensuring the region’s stability, sustainability, and well-being in the face of a changing climate.

INTRODUCTION

The Middle East and North Africa (MENA) region is naturally prone to being hot and dry, in stark contrast with the rest of the world. The region’s arid climate is the primary contributor to its perennial state of water scarcity. When coupled with the region’s limited freshwater supplies and growing demand for water, virtually all MENA countries are facing elevated levels of water stress. The amplifying effects of climate change threaten to increase the gap between water supply and water demand in the region by exacerbating drought conditions. The longer-term consequences of water scarcity that increase this imbalance extend beyond insufficient water availability. Concerns over water quality, critical water infrastructure, and transboundary water cooperation may also compound the region’s existing socioeconomic challenges.

THE CURRENT STATE OF WATER RESOURCES IN THE MIDDLE EAST AND NORTH AFRICA

The MENA region has been widely acknowledged as the most water-stressed region in the world. In fact, according to data from 2019, sixteen of the twenty-five most water-stressed countries in the world can be found in this region (with Bahrain ranked as the world’s most water-stressed country). In this context, water stress is defined as the gap between water supply and water demand for each given country, meaning that the most water-stressed nations are utilizing nearly all of their available water supplies, and any fluctuations to water supply with respect to meeting water demand could trigger periods of water shortage.

Although the MENA region is generally recognized as water-stressed, different parts of the region experience water stress differently. The differences in water vulnerability between countries in the region are highly correlated to the level of access each country has to a range of water resources, both from freshwater and nonconventional water supplies. For example, access to renewable supplies from surface water systems (such as rivers) can place nations at an advantage to countries that have limited ability to draw on freshwater sources (which also include groundwater extracted from subsurface aquifers). Conversely, countries that have extremely limited opportunities to leverage the use of freshwater supplies can mitigate this risk by greatly expanding their utilization of nonconventional water resources (such as desalination and water recycling). Being able to do so is contingent on a country’s financial and development capacity to invest and build water infrastructure that can augment its existing water sources with nonconventional water supplies.

The mostly arid climate and predominantly flat, desert landscape of MENA is not a naturally favorable environment for large surface water systems borne from high-elevation headwaters, but there are a few major exceptions. The Nile River provides a critical water supply to all of its basin states, most especially its two most downstream arid riparians, Egypt and Sudan (which together account for nearly 90 percent of annual water withdrawals from the Nile). In many ways, the Nile is the lifeblood of Egypt: 99 percent of Egypt’s population resides along the floodplain and banks of the river, and the Nile Delta (Egypt’s most fertile region) accounts for 63 percent of Egypt’s agricultural lands.

Much of the recent tensions in the Nile River Basin have centered on the Blue Nile segment of the river, which originates from highland headwaters in Ethiopia and provides 83 percent of the Nile’s annual volume. The construction and subsequent fillings of the hydropower-generating Grand Ethiopian Renaissance Dam has put Ethiopia’s energy security goals at odds with Egypt’s and Sudan’s critical need for the Nile’s water resources. The lack of transboundary cooperation among these three nations on how to manage the Blue Nile conjunctively with respect to the Grand Ethiopian Renaissance Dam and other water infrastructure—especially under prolonged drought conditions brought on by climate change—will likely result in further unilateral actions that could threaten the viability of the Nile as a water resource for all riparians.

The Tigris-Euphrates River System is another river basin that suffers from transboundary water-sharing challenges. Originating from the mountains of eastern Türkiye, both the Tigris and Euphrates Rivers travel through Syria and most of Iraq before merging together to form the Shatt al-Arab, which terminates in the Arabian Gulf. Much like the Blue Nile segment of the larger Nile River, the water issues in the Tigris-Euphrates River System are associated with consequences of upstream water-use operations on downstream riparians. Prolonged drought conditions in this basin (which have been exacerbated by warming from climate change) have led to a zero-sum game of competing water management needs among the riparians. Türkiye, where the headwaters of both rivers originate, has been moving forward with its own water development projects to secure as much as possible of this surface water resource for its own water security. These projects have had the most negative impact on Iraq, the most downstream riparian in this basin. As a cumulative effect, Türkiye’s dam construction projects have reduced Iraq’s water supply from the Tigris and Euphrates Rivers by 80 percent since 1975. Iran, which contributes to the Tigris-Euphrates River System with tributaries that originate from within its borders, has also pursued dam construction projects that have further reduced the tributary flow into the river system. Future projections estimate that by 2025, the flows of the Tigris and Euphrates Rivers will decrease by 25 percent and 50 percent, respectively. The consequences of this diminished river flow are already detrimental for Iraq, resulting in a lack of sufficient potable water in the city of Basra near the river system’s outlet to the Arabian Gulf.

At the root of the water management challenges in the Tigris-Euphrates River System is the lack of binding multilateral agreements between all the riparians of this river system: Türkiye, Syria, Iraq, and Iran. The presence of such a set of agreements that includes all riparians could encourage transboundary cooperation, which would disincentivize the current state of unilateral water operations that disproportionately harm downstream riparians. A number of agreements already have been put into place within this basin, but these have been bilateral in nature between only a couple of the riparians and have had broad stipulations on cooperation. Examples include the 1987 Protocol on Economic Cooperation between Türkiye and Syria (an interim agreement on water quantity to be released at the Syrian-Turkish border) and the 1990 Syrian-Iraqi Water Accord (to allocate the water of the Euphrates between Syria and Iraq). To date, water negotiations between Iraq and Iran on shared tributaries have yielded no tangible agreements. Without cooperation between these riparians—especially between the upstream nations of Türkiye and Iran with Iraq—the water quantity and quality of this basin will continue to decline to dangerous and potentially irreversible levels.

Southwest of the Tigris-Euphrates River System is the Jordan River, a surface water basin with headwaters in the Anti-Lebanon Mountains bordering Syria and Lebanon. The river flows southward through Lake Tiberias and pools into the Dead Sea. Although tributaries from Lebanon, Syria, Jordan, and Israel and the West Bank feed into the river, water-sharing of the Jordan River is primarily a management issue between Jordan and Israel. Increasing aridification as a consequence of drought has been a key driver in the large reduction in flow of the Jordan River, with estimates of current flow being equal to 10 percent of the river’s historical average. Less streamflow into the river from the headwaters has translated into shrinking water levels for both Lake Tiberias and the Dead Sea.

But a reduced water supply is not the only factor compromising this surface water basin. The water quality in the Jordan River and of the two lakes that are part of the system (Tiberias and the Dead Sea) has progressively declined to a state that could cause water from this basin to become unusable without extensive and costly water treatment or desalination. Rising salinity and pollution in the Jordan River are byproducts of sewage and solid waste being discharged into the river and irrigation water runoff draining into the river from nearby farms. Irrigation water runoff entering the Jordan River is highly saline because of the salt leached from crops during irrigation, and it contains chemical contaminants from pesticides applied to crops. This contamination not only threatens the water quality of the Jordan River but also is a risk to nearby groundwater aquifers, into which these pollutants may seep and infiltrate.

Though surface water systems are limited, groundwater aquifers are much more prevalent across the region. As such and historically, groundwater has been a key source of freshwater supply in the region, especially in areas with no access to surface water, including the Arabian Peninsula and the Gaza Strip in Palestine. The most prominent example of groundwater utilization and extraction in the region is Libya’s Great Man-Made River Project, a large-scale water infrastructure project borne out of Libya’s dependency on groundwater and lack of surface water supplies. This historical overreliance on groundwater resulted in the overpumping of coastal aquifers near major Libyan cities in the northern part of the country, prompting the need to transport water from further aquifers in the south. The Great Man-Made River Project would become the means of this water conveyance. Originally, the project was justified as a more cost-effective alternative to desalination, but the scale of the project has made it costly in terms of construction, maintenance, and energy consumption to pump and distribute the extracted groundwater. Furthermore, project expansion and upkeep have been threatened by unreliable financial support and security risks from vandalism and crime. Ultimately, groundwater is a finite resource, which presents the question of what happens to a huge, costly project like the Great Man-Made River Project when the aquifers on which it relies are no longer sustainable.

With the inclusion of alternative non-conventional water supplies across the region, primarily desalination, groundwater has been mainly used to satisfy drinking water and irrigation needs. But even with a diversity of water supply sources available, this resource is still very much at risk of overdraft, as the regional extraction of groundwater far exceeds the natural and artificial replenishment of exploited aquifers. Much of the challenge of managing groundwater is associated with several primary issues. First, there is not sufficient information or adequate quality of data to accurately determine how much groundwater is stored in the region’s aquifers. Irregular monitoring and tracking of groundwater extraction, as well as the replenishment of these aquifers, all contribute to this lack of data. This is an issue across MENA, as on-the-ground monitoring networks in this region are not as robust as in other parts of the world, necessitating a greater reliance on satellite information or modeling data. Second, as an extension of the lack of information issue, there is little to no regulation of groundwater aquifers in the region, which makes managing and sharing transboundary aquifers even more difficult. Usually, nations that share mutual aquifers do not have conjunctive management operations.

The most important water augmentation innovation that has buffered the countries of the region against limited freshwater supplies and water stress is desalination. Although most MENA coastal nations have active desalination plants, none of the countries in the region are as reliant and dependent on desalination as the countries of the Gulf Cooperation Council (GCC): Kuwait, Bahrain, Saudi Arabia, Qatar, the United Arab Emirates, and Oman. Nearly half of the world’s freshwater desalination (45 percent) occurs in the Arabian Gulf, with several GCC members sourcing nearly 90 percent of their drinking-water needs from desalination.

The use of desalinated water has enabled the GCC and other countries in the region to help bridge the gap in the imbalance between their water supplies and water demands. But the construction, operation, and maintenance of water desalination plants is a costly, lengthy (in terms of design and construction), and energy-intensive enterprise. And while the financial resources of the GCC states, and their dire need for water resources in extremely water-scarce environments, make desalination a palatable water acquisition strategy, other countries in the region may not have the capacity and capital to follow suit. Additionally, concerns have been raised as to the environmental impact of this level of desalination activity in the region—especially in the Arabian Gulf—because of the volume of concentrated brine discharge that is released back into the source water body of the desalinated water. But recent research has indicated that the Arabian Gulf is not under risk of elevated salinity caused by the discharge of brine from the many desalination plants along the Gulf’s coast. Even though the research studies denote that this finding may be true in the Arabian Gulf for the coming decades, there is still some uncertainty if this finding could remain valid further into the future with an increased number of and expanded capacity of desalination plants along its coast.

EFFECTS OF GLOBAL WARMING ON REGIONAL CLIMATE

According to the Koppen Classification System, most of the MENA climate can be described as a hot desert environment that is consistent with a dry climate zone. Thus, as a region it is naturally prone to aridity, little rainfall, sparse vegetative land cover, and higher average annual temperatures, especially during the summer period where temperature extremes are more pronounced than other parts of the world. These conditions already have put the MENA region in a natural environmental state that increases the likelihood of extreme water scarcity. However, the accelerated advent of climate change has added a layer of complexity when it comes to the region’s climate and its water resources.

Over the past decade, the growing impacts of climate change in MENA countries have been adverse, with direct implications for the reliability of the region’s water supply and infrastructure to satisfy its various types of water demand. The primary climate impact that drives several implications associated with water insecurity is extreme heat and warming. In recent years, the Middle East, a region already experiencing significantly warmer temperatures than most of the rest of the world, has seen an elevation of daily temperature highs above the historical average for the region. Progressively, during the summer periods in the past several years, a number of countries and cities in the region have broken historical records for daily temperature highs. For example, in July 2023, the Persian Gulf Airport in Iran registered a heat index of 152°F (the heat index being a metric that couples the effect of humidity with air temperature to gauge the perceived heat that humans experience). This extreme level of heat coincided with the hottest month ever recorded, where the global average temperature record was broken and set three times over a span of four days (from July 3 to 6).

Even as climate change has increased air temperatures in the region, a similar effect has been occurring in the surrounding oceans and seas. A corresponding rise in sea surface temperatures has yielded dangerous outcomes with regard to extreme weather. Warmer oceans and seas tend to generate more extreme weather in the form of severe thunderstorms and even cyclones. And while precipitation and rainfall can be considered boons for a mostly dry and arid region like MENA, the intensity of rainfall, winds, and subsequent flooding from these storm events can be catastrophic.

Heavy rainfall events that have produced expansive flooding have been occurring with more frequency in MENA. This is especially the case for the countries of the Arabian Peninsula, an area surrounded by the Arabian Sea and Indian Ocean, two water bodies that experience significant warming during the summertime owing to their proximity to the equator. These heavy thunderstorms and corresponding floods have particularly afflicted the countries in the southern part of the Arabian Peninsula: Oman, Saudi Arabia, the United Arab Emirates, and Yemen. And while these types of storms have been most pronounced along the southern coastline of the Arabian Peninsula, severe weather has even made it as far inland as Mecca, Saudi Arabia.

In extreme cases, these types of storms are intense enough to be categorized as tropical cyclones. Such severe storms can cause catastrophic flooding that results in substantial infrastructure damage and fatalities. The frequency of these types of tropical cyclones forming in the Indian Ocean and making landfall at a high level of severity is relatively low, but they do occur to devastating effect. Both Oman and Yemen have been the primary recipients of these tropical cyclones. In 2021, Cyclone Shaheen made landfall in Oman as a severe cyclonic storm. The heavy rainfall, excessive flooding, and high winds of the cyclone caused serious damage to infrastructure and a considerable death toll. With the likelihood of increased global warming in the future, tropical cyclones may form and make landfall at greater frequency and intensity, with the potential of traveling further inland than the southeastern coastal front of the Arabian Peninsula.

Cyclones have a history of developing from the Indian Ocean in the warmer waters surrounding the equator, but there is growing concern that sea surface temperatures across the globe are rising. Significantly warmer ocean waters will likely produce more extreme weather, even for water bodies that generally are known to produce cyclones and hurricanes (like the Indian Ocean and the Atlantic Ocean). However, an increase in global sea surface temperatures could see extreme weather occur from oceans and seas not historically prone to creating them. This has been the case for the Pacific Ocean, where hurricanes rarely form and make landfall. Historically, the Mediterranean Sea has had similar experiences: it would be unusual for cyclones or medicanes (the term used to refer to cyclones from the Mediterranean Sea) to form and make landfall with severe intensity. But with the amplification of climate change enhancing warming in oceans and seas, both the Pacific and the Mediterranean could see such effects in the future.

An indicator of what a future with extreme weather from the Mediterranean Sea would look like came in September 2023, when Storm Daniel made landfall in eastern Libya. Developing as a medicane and following its trajectory from Greece, Storm Daniel descended into the coastal Libyan city of Derna, causing torrential rainfall and severe flooding. But the tragedy of Derna was not limited to these initial hydrological impacts of extreme weather. The combination of an incredibly large amount of rainfall and the country’s aging and neglected infrastructure led to the collapse of two dams upstream of Derna—Derna Dam and Mansour Dam. The outcome of that critical failure of water infrastructure was nothing short of catastrophic. Entire neighborhoods and large parts of the city of Derna literally washed out to sea under the massive release of water from these collapsed dams, further inundating a city already submerged with floodwaters. The death toll from this climate calamity is in excess of 10,000 people, and that figure is expected to rise as an equally large number of missing people are still unaccounted for.

It is clear that the warming of the oceans and seas surrounding MENA has direct implications when it comes to producing extreme weather that can affect the countries of the region. But in conjunction with these short-term, yet intense and potentially more frequent, weather events is another more long-term and incremental impact from the warming of the oceans: sea level rise. The threat of sea level rise will only continue to increase in the future, as the Sixth Assessment Report of the Intergovernmental Panel on Climate Change indicated that sea level rise due to ocean warming from greenhouse gas–driven global warming will continue for centuries. What is equally alarming is that even if global warming is curbed by fully mitigating greenhouse gas emissions, the coastal encroachment resulting from sea level rise at that point in time will be irreversible for further centuries.

IMPLICATIONS OF THE CLIMATE/WATER NEXUS ON THE MIDDLE EAST AND NORTH AFRICA

The regional climate effects of global warming on both land and sea have direct consequences for managing the region’s water supply, water demand, and water infrastructure. Warming is a key driver of drought conditions, especially for surface water systems. Significantly warmer conditions affect surface water systems in several ways. For surface water systems that rely on water being generated from higher-elevation precipitation and snowpack (which is the case for the Nile River, the Tigris and Euphrates River System, and the Jordan River), climate change can reduce the volume of water that is generated from these higher-elevation headwaters. Because warming can lessen the amount and rate of precipitation that occurs in these higher elevations, the smaller snowpack and subsequent snowmelt from the headwaters would reduce the flow of these rivers. A reduction in snowpack can occur primarily when some of that snowpack sublimates (changes into water vapor directly) owing to extreme heat, as opposed to turning into snowmelt. Also, with higher regional temperatures, the rate of evaporation will likely increase, resulting in less water available downstream as the river experiences elevated evaporation along its route towards its terminus. For countries in the region that utilize a surface water supply source, this reduction in available surface water will cause them to shift more of their reliance on other sources of water supply—placing pressure on alternative sources of water to meet this shortfall.

Warming will also have an effect on water demand in the region. The three broad sectors of water demand are urban or residential water use for human consumption (including for drinking water and sanitation), agricultural water use to support food production, and industrial water use (such as for manufacturing, commercial uses, and energy generation). Rising temperatures in the region have the potential to significantly inflate water demand from these different water consumption sectors as a consequence of their unique water needs.

Agriculture is the largest consumer of water globally, on average amounting to 70 percent of water use. This statistic also holds true for MENA, where most countries’ agricultural water use as a percent of total water withdrawals exceeds 50 percent. In Morocco, Sudan, and Yemen, agricultural water use is close to or higher than 90 percent of total water used. With increased warming, the rate of evapotranspiration from irrigated crops also increases. To counteract this evaporative loss of water from crops due to higher temperatures, irrigation requirements per crop type must also increase to ensure sufficient water has been applied during the growing season. The largest sectoral consumer of water thus will require even more water to meet regional food production needs.

Urban water use (which includes domestic and residential water consumption for drinking water needs and sanitation) accounts for a significantly smaller portion of total water demand in the region (on average approximately 8 percent of freshwater use). But as with agricultural water use, urban water use is also influenced by the region’s warming climate. Inflated urban water use can be linked to the urban heat island effect, where daytime heat from sunlight and warm emissions from vehicles and air conditioners are trapped by heat-absorbing infrastructure and materials (like asphalt in roads). Urban areas also tend to have less natural and green areas, which help to diffuse some of the absorbed heat. During periods of extreme heat, the urban heat island effect can push urban water consumption to higher levels, as urban residents use more drinking water to cool down from the heat and apply more water to maintain green natural spaces in cities.

Another factor that is progressively boosting urban water use is the rate of population growth in the MENA region. In 2022, the average annual population growth across the region was 1.9 percent, with Syria and Yemen leading the annual urban population growth of individual countries at 4.8 percent and 3.8 percent, respectively. Compared to regional annual urban population growth rates in excess of 4 percent pre-1990, the current figure seems modest, but future population growth projections paint a different picture. By 2050, half of MENA countries will see their total populations grow by over 50 percent compared to their population size in 2015. Three nations in particular—Iraq, Palestine, and Sudan—will more than double their population size from 2015.

Impacts to industrial water use are also expected to occur with enhanced regional warming, especially for water needed for energy generation. Hydropower generation is directly affected, as surface river systems with hydropower plants will see reductions in river flows (at the headwaters) owing to higher levels of evaporation. Additionally, water is a critical component of power generation in thermoelectric plants, primarily for cooling purposes to produce electricity more efficiently. Water scarcity as a consequence of climate change can therefore severely constrain a power plant’s ability to efficiently and optimally generate electricity.

Water infrastructure is a critical component of any water management system, as it is the means by which water is transmitted, stored, or treated, to connect the water supply from source to utilization. Unfortunately, several MENA countries do not have reliable and efficient water infrastructure. For example, more than 50 percent of Jordan’s drinking water supply is lost because of water leakages and illegal theft of water from the water transmission network. Similarly, Lebanon is experiencing water system losses of 40 percent as a consequence of illegal water connections and inadequate maintenance of its water transmission network.

The region’s water infrastructure will be even more vulnerable due to the effects of climate change. Extreme heat, extreme weather, and sea level rise threaten the reliability and durability of water storage, treatment, and transmission infrastructure. As higher temperatures from warming elevate evaporation rates, reservoirs and dams used for surface water storage (such as the Aswan High Dam in Egypt or Atatürk Dam in Türkiye) will lose more of their stored water to evaporation. Prolonged exposure to extreme heat over time can reduce the lifespan of critical water infrastructure such as dams, water treatment plants, desalination plants, and water transmission pipelines and canals, thereby increasing the risk of infrastructure failure if adequate repair and maintenance is not implemented.

Extreme weather is an even more immediate threat to critical water infrastructure. High winds, intense rainfall, and flash flooding from severe thunderstorms and cyclones can cause sufficient structural damages that will either force water infrastructure operations offline for repair or, in an extreme case, lead to their catastrophic and irreparable failure (such as what happened to the dams in Derna, Libya). Other types of extreme weather, like the frequently occurring dust storms of the Arabian Peninsula, can also damage water infrastructure.

The future viability of existing coastal water infrastructure and resources is also at risk from the longer-term ramifications of sea level rise. As sea level rise continues unabated in the span of decades and even centuries (as suggested in the Sixth Assessment Report of the Intergovernmental Panel on Climate Change), encroaching seawater will likely inundate and submerge critical water infrastructure such as desalination and water treatment plants along MENA coasts. The corresponding losses of nonconventional water supplies and the ability to produce drinking water from nonpotable sources would be disastrous for the region. It would hurt the GCC countries in particular, as they rely disproportionately on desalinated water to meet their consumption needs. Incremental sea level rise also propagates seawater intrusion into groundwater aquifers near the coast and pushes salty seawater into the coastal outlets of rivers—a problem that is already happening in the Nile River Delta along the Mediterranean in Egypt and the Shatt al-Arab outlet of the Tigris-Euphrates River System to the Arabian Gulf in Iraq.

Besides the water management challenges posed by inadequate water supply, inflated water demand, and precarious water infrastructure integrity, the region could contend with a possible public health crisis from the poor quality of much of its freshwater. As water supplies dwindle and drinking water needs increase because of the effects of warming, disenfranchised segments of the region’s population that live in rural areas or refugee camps, and cannot financially afford to acquire adequate supplies of drinking water, may make difficult and dangerous decisions when it comes to meeting their water needs. This scenario has played out in Syria, where people who are desperate for water have extracted contaminated water from the Euphrates River and utilized it without proper water treatment. Consequently, rural Syria has seen several outbreaks of waterborne illnesses and diseases, the most recent of which is a cholera epidemic that has caused fatalities in the local population.

CONCLUSION

When it comes to the climate-driven water security challenges of the MENA region, several key messages are clear.

Water scarcity and water stress. The region is naturally prone to arid and dry conditions, leading to a chronic state of water scarcity. Limited freshwater supplies and growing demand for water have resulted in elevated levels of water stress across MENA countries.

Regional differences in water stress. Water stress varies across the region, owing primarily to differences in access to freshwater and nonconventional water sources. Countries with access to renewable water supplies have some advantage, while others rely heavily on nonconventional sources like desalination.

The importance of desalination. Desalination has become a crucial water augmentation strategy for mitigating water scarcity in the region. GCC countries in particular mostly rely on desalination for drinking water needs. However, this method is cost- and energy-intensive and could pose some long-term environmental concerns.

Water quality challenges. Poor water quality in freshwater sources poses public health risks, especially in rural areas. Contaminated water sources have led to outbreaks of waterborne diseases.

Groundwater depletion. Groundwater aquifers are a significant source of freshwater, especially in arid regions like the Arabian Peninsula. But overextraction of groundwater is depleting these aquifers.

Transboundary water conflicts. Transboundary water management challenges, particularly in the Nile and Tigris-Euphrates River Basins, have strained relations among riparian nations. The construction of dams and reduced river flows have created tensions, posing a threat to regional stability.

Climate change amplifies water issues. Climate change is exacerbating water insecurity by increasing the frequency and severity of droughts. This new climate reality threatens to widen the gap between water supply and demand, compounding existing water scarcity issues.

Climate change and extreme weather. Climate change has brought about extreme heat waves, severe storms, and cyclones in the region. These events have serious implications for water infrastructure, including reservoirs, dams, and desalination plants.

Sea level rise. In the long term, rising sea levels are threatening coastal water infrastructure, such as desalination plants and water treatment plants. Seawater intrusion into groundwater aquifers and coastal river outlets is also a growing concern.

Impact on water demand. Rising temperatures increase evapotranspiration rates, leading to higher water demands in agriculture and urban areas. Population growth will inflate future urban water consumption, particularly in rapidly growing cities.

Overall, the MENA region faces a multifaceted water crisis that is exacerbated by climate change. Desalination has provided some reprieve to the region’s water deficit, but it comes with its own set of environmental and economic challenges. Transboundary water disputes, groundwater depletion, and the vulnerability of water infrastructure to extreme weather events are pressing issues that require urgent attention. As the region grapples with these complex challenges, addressing water scarcity and improving water management will be immensely important for ensuring the stability, sustainability, and the well-being of its populations in the face of a changing climate.

Mohammed Mahmoud

Mohammed Mahmoud is a water resources management and climate adaptation policy expert and the founding director of the Climate and Water Program at the Middle East Institute. He regularly provides expert analysis on climate change and water security issues in the Middle East and North Africa.

Climate change: yes, your individual action does make a difference

Apr 11, 2024

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What can we do in the face of the climate emergency? Many say we should drive less, fly less, eat less meat. But others argue that personal actions like this are a pointless drop in the ocean when set against the huge systemic changes that are required to prevent devastating global warming.

The above image is for illustration credit to Vox

Climate change: yes, your individual action does make a difference

Steve Westlake, Cardiff University

It’s a debate that has been raging for decades. Clearly, in terms of global greenhouse gas emissions, a single person’s contribution is basically irrelevant (much like a single vote in an election). But my research, first in my masters and now as part of my PhD, has found that doing something bold like giving up flying can have a wider knock-on effect by influencing others and shifting what’s viewed as “normal”.

In a survey I conducted, half of the respondents who knew someone who has given up flying because of climate change said they fly less because of this example. That alone seemed pretty impressive to me. Furthermore, around three quarters said it had changed their attitudes towards flying and climate change in some way. These effects were increased if a high-profile person had given up flying, such as an academic or someone in the public eye. In this case, around two thirds said they fly less because of this person, and only 7% said it has not affected their attitudes.

I wondered if these impressionable people were already behaving like squeaky-clean environmentalists, but the figures suggested not. The survey respondents fly considerably more than average, meaning they have plenty of potential to fly less because of someone else’s example.

Flights can make up a big part of your carbon footprint.
motive56 / shutterstock

To explore people’s reasoning, I interviewed some of those who had been influenced by a “non-flyer”. They explained that the bold and unusual position to give up flying had: conveyed the seriousness of climate change and flying’s contribution to it; crystallised the link between values and actions; and even reduced feelings of isolation that flying less was a valid and sensible response to climate change. They said that “commitment” and “expertise” were the most influential qualities of the person who had stopped flying.

Letting fly

It’s not all a bed of roses, of course. Flying represents freedom, fun and progress. It boosts the economy and can provide precious travel opportunities. So suggesting that everyone should fly less, which may seem the implicit message of someone who gives up flying because of climate change, can lead to arguments and confrontation. One person for example said that my gently worded survey was “fascist and misinformed”. You don’t get that when you ask about washing-up liquid.

My research also probed ideas of inconsistency and hypocrisy. In short, people hate it. If Barack Obama takes a private jet and has a 14-vehicle entourage to get to a climate change conference, or a celebrity weeps for the climate while rocking a huge carbon footprint, it doesn’t go down well. And if future laws are introduced to reduce flying because of climate change, it looks essential that politicians will have to visibly reduce their flying habits, too. Other research has shown that calls for emissions reductions from climate scientists are much more credible if they themselves walk the talk.

That people are influenced by others is hardly a shocking result. Psychology researchers have spent decades amassing evidence about the powerful effects of social influence, while cultural evolution theory suggests we may have evolved to follow the example of those in prestigious positions because it helped us survive. Pick up any book on leadership in an airport shopping mall and it will likely trumpet the importance of leading by example.

Which raises the question: if our political and business leaders are serious about climate change, shouldn’t they be very visibly reducing their own carbon footprints to set an example to the rest of us? This is now the focus of my research.

But why me?

Weaving an invisible thread through all of the above is the thorny issue of fairness and inequality. The wealthiest 10% of the global population are responsible for 50% of emissions, and plenty of that will be due to flying. In the UK, around 15% of people take 70% of the flights, while half of the population don’t fly at all in any one year. As emissions from aviation become an ever increasing slice of the total (currently around 9% in the UK, 2% globally) this inequality will become harder for everyone to ignore.

In the mean time, the debate about personal vs. collective action will continue. My research supports the arguments that this is a false dichotomy: individual action is part of the collective. So, while you won’t save the world on your own, you might be part of the solution.

Click here to subscribe to our climate action newsletter. Climate change is inevitable. Our response to it isn’t.

Steve Westlake, PhD Researcher in Environmental Leadership, Cardiff University

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Nomadic traditions, modern realities

Apr 1, 2024

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Nomadic traditions, modern realities — Exploring Bedouin culture by Saeb Rawashdeh is not an April Fool’s Day. It clearly and accurately depicts the countryside and its inhabitants of the Kingdom of Jordan.

Image above: The arid landscape of Wadi Feynan was known in ancient times for its copper production (Photo courtesy of ACOR/ Barbara Porter Collection)

Nomadic traditions, modern realities — Exploring Bedouin culture

By Saeb Rawashdeh – 1st April 2024

AMMAN — The name “Bedouin” is derived from the term for nomadic desert or steppe dwellers (badawa). It is not an ethnic name and is used to refer to populations across the steppes and deserts of the Arab world who are associated with a nomadic-pastoral-tribal way of life.

“They were romantically described by early travellers to the Near East in the 19thand early 20thcenturies, who saw them as the living representation of biblical nomadic folks. Bedouin were presented as camel breeders migrating far across the steppe landscape, their travels promoted by the invention of the camel saddle and, as a corollary, the black long tents,” noted Danielle Vos from the Groningen University. Bedouins were portrayed as fierce, rugged and having warlike tendencies and a disdain for authority, but also as great hosts and honourable individuals with proud oral traditions.

Vos added that the notion of the “true” Bedouins as camel breeding nomadic tribes venturing deep into the desert is also idealised in the Near East and among Bedouin tribes themselves.

In fact, the role of Bedouins evolved through time and they became farmers, cattle raisers, sheep herders, sometime brigands.

It is a combination of these social roles since the society changed and their role evolved.

Vos categorises three common types: one having a “proper” nomadic existence, raising only camels and some horses; another consisting of sheep herders that have some contact with settlements in the area; and those belonging to the third type who maintain a migration that is restricted to the peripheries of villages and towns, where produce from animal husbandry can be sold.

“Bedouin’s ways of life at Wadi Faynan today include a variety of subsistence strategies, of which sheep and goat herding, cultivation and involvement in the local tourist industry are the most prominent,” Vos said, adding that subsistence strategies in the area both take advantage of, and need to adjust to a number of environmental, social, economic, political and personal circumstances.

As opportunities and restrictions arise, lifestyles change in order to make the most of them; also,the natural setting of Wadi Faynan is important for understanding patterns of mobility, as it allows its inhabitants to exploit different landscapes throughout the year.

The Wadi Faynanis located in the desert to the east of the Rift Valley south of the Dead Sea, and is bordered by the Wadi ‘Araba in its southern and western margins and by the Mountains of Edom and the Jordanian Tablelands to its east and north. The area is characterised by a typical desert climate.

The Araba rift structure in the Faynan area contains an abundance of mineralised rocks, which have provided the inhabitants of the region with a source of copper for the past three millennia.

Archaeological indications of copper mining at Wadi Faynan suggest that the mineral sources in this area were utilised at an industrial scale and the area was part of the Assyrian, Babylonian, Egyptian, Persian, Roman and Byzantine empires.

“Seasonality is a chief aspect of the region’s climate, with precipitation mainly restricted to the winter months December to March, and virtually absent between June and September,” Vos elaborated.

While the Wadi Faynan area only receives 63 mm annual rainfall, the higher grounds of the Jordanian Tablelands enjoy more than 200 mm of precipitation yearly, Vos said, adding that summer is hot and dry, being influenced by the climate of the Saharo-Arabian desert to the southeast, with temperatures averaging at 29°C and occasionally reaching over 38°C in the wadis.

“Strong winds can occasionally sweep through the Wadi, which in combination with the aridity are a cause of deflation and the redistribution of dust and sand. Although the strongest storms usually take place during the winter months, windy episodes may occur all year round ,” Vos stressed, noting that vegetation in the area reflects the complex relationships between topography, rainfall and geology between the Wadi ‘Arabah and the Mountains of Edom, and as a whole southern Jordan forms a meeting point for the Mediterranean, Irano-Turanian and Saharo-Arabian zones.

Furthermore, in areas of sufficient precipitation forestation will form, while low rainfall will result in steppe vegetation, or, where precipitation does not exceed 100 mm, a desert, she highlighted, stressing thatthe different micro-environments created by the area’s topography and climate are well exploited through transhumance mobility.

“In practical terms, at Wadi Faynan, this translates to moving up to the highlands which are cooler than the lowlands during the hot summers, and then down into the Wadi over the winter, where the Wadi floor provides grasing and shelter throughout the cold rainy months,” Vos continued, saying that the extent to which this is done depends on the subsistence strategies chosen at any given moment.

Previously, the tribes that visited Wadi Faynan were mostly semi-nomadic or semi-sedentary pastoralists, but all rural communities in the region were nomadic to some extent, depending on their involvement with agriculture and pastoralism.

“Today, permanent occupation of Wadi Faynan is common not only by villagers, but also with the four main local Bedouin tribes, and is facilitated by the use of supplementary fodder for the animals, Vos said, adding that within a range of practices between pure pastoralism, referring to raising livestock on natural pasture, and agriculture, within the sense of crop cultivation, communities that rely heavily on pastoralism tend to be more mobile than the ones relying entirely on agriculture.

Therefore, nomadism can be defined as the regular mobility of households/home bases from place to place, but the duration of migration and settlement episodes may vary and, in most cases, migration will be seasonal with varying duration and distance, spending a certain amount of the year near a permanent dwelling, usually during winter.

The economic progress and reforms implemented by Jordanian governments directly and positively affected the life of Bedouins in Wadi Faynan. Like in other areas of the country, the local communities became protectors and active participants, interacting with scholar teams. Government invested in various infrastructural projects-roads, hospitals, schools and universities.

The Natural Resources Authority camp at Wadi Faynan became a base for archaeological fieldwork, providing employment opportunities for local individuals. The establishment of the Dana Nature Reserve in 1993 (which borders with Wadi Faynan at its southern end) provided work prospects as well.

“Today, the area enjoys a flourishing tourism industry, including the Faynan Ecolodge, an environmental friendly hotel providing employment opportunities for many of the local Bedouins,” Vos said.

Solution To Energy Storage May Be Beneath Your Feet

Mar 30, 2024

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The above image is for illustration purposes – Keith Hardy

keithhardy2001

Solution To Energy Storage May Be Beneath Your Feet

US Department of Energy

Published on CleanTechnica, 30 March 2024

Anyone who has ever hot-footed it barefoot across the beach on a sunny day walks away with a greater understanding of just how much heat sand can retain. That ability is expected to play a vital role in the future, as technology involving heated sand becomes part of the answer to energy storage needs.

Batteries are likely what most people think about in terms of storing energy for later use, but other technologies exist. Pumped storage hydropower is one common method, albeit one that requires reservoirs at different elevations and is limited by geography. Another approach relies on what is known as thermal energy storage, or TES, which uses molten salt or even superheated rocks.

*Researchers Shin Young Jeong and Zhiwen Ma examine the prototype device that uses superheated sand for long-duration energy storage. Photo by Joe DelNero, NREL.*

TES shows promise as a low-cost alternative to existing storage technologies, and storing energy in solid particles such as sand provides a ready answer, without geological restrictions.

After all, sand, like air and water, is everywhere.

“Sand is easy to access. It is environmentally friendly. It is stable, quite stable, in a wide temperature range. It is also low cost,” said Zhiwen Ma, a mechanical engineer in the laboratory’s Thermal Energy Systems Group.

The Need for Long-Term Storage

Patented technology developed and prototyped at NREL reveals how heaters powered by renewable energy sources like wind and solar can raise the temperature of sand particles to the desired temperature. The sand is then deposited into a silo for storage and use later, either to generate electricity or for process heat in industrial applications. A laboratory-scale prototype validated the technology and allowed researchers to create a computer model that shows a commercial-scale device would retain more than 95% of its heat for at least five days.

“Lithium-ion batteries have really cornered the market at two to four hours of storage, but if we want to achieve our carbon reduction goals, we will need long-duration energy storage devices—things that can store energy for days,” said Jeffrey Gifford, a postdoctoral researcher at NREL.

Gifford, who already shares two patents with Ma on heat exchangers that convert stored thermal energy to electricity, said the use of sand or other particles to store thermal energy has another advantage over batteries. “Particle thermal energy storage doesn’t rely on rare-earth materials or materials that have complex and unsustainable supply chains. For example, in lithium-ion batteries, there are a lot of stories about the challenge of mining cobalt more ethically.”

In addition to TES, Gifford’s expertise is in computational fluid dynamics. That knowledge is important because the sand needs to flow through the storage device. Other TES media includes concrete and rocks, which can easily retain heat but remain solidly in place. “Your heat transfer is much higher and much quicker and much more effective if you’re moving your media,” Gifford said.

TES also has another key advantage: the cost. Ma has calculated sand is the cheapest option for energy storage when compared to four rival technologies, including compressed air energy storage (CAES), pumped hydropower, and two types of batteries. CAES and pumped hydropower can only store energy for tens of hours. The cost per kilowatt-hour for CAES ranges from $150 to $300, while for pumped hydropower it is about $60. A lithium-ion battery would cost $300 a kilowatt-hour and only have a capacity to store energy from one to four hours. With a duration lasting hundreds of hours, sand as a storage medium would cost from $4 to $10 a kilowatt-hour. To ensure low cost, the heat would be generated using off-peak, low-price electricity.

Ma, who holds a handful of patents on the technology, previously served as the principal investigator on an ARPA-E funded project known as ENDURING, for Economic Long-Duration Electricity Storage by Using Low-Cost Thermal Energy Storage and High-Efficiency Power Cycle. The prototype came from this project. Next up is the groundbreaking in 2025 on an electric thermal energy storage (ETES) system at NREL’s Flatirons Campus outside Boulder, Colorado, that will be designed to store energy for between 10 and 100 hours. The stand-alone system is free from any siting restrictions that limit where CAES or pumped storage hydropower can be established.

The DOE-funded demonstration project, Ma said, is intended to show the commercial potential of sand for TES.

Molten salts are already in use to temporarily store energy, but they freeze at about 220 degrees Celsius (428 degrees Fahrenheit) and start to decompose at 600 C. The sand Ma intends to use comes out of the ground in the Midwest of the United States, does not need to be kept from “freezing,” and can retain considerably more heat, in the range of 1,100 C (2,012 F) that can store heat for power generation or to replace burning fossil fuels for industrial heat.

“This represents a new generation of storage beyond molten salt,” Ma said.

Zhiwen Ma and members of his team—(from left) Emre Ustuner, Jason Hirschey, Munjal Shah, Shin Young Jeong, Janna Martinek, and Muhammad Ashraf—exploring the use of superheated sand for long-duration energy storage stand next to a prototype device. Photo by Joe DelNero, NREL.

Deciding What Will Store the Heat

But will just any old sand do? Not according to NREL researchers, who examined various solid particles for their ability to flow and to retain heat. In a paper published last fall, Ma and others experimented on eight solid particle candidates. Among the particles considered were man-made ceramic materials used in fracking, calcined flint clay, brown fused alumina, and silica sand. The clay and fused alumina were rejected because of thermal instability at the target temperature of 1,200 degrees Celsius (2,192 degrees Fahrenheit).

The ceramic materials outperformed the sand in all categories, but the marginal performance gains were considered insufficient to justify the higher cost. While the sand costs from $30 to $80 a ton, the prices of the ceramic materials were about two magnitudes higher. The sand is in the ultra-pure form of alpha quartz and readily available in the Midwest.

Expanding the amount of energy that can be stored in sand is as simple as adding more sand, said Craig Turchi, manager of the Thermal Energy Science and Technologies Research Group at NREL.

“That’s a marginal cost to add additional storage capacity,” he said. “We need storage ranging from minutes to months. Batteries worked really well in the minutes to hours space in terms of how they scale. And when you get into months of storage, you’re usually looking at making a fuel like hydrogen to provide that long-term storage. But in the period between multiple hours and two weeks, there’s not a good fit right now. Hydrogen is too expensive for that. Batteries are too expensive for that.”

The components needed to convert the superheated sand back to electricity does require an upfront cost. “But once you’ve paid for that,” Turchi said, “if you just want to have more duration for your power it’s much, much cheaper to add more sand than the alternative, which is to keep adding batteries.”

By Wayne Hicks. Courtesy of Department of Energy, NREL.

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