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Wikipedia

Water security

February 15, 2024

The aim of water security is to make the most of water's benefits for humans and ecosystems. The second aim is to limit the risks of destructive impacts of water to an acceptable level.[1][2] These risks include for example too much water (flood), too little water (drought and water scarcity) or poor quality (polluted) water.[1] People who live with a high level of water security always have access to "an acceptable quantity and quality of water for health, livelihoods and production".[2] For example, access to water, sanitation and hygiene services is one part of water security.[3] Some organizations use the term water security more narrowly for water supply aspects only.

Water security has many different aspects, in clockwise order from top left: a communal tap for water supply in Soweto, South Africa; residents standing in flood water in Kampala, Uganda; the town of Farina in South Australia abandoned due to years of drought and dust storms; water pollution can lead to eutrophication, harmful algal blooms and fish kills

Decision makers and water managers aim to reach water security goals that address multiple concerns. These outcomes can include increasing economic and social well-being while reducing risks tied to water.[4] There are linkages and trade-offs between the different outcomes.[3]: 13  Planners often consider water security effects for varied groups when they design climate change reduction strategies.[5]: 19–21 

Three main factors determine how difficult or easy it is for a society to sustain its water security. These include the hydrologic environment, the socio-economic environment and changes in the future environment. This last is mainly due to climate change.[1] Decision makers may assess water security risks at varied levels. These range from the household to community, city, basin, country and region.[3]: 11 

The absence of water security is water insecurity.[6]: 5  Water insecurity is a growing threat to societies.[7]: 4  The main factors contributing to water insecurity are water scarcity, water pollution and low water quality due to climate change impacts. Others include poverty, destructive forces of water, and disasters that stem from natural hazards. Climate change affects water security in many ways. Changing rainfall patterns, including droughts, can have a big impact on water availability. Flooding can worsen water quality. Stronger storms can damage infrastructure, especially in the Global South.[8]: 660 

There are different ways to deal with water insecurity. Science and engineering approaches can increase the water supply or make water use more efficient. Financial and economic tools can include a safety net to ensure access for poorer people. Management tools such as demand caps can improve water security.[7]: 16  They work on strengthening institutions and information flows. They may also improve water quality management, reduce inequalities and investment in water infrastructure. Improving the climate resilience of water and hygiene services is important. These efforts help to reduce poverty and achieve sustainable development.[2]

There is no single method to measure water security.[8]: 562  Metrics of water security roughly fall into two groups. This includes those that are based on experiences versus metrics that are based on resources. The former mainly focus on measuring the water experiences of households and human well-being. The latter tend to focus on freshwater stores or water resources security.[9]

The IPCC Sixth Assessment Report found that increasing weather and climate extreme events have exposed millions of people to acute food insecurity and reduced water security. Scientists have observed the largest impacts in Africa, Asia, Central and South America, Small Islands and the Arctic.[10]: 9   The report predicted that global warming of 2 °C would expose roughly 1-4 billion people to water stress. It finds 1.5-2.5 billion people live in areas exposed to water scarcity.[10]: 660 

Definitions edit

Broad definition edit

There are various definitions for the term water security.[11][12]: 5  It emerged as a concept in the 21st century. It is broader than the absence of water scarcity.[1] It differs from the concepts of food security and energy security. Whereas those concepts cover reliable access to food or energy, water security covers not only the absence of water but also its presence when there is too much of it.[2]

One definition of water security is "the reliable availability of an acceptable quantity and quality of water for health, livelihoods and production, coupled with an acceptable level of water-related risks".[2]

A similar definition of water security by UN-Water is: "the capacity of a population to safeguard sustainable access to adequate quantities of acceptable quality water for sustaining livelihoods, human well-being, and socio-economic development, for ensuring protection against water-borne pollution and water-related disasters, and for preserving ecosystems in a climate of peace and political stability."[11]: 1 [13]

World Resources Institute also gave a similar definition in 2020. "For purposes of this report, we define water security as the capacity of a population to

  • safeguard sustainable access to adequate quantities of acceptable quality water for sustaining livelihoods, human well-being, and socioeconomic development;
  • protect against water pollution and water-related disasters; and
  • preserve ecosystems, upon which clean water availability and other ecosystem services depend."[7]: 17 

Narrower definition with a focus on water supply edit

Some organizations use water security in a more specific sense to refer to water supply only. They do not consider the water-related risks of too much water. For example, the definition of WaterAid in 2012 focuses on water supply issues. They defined water security as "reliable access to water of sufficient quantity and quality for basic human needs, small-scale livelihoods and local ecosystem services, coupled with a well managed risk of water-related disasters".[11]: 5  The World Water Council also uses this more specific approach with a focus on water supply. "Water security refers to the availability of water, in adequate quantity and quality, to sustain all these needs together (social and economic sectors, as well as the larger needs of the planet's ecosystems) – without exceeding its ability to renew."[14][15]

Relationship with WASH and IWRM edit

WASH (water, sanitation and hygiene) is an important concept when we discuss water security. Access to WASH services is one part of achieving water security.[3] The relationship works both ways. To be sustainable, WASH services need to address water security issues.[16]: 4  For example WASH relies on water resources that are part of the water cycle. But climate change has many impacts on the water cycle which can threaten water security.[11]: vII  There is also growing competition for water. This reduces the availability of water resources in many areas in the world.[16]: 4 

Water security incorporates ideas and concepts to do with the sustainability, integration and adaptiveness of water resource management.[17][4] In the past, experts used terms such as integrated water resources management (IWRM) or sustainable water management for this.

Related concepts edit

Water risk edit

Water risk refers to the possibility of problems to do with water. Examples are water scarcity, water stress, flooding, infrastructure decay and drought.[18]: 4  There exists an inverse relationship between water risk and water security. This means as water risk increases, water security decreases. Water risk is complex and multilayered. It includes risks flooding and drought. These can lead to infrastructure failure and worsen hunger.[19] When these disasters take place, they result in water scarcity or other problems. The potential economic effects of water risk are important to note. Water risks threaten entire industries. Examples are the food and beverage sector, agriculture, oil and gas and utilities. Agriculture uses 69% of total freshwater in the world. So this industry is very vulnerable to water stress.[20]

Risk is a combination of hazard, exposure and vulnerability.[4] Examples of hazards are droughts, floods and decline in quality. Bad infrastructure and bad governance lead to high exposure to risk.

The financial sector is becoming more aware of the potential impacts of water risk and the need for its proper management. By 2025, water risk will threaten $145 trillion in assets under management.[21]

To control water risk, companies can develop water risk management plans.[19] Stakeholders within financial markets can use these plans to measure company environmental, social and governance (ESG) performance. They can then identify leaders in water risk management.[22][20] The World Resources Institute has developed an online water data platform named Aqueduct for risk assessment and water management. China Water Risk is a nonprofit dedicated to understanding and managing water risk in China. The World Wildlife Fund has a Water Risk Filter that helps companies assess and respond to water risk with scenarios for 2030 and 2050.[23]

Understanding risk is part of water security policy. But it is also important to take social equity considerations more into account.[24]

There is no wholly accepted theory or mathematical model for determining or managing water risk.[3]: 13  Instead, managers use a range of theories, models and technologies to understand the trade-offs that exist in responding to risk.

Water conflict edit

This section is an excerpt from Water conflict.[edit]
 
Ethiopia's move to fill the dam's reservoir could reduce Nile flows by as much as 25% and devastate Egyptian farmlands.[25]

Water conflict typically refers to violence or disputes associated with access to, or control of, water resources, or the use of water or water systems as weapons or casualties of conflicts. The term water war is colloquially used in media for some disputes over water, and often is more limited to describing a conflict between countries, states, or groups over the rights to access water resources.[26][27] The United Nations recognizes that water disputes result from opposing interests of water users, public or private.[28] A wide range of water conflicts appear throughout history, though they are rarely traditional wars waged over water alone.[29] Instead, water has long been a source of tension and one of the causes for conflicts. Water conflicts arise for several reasons, including territorial disputes, a fight for resources, and strategic advantage.[30]

Water conflicts can occur on the intrastate and interstate levels. Interstate conflicts occur between two or more countries that share a transboundary water source, such as a river, sea, or groundwater basin. For example, the Middle East has only 1% of the world's fresh water shared among 5% of the world's population and most of the rivers cross international borders.[31] Intrastate conflicts take place between two or more parties in the same country, such as conflicts between farmers and urban water users.

Desired outcomes edit

There are three groups of water security outcomes. These include economic, environmental and equity (or social) outcomes.[1] Outcomes are things that are happening or that we want to see happen as a result of policy and management:

  • Economic outcomes: Sustainable growth which takes changing water needs and threats into account.[3] Sustainable growth includes job creation, increased productivity and standards of living.
  • Environmental outcomes: Quality and availability of water for the ecosystems services that depend on this water resource. Loss of freshwater biodiversity and depletion of groundwater are examples of negative environmental outcomes.[32][33]
  • Equity or social outcomes: Inclusive services so that consumers, industry and agriculture can access safe, reliable, sufficient and affordable water. These also mean they can dispose of wastewater safely. This area includes gender issues, empowerment, participation and accountability.[1]

There are four major focus areas for water security and its outcomes. It is about using water so that we increase economic and social welfare, move towards long-term sustainability or reduce risks tied to water.[4] Decision makers and water managers must consider the linkages and trade-offs between the varied types of outcomes.[3]: 13 

Improving water security is a key factor to achieve growth, development that is sustainable and reduce poverty.[2] Water security is also about social justice and fair distribution of environmental benefits and harms.[34] Development that is sustainable can help reduce poverty and increase living standards. This is most likely to benefit those affected by the impacts of insecure water resources in the region, especially women and children.

Water security is important for attaining most of the 17 United Nations Sustainable Development Goals (SDGs). This is because access to adequate and safe water is a precondition for meeting many of the individual goals.[8]: 4–8  It is also important for attaining development that is resilient to climate change.[8]: 4–7  Planners take note of water security outcomes for various groups in society when they design strategies for climate change adaptation.[3]: 19–21 

Determining factors edit

Three main factors determine the ability of a society to sustain water security:[2]

  1. Hydrologic environment
  2. Socio-economic environment
  3. Changes in the future environment (climate change)

Hydrologic environment edit

The hydrologic environment is important for water security. The term hydrologic environment refers to the "absolute level of water resource availability". But it also refers to how much it varies in time and location. Inter-annual means from one year to the next, Intra-annual means from one season to the next. We can refer to location as spatial distribution.[2] Scholars distinguish between a hydrologic environment that is easy to manage and one that is difficult.[2]

An easy to manage hydrologic environment would be one with low rainfall variability. In this case rain is distributed throughout the year and perennial river flows sustained by groundwater base flows. For example, many of the world's industrialized nations have a hydrologic environment that they can manage quite easily. This has helped them achieve water security early in their development.[2]

A difficult to manage hydrologic environment is one with absolute water scarcity such as deserts or low-lying lands prone to severe flood risk. Regions where rainfall is very variable from one season to the next, or regions where rainfall varies a lot from one year to the next are also likely to face water security challenges. We call this high inter-annual climate variability. An example would be East Africa, where there have been prolonged droughts every two to three years since 1999.[35] Most of the world's developing countries have challenges in managing hydrologies and have not achieved water security. This is not a coincidence.[2]

The poverty and hydrology hypothesis states that regions with a difficult hydrology remain poor because the respective governments have not been able to make the large investments necessary to achieve water security. Examples of such regions would be those with rainfall variability within one year and across several years. This leads to water insecurity which constrains economic growth.[2] There is a statistical link between increased changes in rainfall patterns and lower per capita incomes.[36]

Socio-economic environment edit

Relative levels of economic development and equality or inequality are strong determinants of community and household scale water security. Whilst the poverty and hydrology hypothesis suggests that there is a link between poverty and difficult hydrologies, there are many examples of "difficult hydrologies" that have not (yet) resulted in poverty and water insecurity.[2] [37]

Social and economic inequalities are strong drivers of water insecurity, especially at the community and household scales. Gender, race and caste inequalities have all been linked to differential access to water services such as drinking water and sanitation. In particular women and girls frequently have less access to economic and social opportunities as a directly consequence of being primarily responsible for meeting household water needs. The entire journey from water source to point of use is fraught with hazards largely faced by women and girls.[38] There is strong evidence that improving access to water and sanitation is a good way of addressing such inequalities.

Climate change edit

Further information: Effects of climate change on the water cycle and Water security § Reduced water quality due to climate change impacts

Impacts of climate change that are tied to water, affect people's water security on a daily basis. They include more frequent and intense heavy precipitation which affects the frequency, size and timing of floods.[39] Also droughts can alter the total amount of freshwater and cause a decline in groundwater storage, and reduction in groundwater recharge.[40] Reduction in water quality due to extreme events can also occur.[8]: 558  Faster melting of glaciers can also occur.[41]

Global climate change will probably make it more complex and expensive to ensure water security.[2] It creates new threats and adaptation challenges.[1] This is because climate change leads to increased hydrological variability and extremes. Climate change has many impacts on the water cycle. These result in higher climatic and hydrological variability, which can threaten water security.[11]: vII  Changes in the water cycle threaten existing and future water infrastructure. It will be harder to plan investments for future water infrastructure as there are so many uncertainties about future variability for the water cycle.[1] This makes societies more exposed to risks of extreme events linked to water and therefore reduces water security.[11]: vII 

It is difficult to predict the effects of climate change on national and local levels. Water security will be affected by sea level rise in low lying coastal areas while populations dependent on snowmelt as their water source will be affected by the recession of glaciers and mountain snow.[12]: 21 

Future climate change must be viewed in context of other existing challenges for water security. Other challenges existing climate variability in areas closer to the equator, population growth and increased demand for water resources. Others include political challenges, increased disaster exposure due to settlement in hazard-prone areas, and environmental degradation.[12]: 22  Water demand for irrigation in agriculture will increase due to climate change. This is because evaporation rates and the rate of water loss from crops will be higher due to rising temperatures.[7]: 4 

Climate factors have a major effect on water security as various levels. Geographic variability in water availability, reliability of rainfall and vulnerability to droughts, floods and cyclones are inherent hazards that affect development opportunities. These play out at international to intra-basin scales. At local scales, social vulnerability is a factor that increases the risks to water security, no matter the cause.[5]: 6  For example, people affected by poverty may have less ability to cope with climate shocks.[5]

Challenges and threats edit

There are many factors that contribute to low water security. Some examples are:[7]: 4 [6]: 9 

  • Water scarcity: Water demand exceeds supply in many regions of the world. This can be due to population growth, higher living standards, general economic expansion and/or greater quantities of water used in agriculture for irrigation.
  • Increasing water pollution and low levels of wastewater treatment, which is making local water unusable.
  • Poor planning of water use, poor water management and misuse. These can cause groundwater levels to drop, rivers and lakes to dry out, and local ecosystems to collapse.
  • Trans-boundary waters and international rivers which belong to several countries. Country borders often do not align with natural watersheds. One reason is that international borders result from boundaries during colonialism.[2]
  • Climate change. This makes water-related disasters such as droughts and floods more frequent and intense; rising temperatures and sea levels can contaminate freshwater sources.[6]: 9 

Water scarcity edit

A major threat to water security is water scarcity. About 27% of the world's population lived in areas affected by water scarcity in the mid-2010s. This number will likely increase to 42% by 2050.[42]

This section is an excerpt from Water scarcity.[edit]
 
Map of global water stress (a symptom of water scarcity) in 2019. Water stress is the ratio of water use relative to water availability and is therefore a demand-driven scarcity.[43]

Water scarcity (closely related to water stress or water crisis) is the lack of fresh water resources to meet the standard water demand. There are two types of water scarcity namely physical and economic water scarcity.[44]: 560  Physical water scarcity is where there is not enough water to meet all demands, including that needed for ecosystems to function. Arid areas for example Central Asia, West Asia, and North Africa often experience physical water scarcity.[45] Economic water scarcity on the other hand, is the result of lack of investment in infrastructure or technology to draw water from rivers, aquifers, or other water sources. It also results from weak human capacity to meet water demand.[44]: 560  Much of Sub-Saharan Africa experiences economic water scarcity.[46]: 11 

There is enough freshwater available globally and averaged over the year to meet demand. As such, water scarcity is caused by a mismatch between when and where people need water, and when and where it is available.[47] The main drivers of the increase in global water demand are the increasing world population, rise in living conditions, changing diets (to more animal products),[48] and expansion of irrigated agriculture.[49][50] Climate change (including droughts or floods), deforestation, water pollution and wasteful use of water can also cause insufficient water supply.[51] Scarcity varies over time as a result of natural variability in hydrology. These variations in scarcity may also be a function of prevailing economic policy and planning approaches.

Water pollution edit

Water pollution is a threat to water security. It can affect the supply of drinking water and indirectly contribute to water scarcity.

This section is an excerpt from Water pollution.[edit]
Water pollution (or aquatic pollution) is the contamination of water bodies, usually as a result of human activities, so that it negatively affects its uses.[52]: 6  Water bodies include lakes, rivers, oceans, aquifers, reservoirs and groundwater. Water pollution results when contaminants mix with these water bodies. Contaminants can come from one of four main sources: sewage discharges, industrial activities, agricultural activities, and urban runoff including stormwater.[53] Water pollution is either surface water pollution or groundwater pollution. This form of pollution can lead to many problems, such as the degradation of aquatic ecosystems or spreading water-borne diseases when people use polluted water for drinking or irrigation.[54] Another problem is that water pollution reduces the ecosystem services (such as providing drinking water) that the water resource would otherwise provide.

Reduced water quality due to climate change edit

 
Drinking water quality framework: Environment (including weather events), infrastructure and management affect drinking water quality at the point of collection (PoC) and point of use (PoU).[55]

Weather and its related shocks can affect water quality in several ways. These depend on the local climate and context.[55] Shocks that are linked to weather include water shortages, heavy rain and temperature extremes. They can damage water infrastructure through erosion under heavy rainfall and floods, cause loss of water sources in droughts, and make water quality deteriorate.[55]

Climate change can reduce lower water quality in several ways:[8]: 582 

  • Heavy rainfall can rapidly reduce the water quality in rivers and shallow groundwater. It can affect water quality in reservoirs even if these effects can be slow.[56] Heavy rainfall also impacts groundwater in deeper, unfractured aquifers. But these impacts are less pronounced. Rainfall can increase fecal contamination of water sources.[55]
  • Floods after heavy rainfalls can mix floodwater with wastewater. Also pollutants can reach water bodies by increased surface runoff.
  • Groundwater quality may deteriorate due to droughts. The pollution in rivers that feed groundwater becomes less diluted. As groundwater levels drop, rivers may lose direct contact with groundwater.[57]
  • In coastal regions, more saltwater may mix into freshwater aquifers due to sea level rise and more intense storms.[11]: 16 [4] This process is called saltwater intrusion.
  • Warmer water in lakes, oceans, reservoirs and rivers can cause more eutrophication. This results in more frequent harmful algal blooms.[8]: 140  Higher temperatures cause problems for water bodies and aquatic ecosystems because warmer water contains less oxygen.[58]
  • Permafrost thawing leads to an increased flux of contaminants.[59]
  • Increased meltwater from glaciers may release contaminants.[60] As glaciers shrink or disappear, the positive effect of seasonal meltwater on downstream water quality through dilution is disappearing.[61]

Poverty edit

People in low-income countries are at greater risk of water insecurity and may also have less resources to mitigate it. This can result in human suffering, sustained poverty, constrained growth and social unrest.[2]

Food and water insecurity pose significant challenges for numerous individuals across the United States. Strategies employed by households in response to these pressing issues encompass labor intensive methods, such as melting ice, earning wages, and occasionally incurring debt, all aimed at water conservation. Additionally, families may turn to foraging for water-based plants and animals, seeking alternative sources of sustenance. Adjusting consumption patterns becomes imperative, involving the rationing of servings and prioritizing nutritional value, particularly for vulnerable members like small children. The phenomenon of substituting more expensive, nutritious food with cheaper alternatives is also observed.[62]

Furthermore, individuals may consume from sources considered "stigmatized" by society, such as urine or unfiltered water. Migration emerges as a viable option, with families fostering children to relatives outside famine zones and engaging in seasonal or permanent resettlement. In certain instances, resource preservation involves the challenging decision of abandoning specific family members. This is achieved through withholding resources from non-family members, prioritizing the health of some family members over others, and, in extreme cases, leaving individuals behind. As the climate changes, the impact of food and water insecurity is disproportionately felt, necessitating a re-evaluation of societal misconceptions about those making survival sacrifices. Larger entities, including the government and various organizations, extend assistance based on available resources, highlighting the importance of addressing information gaps in specific data.[62]

Destructive forces of water edit

 
Flooded roads in Ponce, Puerto Rico, a week after Hurricane Maria devastated the island (2017).

Water can cause large-scale destruction due to its huge power.[2] This destruction can result from sudden events. Examples are tsunamis, floods or landslides. Events that happen slowly over time such as erosion, desertification or water pollution can also cause destruction.[2]

Other threats edit

Other threats to water security include:

Management approaches edit

There are different ways to tackle water insecurity. Science and engineering approaches can increase the water supply or make water use more efficient. Financial and economic tools can be used as a safety net for poorer people. Higher prices may encourage more investments in water systems. Finally, management tools such as demand caps can improve water security.[7]: 16, 104  Decision makers invest in institutions, information flows and infrastructure to achieve a high level of water security.[1]

Investment decisions edit

Institutions edit

The right institutions are important to improve water security.[2] Institutions govern how decisions can promote or constrain water security outcomes for the poor.[3] Strengthening institutions might involve reallocating risks and duties between the state, market and communities in new ways. This can include performance-based models, development impact bonds, or blended finance from government, donors and users. These finance mechanisms are set up to work jointly with state, private sector and communities investors.[3]: 37 

Sustainable Development Goal 16 is about peace, justice and strong institutions. It recognizes that strong institutions are a necessary condition for sustainable development, including water security.[3]: 35 

Drinking water quality and water pollution are linked. But policymakers often do not address them in a comprehensive way. For example, pollution from industries is often not linked to drinking water quality in developing countries.[3]: 32  Keeping track of river, groundwater and wastewater is important. It can identify sources of contamination and guide targeted regulatory responses. The WHO has described water safety plans as the most effective means of maintaining a safe supply of drinking water to the public.[65]

Information flows edit

It is important for institutions to have access to information about water. This helps them with their planning and decision-making.[1] It also helps with tracking how accountable and effective policies are. Investments into climate information tools that are appropriate for the local context are useful.[5]: 59  They cover a wide range of temporal and spatial scales. They also respond to regional climate risks tied to water.[5]: 58 

Seasonal climate and hydrological forecasts can be useful to prepare for and reduce water security risks. They are especially useful if people can apply them at the local scale.[66][67] Applying knowledge of how climate anomalies relate to each other over long distances can improve seasonal forecasts for specific regions. These teleconnections are correlations between patterns of rainfall, temperature, and wind speed between distant areas. They are caused by large-scale ocean and atmospheric circulation.[68][69]

In regions where rainfall varies with the seasons and from year to year, water managers would like to have more accurate seasonal weather forecasts. In some locations the onset of seasonal rainfall is particularly hard to predict. This is because aspects of the climate system are difficult to describe with mathematical models. For example, the long rains in East Africa which fall March to May have been difficult to simulate with climate models. When climate models work well they can produce useful seasonal forecasts.[70] One reason for these difficulties is the complex topography of the area.[70] Improved understanding of atmospheric processes may allow climate scientists to provide more relevant and localized information to water managers on a seasonal timescale. They could also provide more detailed predictions for the effects of climate change on a longer timeframe.[71]

 
Annual rainfall pattern in two regions of Ethiopia. The lines represent observations (red dashed line) and model results (green line) in a climate model study of the region.[72]

One example would be seasonal forecasts of rainfall in Ethiopia's Awash river basin. These may become more accurate by understanding better how sea surface temperatures in different ocean regions relate to rainfall patterns in this river basin.[69] At a larger regional scale, a better understanding of the relationship between pressure systems in the Indian Ocean and the South Atlantic on the one hand, and wind speeds and rainfall patterns in the Greater Horn of Africa on the other hand would be helpful. This kind of scientific analysis may contribute to improved representation of this region in climate models to assist development planning.[73] It could also guide people when they plan water allocation in the river basin or prepare emergency response plans for future events of water scarcity and flooding.[69]

Infrastructure edit

Water infrastructure serves to access, store, regulate, move and conserve water. Several assets carry out these functions. Natural assets are lakes, rivers, wetlands, aquifers, springs. Engineered assets are bulk water management infrastructure, such as dams.[2] Examples include:[1]

Public and private spending on water infrastructure and supporting institutions must be well balanced. They are likely to evolve over time.[2] This is important to avoid unplanned social and environmental costs from building new facilities.

For example, in the case of Africa, investments into groundwater use is an option to increase water security and for climate change adaptation.[74] Water security in African countries could benefit from the distribution of groundwater storage and recharge on the continent. Recharge is a process where water moves to groundwater. Many countries that have low recharge have substantial groundwater storage. Countries with low storage typically have high, regular recharge.[75]

Consideration of scales edit

People manage water security risks at different spatial scales. These range from the household to community, town, city, basin and region.[3]: 11  At the local scale, actors include county governments, schools, water user groups, local water providers and the private sector. At the next larger scale there are basin and national level actors. These actors help to identify any constraints with regards to policy, institutions and investments. Lastly, there are global actors such as the World Bank, UNICEF, FCDO, WHO and USAID. They help to develop suitable service delivery models.[3]: 11 

The physical geography of a country shows the correct scale that planners should use for managing water security risks. Even within a country, the hydrologic environment may vary a lot. See for example the variations in seasonal rainfall across Ethiopia.

Reducing inequalities in water security edit

Inequalities with regards to water security within a society have structural and historical roots. They can affect people at different scales. These range from the household, to the community, town, river basin or the region.[3]: 20  High risk social groups and regions can be identified during political debates but are often ignored. Water inequality is often tied to gender in low-income countries. At the household level, women are often the "water managers". But they have limited choices over water and related issues.[3]: 21 

Improving climate resilience of water and sanitation services edit

Many institutions are working to develop WASH services that are resilient to climate.[3]: 27, 37 [76][77]

This section is an excerpt from WASH § Improving climate resilience.[edit]

Climate-resilient water services (or climate-resilient WASH) are services that provide access to high quality drinking water during all seasons and even during extreme weather events.[78] Climate resilience in general is the ability to recover from, or to mitigate vulnerability to, climate-related shocks such as floods and droughts.[79] Climate resilient development has become the new paradigm for sustainable development. This concept thus influences theory and practice across all sectors globally.[79] This is particularly true in the water sector, since water security is closely connected to climate change. On every continent, governments are now adopting policies for climate resilient economies. International frameworks such as the Paris Agreement and the Sustainable Development Goals are drivers for such initiatives.[79]

Several activities can improve water security and increase resilience to climate risks: Carrying out a detailed analysis of climate risk to make climate information relevant to specific users; developing metrics for monitoring climate resilience in water systems (this will help to track progress and guide investments for water security); and using new institutional models that improve water security.[80]

Climate resilient policies can be useful for allocating water, keeping in mind that less water may be available in future. This requires a good understanding of the current and future hydroclimatic situation. For example, a better understanding of future changes in climate variability leads to a better response to their possible impacts.[81]

To build climate resilience into water systems, people need to have access to climate information that is appropriate for their local context.[80]: 59  Climate information products are useful if they cover a wide range of temporal and spatial scales, and provide information on regional water-related climate risks.[80]: 58  For example, government staff need easy access to climate information to achieve better water management.[81]

Four important activities to achieve climate resilient WASH services include: First, a risk analysis is performed to look at possible implications of extreme weather events as well as preventive actions.[82]: 4  Such preventive actions can include for example elevating the infrastructure to be above expected flood levels. Secondly, managers assess the scope for reducing greenhouse gas emissions and put in place suitable options, e.g. using more renewable energy sources. Thirdly, the water utilities ensure that water sources and sanitation services are reliable at all times during the year, also during times of droughts and floods. Finally, the management and service delivery models are strengthened so that they can withstand a crisis.[82]: 5 

To put climate resilience into practice and to engage better with politicians, the following guide questions are useful: "resilience of what, to what, for whom, over what time frame, by whom and at what scale?".[79] For example, "resilience of what?" means thinking beyond infrastructure but to also include resilience of water resources, local institutions and water users. Another example is that "resilience for whom?" speaks about reducing vulnerability and preventing negative developments: Some top-down interventions that work around power and politics may undermine indigenous knowledge and compromise community resilience.[79]

Measurement tools edit

 
Aggregated global water security index, calculated using the aggregation of water availability, accessibility, safety and quality, and management indices. The value '0–1' (with the continuous color 'red to blue') represents 'low to high' security.[83]

There is no single way to measure water security.[8]: 562  There are no standard indicators to measure water security. That is because it is a concept that focuses on outcomes.[1] The outcomes that are regard as important can change depending on the context and stakeholders.

Instead, it is common to compare relative levels of water security by using metrics for certain aspects of water security.[8]: 562  For example, the Global Water Security Index includes metrics on:

  • availability (water scarcity index, drought index, groundwater depletion);
  • accessibility to water services (access to sanitation and drinking water);
  • safety and quality (water quality index, global flood frequency);
  • management (World Governance Index, transboundary legal framework, transboundary political tension).[83]

Scientists have been working on ways to measure water security at a variety of levels. The metrics roughly fall into two groups. There are those that are based on experiences versus metrics that are based on resources. The former mainly focus on measuring the experiences of households and human well-being. Meanwhile the latter focuses on the amount of available freshwater.[9]

The Household Water Insecurity Experiences (HWISE) Scale measures several components of water insecurity at the household level. These include adequacy, reliability, accessibility and safety.[84] This scale can help to identify vulnerable subpopulations and ensure resources are allocated to those in need. It can also measure how effective of water policies and projects are.[84]

Global estimates edit

The IPCC Sixth Assessment Report summarises the current and future water security trends. It says that increasing weather and extreme climate events have led to acute food insecurity and reduced water security for millions of people. The largest impacts are seen in Africa, Asia, Central and South America, Small Islands and the Arctic.[10]: 9 

The same report predicted that global warming of 2 °C would expose roughly 1-4 billion people to water stress. This would depend on regional patterns of climate change and the socio-economic scenarios.[8]: 558  On water scarcity which is one factor in water insecurity the report finds 1.5-2.5 billion people live water scarce areas.[10]: 660 

Water scarcity and water security are not always equal. There are regions with high water security even though they also experience water scarcity. Examples are parts of the United States, Australia and Southern Europe. This is due to efficient water services that have a high level of safety, quality, and accessibility.[83][8]: 562  However, even in those regions, groups such as Indigenous peoples tend to have less access to water and face water insecurity at times.[8]: 562 

Country examples edit

Bangladesh edit

Further information: Water supply and sanitation in Bangladesh and Climate change in Bangladesh
 
 
Too much water can also cause water insecurity. Left: Flooding in Bangladesh; right: People on an island in a flooded river in Bangladesh.

Risks to water security in Bangladesh include:[5]: 45 

The country experiences water security risks in the capital Dhaka as well as in the coastal region.[5] In Dhaka, monsoonal pulses can lead to urban flooding. This can pollute the water supply.[5] A number of processes and events cause water risks for about 20 million people in the coastal regions. These include aquifers that are getting saltier, seasonal water scarcity, fecal contamination, and flooding from the monsoon and from storm surges due to cyclones.[5]: 64 

Different types of floods occur in coastal Bangladesh. They are: river floods, tidal floods and storm surge floods due to tropical cyclones.[85] These floods can damage drinking water infrastructure. They can also lead to reduced water quality as well as losses in agricultural and fishery yields.[5] There is a link between water insecurity and poverty in the low-lying areas in the Ganges-Brahmaputra tidal delta plain.[85] Those low-lying areas are embanked areas in coastal Bangladesh.

The government has various programs to reduce risks for people who live in coastal communities. These programs also lead to increases in economic wellbeing.[85] Examples include the "Coastal Embankment Improvement Project"[86] by World Bank in 2013, the BlueGold project[87] in 2012, UNICEF's "Managed Aquifer Recharge" program in 2014 and the Bangladesh Delta Plan in 2014.[85] Such investments in water security aim to increase the continued use and upkeep of water facilities. They can help coastal communities to escape the poverty trap caused by water insecurity.[85]

A program called the "SafePani framework" focuses on how the state shares risks and responsibilities with service providers and communities.[5] This program aims to help decision makers to address climate risks through a process called climate resilient water safety planning.[5] The program is a cooperation between UNICEF and the Government of Bangladesh.

Ethiopia edit

Further information: Climate change in Ethiopia and Water supply and sanitation in Ethiopia
 
Rainfall regimes vary across Ethiopia. Left figure: Annual average rainfall in mm/day with the interquartile range (25th–75th) of monthly rainfall in mm/day indicated by black contours (1981–2020).[88] Right figure: Three rainfall zones in Ethiopia with different seasonal rainfall patterns. The green zone has two separate rainy seasons, and the red zone has a single peak in rainfall in Jun to September.

Ethiopia has two main wet seasons per year. It rains in the spring and summer. These seasonal patterns of rainfall vary a lot across the country.[69][89] Western Ethiopia has a seasonal rainfall pattern that is similar to the Sahel. It has rainfall from February to November (which is decreasing to the north), and has peak rainfall from June to September. Southern Ethiopia has a rainfall pattern similar to the one in East Africa. There are two distinct wet seasons every year, February to May, and October to November.[72][89] Central and eastern Ethiopia has some rainfall between February and November, with a smaller peak in rainfall from March to May and a second higher peak from June to September.[89]

In 2022 Ethiopia had one of the most severe La Niña-induced droughts in the last forty years. It came about due to four consecutive rainy seasons which did not produce enough rain.[90] This drought increased water insecurity for more than 8 million pastoralists and agro-pastoralists in the Somali, Oromia, SNNP and South-West regions. About 7.2 million people needed food aid, and 4.4 million people needed help to access water. Food prices have increased a lot due to the drought conditions. Many people in the affected area have experienced food shortages due to the water insecurity situation.[90]

In the Awash basin in central Ethiopia floods and droughts are common. Agriculture in the basin is mainly rainfed (without irrigation systems). This applies to around 98% of total cropland as of 2012. So changes in rainfall patterns due to climate change will reduce economic activities in the basin.[91] Rainfall shocks have a direct impact on agriculture. A rainfall decrease in the Awash basin could lead to a 5% decline in the basin's overall GDP. The agricultural GDP could even drop by as much as 10%.[91]

Partnerships with the Awash Basin Development Office (AwBDO) and the Ministry of Water, Irrigation and Electricity (MoWIE) have led to the development of new models of water allocation in the Awash basin. This can improve water security for the 18.3 million residents in the basin. With this they will have enough water for their domestic, irrigation and industry needs.[5]

Kenya edit

Further information: Water supply and sanitation in Kenya and Climate change in Kenya

Kenya ranked 46th out of 54 African countries in an assessment of water security in 2022.[92] Major water security issues in Kenya include drinking water safety, water scarcity, lack of water storage, poor wastewater treatment, and drought and flood.[92] Large-scale climate patterns influence the rainfall patterns in East Africa. Such climate patterns include the El Niño–Southern Oscillation (ENSO) and the Indian Ocean Dipole (IOD). Cooling in the Pacific Ocean during the La Niña phase of ENSO is linked with dryer conditions in Kenya. This can lead to drought as it did in 2016-17. On the other hand a warmer Western Indian Ocean due to a strong positive Indian Ocean Dipole caused extreme flooding in Kenya in 2020.[93]

Around 38% of Kenya's population and 70% of its livestock live in arid and semi-arid lands.[94] These areas have low rainfall which varies a lot from one season to the next. This means that surface water and groundwater resources vary a lot by location and time of year. Residents in Northern Kenya are seeing increased changes in rainfall patterns and more frequent droughts.[95] These changes affect livelihoods in this region where people have been living as migratory herders. They are used to herding livestock with a seasonal migration pattern.[95] More people are now settling in small urban centers, and there is increasing conflict over water and other resources.[96] Water insecurity is a feature of life for both settled and nomadic pastoralists. Women and children bear the burden for fetching water.[97]

Groundwater sources have great potential to improve water supply in Kenya. However, the use of groundwater is limited by low quality and knowledge, pumping too much groundwater, known as overdrafting, and salt water intrusion along coastal areas.[98][99] Another challenge is the upkeep of groundwater infrastructure, mainly in rural areas.[100]

See also edit

References edit

  1. ^ a b c d e f g h i j k l Sadoff, Claudia; Grey, David; Borgomeo, Edoardo (2020). "Water Security". Oxford Research Encyclopedia of Environmental Science. doi:10.1093/acrefore/9780199389414.013.609. ISBN 978-0-19-938941-4.
  2. ^ a b c d e f g h i j k l m n o p q r s t u Grey, David; Sadoff, Claudia W. (2007-12-01). "Sink or Swim? Water security for growth and development". Water Policy. 9 (6): 545–571. doi:10.2166/wp.2007.021. hdl:11059/14247. ISSN 1366-7017.
  3. ^ a b c d e f g h i j k l m n o p q REACH (2020) REACH Global Strategy 2020-2024, University of Oxford, Oxford, UK (REACH program).
  4. ^ a b c d e Hoekstra, Arjen Y; Buurman, Joost; van Ginkel, Kees C H (2018). "Urban water security: A review". Environmental Research Letters. 13 (5): 053002. doi:10.1088/1748-9326/aaba52.   Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  5. ^ a b c d e f g h i j k l m Murgatroyd, A., Charles, K.J., Chautard, A., Dyer, E., Grasham, C., Hope, R., Hoque, S.F., Korzenevica, M., Munday, C., Alvarez-Sala, J., Dadson, S., Hall, J.W., Kebede, S., Nileshwar, A., Olago, D., Salehin, M., Ward, F., Washington, R., Yeo, D. and Zeleke, G. (2021). Water Security for Climate Resilience Report: A synthesis of research from the Oxford University REACH programme. University of Oxford, UK: REACH.  Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  6. ^ a b c d UNICEF (2021) Reimagining WASH - Water Security for All
  7. ^ a b c d e f Peter Gleick, Charles Iceland, and Ayushi Trivedi (2020) Ending Conflicts over Water: Solutions to Water and Security Challenges, World Resources Institute
  8. ^ a b c d e f g h i j k l m Caretta, M.A., A. Mukherji, M. Arfanuzzaman, R.A. Betts, A. Gelfan, Y. Hirabayashi, T.K. Lissner, J. Liu, E. Lopez Gunn, R. Morgan, S. Mwanga, and S. Supratid, 2022: Chapter 4: Water. In: Climate Change 2022: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [H.-O. Pörtner, D.C. Roberts, M. Tignor, E.S. Poloczanska, K. Mintenbeck, A. Alegría, M. Craig, S. Langsdorf, S. Löschke, V. Möller, A. Okem, B. Rama (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 551–712, doi:10.1017/9781009325844.006.
  9. ^ a b Octavianti, Thanti; Staddon, Chad (May 2021). "A review of 80 assessment tools measuring water security". WIREs Water. 8 (3). doi:10.1002/wat2.1516. S2CID 233930546.   Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  10. ^ a b c d IPCC, 2022: Summary for Policymakers [H.-O. Pörtner, D.C. Roberts, E.S. Poloczanska, K. Mintenbeck, M. Tignor, A. Alegría, M. Craig, S. Langsdorf, S. Löschke, V. Möller, A. Okem (eds.)]. In: Climate Change 2022: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [H.-O. Pörtner, D.C. Roberts, M. Tignor, E.S. Poloczanska, K. Mintenbeck, A. Alegría, M. Craig, S. Langsdorf, S. Löschke, V. Möller, A. Okem, B. Rama (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 3–33, doi:10.1017/9781009325844.001.
  11. ^ a b c d e f g UN-Water (2013) Water Security & the Global Water Agenda - A UN-Water Analytical Brief, ISBN 978-92-808-6038-2, United Nations University
  12. ^ a b c WaterAid (2012) Water security framework. WaterAid, London
  13. ^ "What is Water Security? Infographic". UN-Water. n.d. Retrieved 2021-02-11.
  14. ^ Global water security : lessons learnt and long-term implications. Singapore: World Water Council. 2018. ISBN 978-981-10-7913-9. OCLC 1021856401.[page needed]
  15. ^ World Water Council (2018) Water security for all - Policy Recommendations
  16. ^ a b Wetlands International (2017). WASH and Water Security. Integration and the role of civil society. Wetlands International, The Netherlands.
  17. ^ Varady, Robert G.; Albrecht, Tamee R.; Staddon, Chad; Gerlak, Andrea K.; Zuniga-Teran, Adriana A. (2021). "The Water Security Discourse and Its Main Actors". Handbook of Water Resources Management: Discourses, Concepts and Examples. pp. 215–252. doi:10.1007/978-3-030-60147-8_8. ISBN 978-3-030-60145-4. S2CID 236726731.
  18. ^ The CEO Water Mandate (2014) Driving Harmonization of Water-Related Terminology, Discussion Paper September 2014. Alliance for Water Stewardship, Ceres, CDP (formerly the Carbon Disclosure Project), The Nature Conservancy, Pacific Institute, Water Footprint Network, World Resources Institute, and WWF
  19. ^ a b Bonnafous, Luc; Lall, Upmanu; Siegel, Jason (2017-04-19). "A water risk index for portfolio exposure to climatic extremes: conceptualization and an application to the mining industry". Hydrology and Earth System Sciences. 21 (4): 2075–2106. Bibcode:2017HESS...21.2075B. doi:10.5194/hess-21-2075-2017.
  20. ^ a b "The Water Crisis and Industries at Risk". Morgan Stanley. Retrieved 2020-04-06.
  21. ^ Carr, Acacia (3 December 2018). "Water Risk: Single Largest Risk Threatening People, Planet and Profit | GreenMoney Journal". Retrieved 2020-04-06.
  22. ^ "Climate change is devastating the world's water supplies. Why aren't we talking about it?". Climate & Capital Media. 2021-01-14. Retrieved 2021-01-15.
  23. ^ "New Water Risk Filter Scenarios will help companies and investors turn risk into resilience".
  24. ^ Grasham, Catherine Fallon; Charles, Katrina Jane; Abdi, Tilahun Geneti (2022). "(Re-)orienting the Concept of Water Risk to Better Understand Inequities in Water Security". Frontiers in Water. 3: 799515. doi:10.3389/frwa.2021.799515.   Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  25. ^ "In Africa, War Over Water Looms As Ethiopia Nears Completion Of Nile River Dam". NPR. 27 February 2018.
  26. ^ Tulloch, James (August 26, 2009). "Water Conflicts: Fight or Flight?". Allianz. Archived from the original on 2008-08-29. Retrieved 14 January 2010.
  27. ^ Kameri-Mbote, Patricia (January 2007). (PDF). Navigating Peace. Woodrow Wilson International Center for Scholars (4). Archived from the original (PDF) on 2010-07-06.
  28. ^ United Nations Potential Conflict to Cooperation Potential, accessed November 21, 2008
  29. ^ Peter Gleick, 1993. "Water and conflict." International Security Vol. 18, No. 1, pp. 79-112 (Summer 1993).
  30. ^ Heidelberg Institute for International Conflict Research (Department of Political Science, University of Heidelberg); Conflict Barometer 2007:Crises – Wars – Coups d'État – Nagotiations – Mediations – Peace Settlements, 16th annual conflict analysis, 2007
  31. ^ Sutherland, Ben (March 18, 2003). "Water shortages 'foster terrorism'". BBC News. Retrieved 14 January 2010.
  32. ^ Vörösmarty, C. J.; McIntyre, P. B.; Gessner, M. O.; Dudgeon, D.; Prusevich, A.; Green, P.; Glidden, S.; Bunn, S. E.; Sullivan, C. A.; Liermann, C. Reidy; Davies, P. M. (September 2010). "Global threats to human water security and river biodiversity". Nature. 467 (7315): 555–561. Bibcode:2010Natur.467..555V. doi:10.1038/nature09440. hdl:10983/13924. PMID 20882010. S2CID 4422681.
  33. ^ Foster, S.; Villholth, Karen; Scanlon, B.; Xu, Y. (2021-07-01). "Water security and groundwater". International Association of Hydrogeologists. hdl:10568/116815.
  34. ^ Staddon, Chad; Scott, Christopher (2021). Putting water security to work : addressing global sustainable development challenges (1st ed.). London. ISBN 9780367650193.{{cite book}}: CS1 maint: location missing publisher (link)
  35. ^ Funk, Chris (4 October 2021). "Scientists sound the alarm over drought in East Africa: what must happen next". The Conversation. Retrieved 2022-07-07.
  36. ^ Brown, Casey; Lall, Upmanu (2006). "Water and economic development: The role of variability and a framework for resilience". Natural Resources Forum. 30 (4): 306–317. doi:10.1111/j.1477-8947.2006.00118.x.
  37. ^ Brown, Casey; Lall, Upmanu (2006). "Water and economic development: The role of variability and a framework for resilience". Natural Resources Forum. 30 (4): 306–317. doi:10.1111/j.1477-8947.2006.00118.x.
  38. ^ Staddon, Chad; Brewis, Alexandra (2024-04-01). "Household Water Containers: Mitigating risks for improved Modular, Adaptive, and Decentralized (MAD) water systems". Water Security. 21: 100163. doi:10.1016/j.wasec.2023.100163. ISSN 2468-3124.
  39. ^ "Flooding and Climate Change: Everything You Need to Know". www.nrdc.org. 2019-04-10. Retrieved 2023-07-11.
  40. ^ Petersen-Perlman, Jacob D.; Aguilar-Barajas, Ismael; Megdal, Sharon B. (2022-08-01). "Drought and groundwater management: Interconnections, challenges, and policyresponses". Current Opinion in Environmental Science & Health. 28: 100364. Bibcode:2022COESH..2800364P. doi:10.1016/j.coesh.2022.100364. ISSN 2468-5844.
  41. ^ Harvey, Chelsea. "Glaciers May Melt Even Faster Than Expected, Study Finds". Scientific American. Retrieved 2023-07-11.
  42. ^ Boretti, Alberto; Rosa, Lorenzo (2019). "Reassessing the projections of the World Water Development Report". npj Clean Water. 2 (1): 1–6. doi:10.1038/s41545-019-0039-9. hdl:11380/1198301. ISSN 2059-7037.
  43. ^ Kummu, M.; Guillaume, J. H. A.; de Moel, H.; Eisner, S.; Flörke, M.; Porkka, M.; Siebert, S.; Veldkamp, T. I. E.; Ward, P. J. (2016). "The world's road to water scarcity: shortage and stress in the 20th century and pathways towards sustainability". Scientific Reports. 6 (1): 38495. Bibcode:2016NatSR...638495K. doi:10.1038/srep38495. ISSN 2045-2322. PMC 5146931. PMID 27934888.
  44. ^ a b Caretta, M.A., A. Mukherji, M. Arfanuzzaman, R.A. Betts, A. Gelfan, Y. Hirabayashi, T.K. Lissner, J. Liu, E. Lopez Gunn, R. Morgan, S. Mwanga, and S. Supratid, 2022: Chapter 4: Water. In: Climate Change 2022: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [H.-O. Pörtner, D.C. Roberts, M. Tignor, E.S. Poloczanska, K. Mintenbeck, A. Alegría, M. Craig, S. Langsdorf, S. Löschke, V. Möller, A. Okem, B. Rama (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA, pp. 551–712, doi:10.1017/9781009325844.006.
  45. ^ Rijsberman, Frank R. (2006). "Water scarcity: Fact or fiction?". Agricultural Water Management. 80 (1–3): 5–22. Bibcode:2006AgWM...80....5R. doi:10.1016/j.agwat.2005.07.001.
  46. ^ IWMI (2007) Water for Food, Water for Life: A Comprehensive Assessment of Water Management in Agriculture. London: Earthscan, and Colombo: International Water Management Institute.
  47. ^ Mekonnen, Mesfin M.; Hoekstra, Arjen Y. (2016). "Four billion people facing severe water scarcity". Science Water Stress Advances. 2 (2): e1500323. Bibcode:2016SciA....2E0323M. doi:10.1126/sciadv.1500323. ISSN 2375-2548. PMC 4758739. PMID 26933676.
  48. ^ Liu, Junguo; Yang, Hong; Gosling, Simon N.; Kummu, Matti; Flörke, Martina; Pfister, Stephan; Hanasaki, Naota; Wada, Yoshihide; Zhang, Xinxin; Zheng, Chunmiao; Alcamo, Joseph (2017). "Water scarcity assessments in the past, present, and future: Review on Water Scarcity Assessment". Earth's Future. 5 (6): 545–559. doi:10.1002/2016EF000518. PMC 6204262. PMID 30377623.
  49. ^ Vorosmarty, C. J. (2000-07-14). "Global Water Resources: Vulnerability from Climate Change and Population Growth". Science. 289 (5477): 284–288. Bibcode:2000Sci...289..284V. doi:10.1126/science.289.5477.284. PMID 10894773. S2CID 37062764.
  50. ^ Ercin, A. Ertug; Hoekstra, Arjen Y. (2014). "Water footprint scenarios for 2050: A global analysis". Environment International. 64: 71–82. doi:10.1016/j.envint.2013.11.019. PMID 24374780.
  51. ^ "Water Scarcity. Threats". WWF. 2013. from the original on 21 October 2013. Retrieved 20 October 2013.
  52. ^ Von Sperling, Marcos (2007). "Wastewater Characteristics, Treatment and Disposal". IWA Publishing. 6. doi:10.2166/9781780402086. ISBN 978-1-78040-208-6.   Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  53. ^ Eckenfelder Jr WW (2000). Kirk-Othmer Encyclopedia of Chemical Technology. John Wiley & Sons. doi:10.1002/0471238961.1615121205031105.a01. ISBN 978-0-471-48494-3.
  54. ^ "Water Pollution". Environmental Health Education Program. Cambridge, MA: Harvard T.H. Chan School of Public Health. July 23, 2013. from the original on September 18, 2021. Retrieved September 18, 2021.
  55. ^ a b c d Charles, Katrina J.; Howard, Guy; Villalobos Prats, Elena; Gruber, Joshua; Alam, Sadekul; Alamgir, A.S.M.; Baidya, Manish; Flora, Meerjady Sabrina; Haque, Farhana; Hassan, S.M. Quamrul; Islam, Saiful (2022). "Infrastructure alone cannot ensure resilience to weather events in drinking water supplies". Science of the Total Environment. 813: 151876. Bibcode:2022ScTEn.813o1876C. doi:10.1016/j.scitotenv.2021.151876. hdl:1983/92cc5791-168b-457a-93c7-458890f1bf26. PMID 34826465.
  56. ^ Brookes, Justin D.; Antenucci, Jason; Hipsey, Matthew; Burch, Michael D.; Ashbolt, Nicholas J.; Ferguson, Christobel (2004-07-01). "Fate and transport of pathogens in lakes and reservoirs". Environment International. 30 (5): 741–759. doi:10.1016/j.envint.2003.11.006. PMID 15051248.
  57. ^ Kløve, Bjørn; Ala-Aho, Pertti; Bertrand, Guillaume; Gurdak, Jason J.; Kupfersberger, Hans; Kværner, Jens; Muotka, Timo; Mykrä, Heikki; Preda, Elena; Rossi, Pekka; Uvo, Cintia Bertacchi; Velasco, Elzie; Pulido-Velazquez, Manuel (2014). "Climate change impacts on groundwater and dependent ecosystems". Journal of Hydrology. Climatic change impact on water: Overcoming data and science gaps. 518: 250–266. Bibcode:2014JHyd..518..250K. doi:10.1016/j.jhydrol.2013.06.037. hdl:10251/45180. ISSN 0022-1694.
  58. ^ Chapra, Steven C.; Camacho, Luis A.; McBride, Graham B. (January 2021). "Impact of Global Warming on Dissolved Oxygen and BOD Assimilative Capacity of the World's Rivers: Modeling Analysis". Water. 13 (17): 2408. doi:10.3390/w13172408. ISSN 2073-4441.
  59. ^ Miner, Kimberley R.; D'Andrilli, Juliana; Mackelprang, Rachel; Edwards, Arwyn; Malaska, Michael J.; Waldrop, Mark P.; Miller, Charles E. (2021). "Emergent biogeochemical risks from Arctic permafrost degradation". Nature Climate Change. 11 (10): 809–819. Bibcode:2021NatCC..11..809M. doi:10.1038/s41558-021-01162-y. ISSN 1758-678X. S2CID 238234156.
  60. ^ Milner, Alexander M.; Khamis, Kieran; Battin, Tom J.; Brittain, John E.; Barrand, Nicholas E.; Füreder, Leopold; Cauvy-Fraunié, Sophie; Gíslason, Gísli Már; Jacobsen, Dean; Hannah, David M.; Hodson, Andrew J.; Hood, Eran; Lencioni, Valeria; Ólafsson, Jón S.; Robinson, Christopher T. (2017). "Glacier shrinkage driving global changes in downstream systems". Proceedings of the National Academy of Sciences. 114 (37): 9770–9778. Bibcode:2017PNAS..114.9770M. doi:10.1073/pnas.1619807114. ISSN 0027-8424. PMC 5603989. PMID 28874558.
  61. ^ Yapiyev, Vadim; Wade, Andrew J.; Shahgedanova, Maria; Saidaliyeva, Zarina; Madibekov, Azamat; Severskiy, Igor (2021-12-01). "The hydrochemistry and water quality of glacierized catchments in Central Asia: A review of the current status". Journal of Hydrology: Regional Studies. 38: 100960. doi:10.1016/j.ejrh.2021.100960. S2CID 243980977.
  62. ^ a b Wutich, Amber; Brewis, Alexandra (August 2014). "Food, Water, and Scarcity: Toward a Broader Anthropology of Resource Insecurity". Current Anthropology. 55 (4): 444–468. doi:10.1086/677311. hdl:2286/R.I.25665. ISSN 0011-3204. S2CID 59446967.
  63. ^ a b "Water and Wastewater Systems Sector | Homeland Security". www.dhs.gov. Retrieved 2017-05-07.
  64. ^ Buono, Regina M.; López Gunn, Elena; McKay, Jennifer; Staddon, Chad (2020). Regulating Water Security in Unconventional Oil and Gas (1st ed. 2020 ed.). Cham. ISBN 978-3-030-18342-4. OCLC 1129296222.{{cite book}}: CS1 maint: location missing publisher (link)[page needed]
  65. ^ Guidelines for drinking-water quality (4 ed.). World Health Organization. 2022. p. 45. ISBN 978-92-4-004506-4. Retrieved 1 April 2022.
  66. ^ Andersson, Lotta; Wilk, Julie; Graham, L. Phil; Wikner, Jacob; Mokwatlo, Suzan; Petja, Brilliant (2020-06-01). "Local early warning systems for drought – Could they add value to nationally disseminated seasonal climate forecasts?". Weather and Climate Extremes. 28: 100241. Bibcode:2020WCE....2800241A. doi:10.1016/j.wace.2019.100241. S2CID 212854220.
  67. ^ Portele, Tanja C.; Lorenz, Christof; Dibrani, Berhon; Laux, Patrick; Bliefernicht, Jan; Kunstmann, Harald (2021-05-19). "Seasonal forecasts offer economic benefit for hydrological decision making in semi-arid regions". Scientific Reports. 11 (1): 10581. Bibcode:2021NatSR..1110581P. doi:10.1038/s41598-021-89564-y. ISSN 2045-2322. PMC 8134578. PMID 34011949.
  68. ^ Lledó, Llorenç; Cionni, Irene; Torralba, Verónica; Bretonnière, Pierre-Antoine; Samsó, Margarida (2020-06-22). "Seasonal prediction of Euro-Atlantic teleconnections from multiple". Environmental Research Letters. 15 (7): 074009. Bibcode:2020ERL....15g4009L. doi:10.1088/1748-9326/ab87d2. S2CID 216346466.
  69. ^ a b c d Taye, Meron Teferi; Dyer, Ellen; Charles, Katrina J.; Hirons, Linda C. (2021). "Potential predictability of the Ethiopian summer rains: Understanding local variations and their implications for water management decisions". Science of the Total Environment. 755 (Pt 1): 142604. Bibcode:2021ScTEn.755n2604T. doi:10.1016/j.scitotenv.2020.142604. PMID 33092844. S2CID 225052023.
  70. ^ a b Dyer, Ellen; Washington, Richard (2021). "Kenyan Long Rains: A Subseasonal Approach to Process-Based Diagnostics". Journal of Climate. 34 (9): 3311–3326. Bibcode:2021JCli...34.3311D. doi:10.1175/JCLI-D-19-0914.1. S2CID 230528271.
  71. ^ Pearson, Charles (July 2008). . WMO Bulletin. 57 (3): 173. Archived from the original on December 17, 2023 – via WMO.
  72. ^ a b Dyer, Ellen; Washington, Richard; Teferi Taye, Meron (May 2020). "Evaluating the CMIP5 ensemble in Ethiopia: Creating a reduced ensemble for rainfall and temperature in Northwest Ethiopia and the Awash basin". International Journal of Climatology. 40 (6): 2964–2985. Bibcode:2020IJCli..40.2964D. doi:10.1002/joc.6377. S2CID 210622749.
  73. ^ Dyer, Ellen; Hirons, Linda; Taye, Meron Teferi (2022). "July–September rainfall in the Greater Horn of Africa: the combined influence of the Mascarene and South Atlantic highs". Climate Dynamics. 59 (11–12): 3621–3641. Bibcode:2022ClDy...59.3621D. doi:10.1007/s00382-022-06287-0. S2CID 248408369.  Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  74. ^ WaterAid and BGS (2022) Groundwater: The world's neglected defence against climate change
  75. ^ MacDonald, Alan M; Lark, R Murray; Taylor, Richard G; Abiye, Tamiru; Fallas, Helen C; Favreau, Guillaume; Goni, Ibrahim B; Kebede, Seifu; Scanlon, Bridget; Sorensen, James P R; Tijani, Moshood; Upton, Kirsty A; West, Charles (2021). "Mapping groundwater recharge in Africa from ground observations and implications for water security". Environmental Research Letters. 16 (3): 034012. Bibcode:2021ERL....16c4012M. doi:10.1088/1748-9326/abd661. ISSN 1748-9326. S2CID 233941479.  Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  76. ^ Strategic Framework for WASH Climate Resilient Development (Revised 2017 ed.). GWP and UNICEF. 2014. ISBN 978-91-87823-08-4.
  77. ^ UNICEF Guidance Note: How UNICEF regional and country offices can shift to climate resilient WASH programming (PDF). UNICEF. 2020.
  78. ^ Charles, Katrina J.; Howard, Guy; Villalobos Prats, Elena; Gruber, Joshua; Alam, Sadekul; Alamgir, A.S.M.; Baidya, Manish; Flora, Meerjady Sabrina; Haque, Farhana; Hassan, S.M. Quamrul; Islam, Saiful (2022). "Infrastructure alone cannot ensure resilience to weather events in drinking water supplies". Science of the Total Environment. 813: 151876. Bibcode:2022ScTEn.813o1876C. doi:10.1016/j.scitotenv.2021.151876. hdl:1983/92cc5791-168b-457a-93c7-458890f1bf26. PMID 34826465.
  79. ^ a b c d e Grasham, Catherine Fallon; Calow, Roger; Casey, Vincent; Charles, Katrina J.; de Wit, Sara; Dyer, Ellen; Fullwood-Thomas, Jess; Hirons, Mark; Hope, Robert; Hoque, Sonia Ferdous; Jepson, Wendy; Korzenevica, Marina; Murphy, Rebecca; Plastow, John; Ross, Ian (2021). "Engaging with the politics of climate resilience towards clean water and sanitation for all". npj Clean Water. 4 (1): 42. Bibcode:2021npjCW...4...42G. doi:10.1038/s41545-021-00133-2. ISSN 2059-7037. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  80. ^ a b c Murgatroyd A, Charles KJ, Chautard A, Dyer E, Grasham C, Hope R, et al. (2021). Water Security for Climate Resilience Report: A synthesis of research from the Oxford University REACH programme (Report). University of Oxford, UK. Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  81. ^ a b Taye, Meron Teferi; Dyer, Ellen (22 August 2019). "Ethiopia's future is tied to water -- a vital yet threatened resource in a changing climate". The Conversation. Retrieved 4 August 2022.
  82. ^ a b UNICEF and GWP (2022) Strategic Framework for WASH Climate Resilient Development - 2022 Edition, Prepared in cooperation with HR Wallingford in 2014, 2017 and 2022, and with the Overseas Development Institute (ODI) in 2014, ISBN 978-91-87823-69-5
  83. ^ a b c Gain, Animesh K; Giupponi, Carlo; Wada, Yoshihide (2016). "Measuring global water security towards sustainable development goals". Environmental Research Letters. 11 (12): 124015. Bibcode:2016ERL....11l4015G. doi:10.1088/1748-9326/11/12/124015. ISSN 1748-9326.   Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  84. ^ a b Young, Sera L.; Boateng, Godfred O.; Jamaluddine, Zeina; Miller, Joshua D.; Frongillo, Edward A.; Neilands, Torsten B.; Collins, Shalean M.; Wutich, Amber; Jepson, Wendy E.; Stoler, Justin (2019-09-01). "The Household Water InSecurity Experiences (HWISE) Scale: development and validation of a household water insecurity measure for low-income and middle-income countries". BMJ Global Health. 4 (5): e001750. doi:10.1136/bmjgh-2019-001750. PMC 6768340. PMID 31637027.
  85. ^ a b c d e Borgomeo, Edoardo; Hall, Jim W.; Salehin, Mashfiqus (2018). "Avoiding the water-poverty trap: insights from a conceptual human-water dynamical model for coastal Bangladesh". International Journal of Water Resources Development. 34 (6): 900–922. doi:10.1080/07900627.2017.1331842. S2CID 28011229.
  86. ^ "Development Projects : Coastal Embankment Improvement Project - Phase I (CEIP-I) - P128276". World Bank. Retrieved 2023-02-10.
  87. ^ "Blue Gold Program, Bangladesh - Mott MacDonald". www.mottmac.com. Retrieved 2023-02-10.
  88. ^ "CHIRPS: Rainfall Estimates from Rain Gauge and Satellite Observations | Climate Hazards Center - UC Santa Barbara". www.chc.ucsb.edu. Retrieved 2022-09-14.
  89. ^ a b c Abebe, Dawit (2010). "Future climate of Ethiopia from PRECIS Regional Climate Model Experimental Design" (PDF). Met Office UK. Retrieved 21 August 2022.
  90. ^ a b "Ethiopia: Drought Update No. 4, June 2022 - Ethiopia | ReliefWeb". reliefweb.int. 3 June 2022. Retrieved 2022-07-06.
  91. ^ a b Borgomeo, Edoardo; Vadheim, Bryan; Woldeyes, Firew B.; Alamirew, Tena; Tamru, Seneshaw; Charles, Katrina J.; Kebede, Seifu; Walker, Oliver (2018). "The Distributional and Multi-Sectoral Impacts of Rainfall Shocks: Evidence From Computable General Equilibrium Modelling for the Awash Basin, Ethiopia". Ecological Economics. 146: 621–632. doi:10.1016/j.ecolecon.2017.11.038.   Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
  92. ^ a b Oluwasanya, G., Perera, D., Qadir, M., Smakhtin, V., 2022. Water Security in Africa: A Preliminary Assessment, Issue 13. United Nations University Institute for Water, Environment and Health, Hamilton, Canada.
  93. ^ Ferrer, Núria; Folch, Albert; Lane, Mike; Olago, Daniel; Odida, Julius; Custodio, Emilio (2019-04-15). "Groundwater hydrodynamics of an Eastern Africa coastal aquifer, including La Niña 2016–17 drought". Science of the Total Environment. 661: 575–597. Bibcode:2019ScTEn.661..575F. doi:10.1016/j.scitotenv.2019.01.198. hdl:2117/134140. ISSN 0048-9697. PMID 30682610. S2CID 59274112.
  94. ^ "State Department for Arid and Semi-Arid Lands, Kenya". State Department for Arid and Semi-Arid Lands, Kenya. Retrieved 2023-01-25.
  95. ^ a b Njoka, J.T., Yanda, P., Maganga, F., Liwenga, E., Kateka, A., Henku, A., Mabhuye, E., Malik, N. and Bavo, C. (2016) 'Kenya: country situation assessment', PRISE working paper. Center for Sustainable Dryland Ecosystems and Societies, University of Nairobi. https://idl-bnc-idrc.dspacedirect.org/bitstream/handle/10625/58566/IDL-58566.pdf
  96. ^ Reid, Robin S.; Fernández-Giménez, María E.; Galvin, Kathleen A. (2014-10-17). "Dynamics and Resilience of Rangelands and Pastoral Peoples Around the Globe". Annual Review of Environment and Resources. 39 (1): 217–242. doi:10.1146/annurev-environ-020713-163329. ISSN 1543-5938. S2CID 154486594.
  97. ^ Balfour, Nancy; Obando, Joy; Gohil, Deepali (2020-01-01). "Dimensions of water insecurity in pastoralist households in Kenya". Waterlines. 39 (1): 24–43. doi:10.3362/1756-3488.19-00016. ISSN 0262-8104. S2CID 216343833.
  98. ^ Barasa M, Crane E, Upton K, Ó Dochartaigh BÉ and Bellwood-Howard I. 2018. Africa Groundwater Atlas: Hydrogeology of Kenya. British Geological Survey. Accessed [27 January 2023]. https://earthwise.bgs.ac.uk/index.php/Hydrogeology_of_Kenya#Groundwater_use
  99. ^ Mumma, Albert; Lane, Michael; Kairu, Edward; Tuinhof, Albert; Hirji, Rafik. 2011. Kenya Groundwater Governance Case Study. Water papers. Washington, DC. World Bank. License: CC BY 3.0 IGO. https://openknowledge.worldbank.org/handle/10986/17227
  100. ^ Foster, Tim; Hope, Rob (2016-10-01). "A multi-decadal and social-ecological systems analysis of community waterpoint payment behaviours in rural Kenya". Journal of Rural Studies. 47: 85–96. doi:10.1016/j.jrurstud.2016.07.026. ISSN 0743-0167. S2CID 156255059.

External links edit

  • International Water Security Network
  • Water Security (an open source journal that started in 2017)

February 15, 2024
water, security, water, security, make, most, water, benefits, humans, ecosystems, second, limit, risks, destructive, impacts, water, acceptable, level, these, risks, include, example, much, water, flood, little, water, drought, water, scarcity, poor, quality,. The aim of water security is to make the most of water s benefits for humans and ecosystems The second aim is to limit the risks of destructive impacts of water to an acceptable level 1 2 These risks include for example too much water flood too little water drought and water scarcity or poor quality polluted water 1 People who live with a high level of water security always have access to an acceptable quantity and quality of water for health livelihoods and production 2 For example access to water sanitation and hygiene services is one part of water security 3 Some organizations use the term water security more narrowly for water supply aspects only Water security has many different aspects in clockwise order from top left a communal tap for water supply in Soweto South Africa residents standing in flood water in Kampala Uganda the town of Farina in South Australia abandoned due to years of drought and dust storms water pollution can lead to eutrophication harmful algal blooms and fish kills Decision makers and water managers aim to reach water security goals that address multiple concerns These outcomes can include increasing economic and social well being while reducing risks tied to water 4 There are linkages and trade offs between the different outcomes 3 13 Planners often consider water security effects for varied groups when they design climate change reduction strategies 5 19 21 Three main factors determine how difficult or easy it is for a society to sustain its water security These include the hydrologic environment the socio economic environment and changes in the future environment This last is mainly due to climate change 1 Decision makers may assess water security risks at varied levels These range from the household to community city basin country and region 3 11 The absence of water security is water insecurity 6 5 Water insecurity is a growing threat to societies 7 4 The main factors contributing to water insecurity are water scarcity water pollution and low water quality due to climate change impacts Others include poverty destructive forces of water and disasters that stem from natural hazards Climate change affects water security in many ways Changing rainfall patterns including droughts can have a big impact on water availability Flooding can worsen water quality Stronger storms can damage infrastructure especially in the Global South 8 660 There are different ways to deal with water insecurity Science and engineering approaches can increase the water supply or make water use more efficient Financial and economic tools can include a safety net to ensure access for poorer people Management tools such as demand caps can improve water security 7 16 They work on strengthening institutions and information flows They may also improve water quality management reduce inequalities and investment in water infrastructure Improving the climate resilience of water and hygiene services is important These efforts help to reduce poverty and achieve sustainable development 2 There is no single method to measure water security 8 562 Metrics of water security roughly fall into two groups This includes those that are based on experiences versus metrics that are based on resources The former mainly focus on measuring the water experiences of households and human well being The latter tend to focus on freshwater stores or water resources security 9 The IPCC Sixth Assessment Report found that increasing weather and climate extreme events have exposed millions of people to acute food insecurity and reduced water security Scientists have observed the largest impacts in Africa Asia Central and South America Small Islands and the Arctic 10 9 The report predicted that global warming of 2 C would expose roughly 1 4 billion people to water stress It finds 1 5 2 5 billion people live in areas exposed to water scarcity 10 660 Contents 1 Definitions 1 1 Broad definition 1 2 Narrower definition with a focus on water supply 1 3 Relationship with WASH and IWRM 2 Related concepts 2 1 Water risk 2 2 Water conflict 3 Desired outcomes 4 Determining factors 4 1 Hydrologic environment 4 2 Socio economic environment 4 3 Climate change 5 Challenges and threats 5 1 Water scarcity 5 2 Water pollution 5 3 Reduced water quality due to climate change 5 4 Poverty 5 5 Destructive forces of water 5 6 Other threats 6 Management approaches 6 1 Investment decisions 6 1 1 Institutions 6 1 2 Information flows 6 1 3 Infrastructure 6 2 Consideration of scales 6 3 Reducing inequalities in water security 6 4 Improving climate resilience of water and sanitation services 7 Measurement tools 8 Global estimates 9 Country examples 9 1 Bangladesh 9 2 Ethiopia 9 3 Kenya 10 See also 11 References 12 External linksDefinitions editBroad definition edit There are various definitions for the term water security 11 12 5 It emerged as a concept in the 21st century It is broader than the absence of water scarcity 1 It differs from the concepts of food security and energy security Whereas those concepts cover reliable access to food or energy water security covers not only the absence of water but also its presence when there is too much of it 2 One definition of water security is the reliable availability of an acceptable quantity and quality of water for health livelihoods and production coupled with an acceptable level of water related risks 2 A similar definition of water security by UN Water is the capacity of a population to safeguard sustainable access to adequate quantities of acceptable quality water for sustaining livelihoods human well being and socio economic development for ensuring protection against water borne pollution and water related disasters and for preserving ecosystems in a climate of peace and political stability 11 1 13 World Resources Institute also gave a similar definition in 2020 For purposes of this report we define water security as the capacity of a population to safeguard sustainable access to adequate quantities of acceptable quality water for sustaining livelihoods human well being and socioeconomic development protect against water pollution and water related disasters and preserve ecosystems upon which clean water availability and other ecosystem services depend 7 17 Narrower definition with a focus on water supply edit Some organizations use water security in a more specific sense to refer to water supply only They do not consider the water related risks of too much water For example the definition of WaterAid in 2012 focuses on water supply issues They defined water security as reliable access to water of sufficient quantity and quality for basic human needs small scale livelihoods and local ecosystem services coupled with a well managed risk of water related disasters 11 5 The World Water Council also uses this more specific approach with a focus on water supply Water security refers to the availability of water in adequate quantity and quality to sustain all these needs together social and economic sectors as well as the larger needs of the planet s ecosystems without exceeding its ability to renew 14 15 Relationship with WASH and IWRM edit WASH water sanitation and hygiene is an important concept when we discuss water security Access to WASH services is one part of achieving water security 3 The relationship works both ways To be sustainable WASH services need to address water security issues 16 4 For example WASH relies on water resources that are part of the water cycle But climate change has many impacts on the water cycle which can threaten water security 11 vII There is also growing competition for water This reduces the availability of water resources in many areas in the world 16 4 Water security incorporates ideas and concepts to do with the sustainability integration and adaptiveness of water resource management 17 4 In the past experts used terms such as integrated water resources management IWRM or sustainable water management for this Related concepts editWater risk edit Water risk refers to the possibility of problems to do with water Examples are water scarcity water stress flooding infrastructure decay and drought 18 4 There exists an inverse relationship between water risk and water security This means as water risk increases water security decreases Water risk is complex and multilayered It includes risks flooding and drought These can lead to infrastructure failure and worsen hunger 19 When these disasters take place they result in water scarcity or other problems The potential economic effects of water risk are important to note Water risks threaten entire industries Examples are the food and beverage sector agriculture oil and gas and utilities Agriculture uses 69 of total freshwater in the world So this industry is very vulnerable to water stress 20 Risk is a combination of hazard exposure and vulnerability 4 Examples of hazards are droughts floods and decline in quality Bad infrastructure and bad governance lead to high exposure to risk The financial sector is becoming more aware of the potential impacts of water risk and the need for its proper management By 2025 water risk will threaten 145 trillion in assets under management 21 To control water risk companies can develop water risk management plans 19 Stakeholders within financial markets can use these plans to measure company environmental social and governance ESG performance They can then identify leaders in water risk management 22 20 The World Resources Institute has developed an online water data platform named Aqueduct for risk assessment and water management China Water Risk is a nonprofit dedicated to understanding and managing water risk in China The World Wildlife Fund has a Water Risk Filter that helps companies assess and respond to water risk with scenarios for 2030 and 2050 23 Understanding risk is part of water security policy But it is also important to take social equity considerations more into account 24 There is no wholly accepted theory or mathematical model for determining or managing water risk 3 13 Instead managers use a range of theories models and technologies to understand the trade offs that exist in responding to risk Water conflict edit This section is an excerpt from Water conflict edit nbsp Ethiopia s move to fill the dam s reservoir could reduce Nile flows by as much as 25 and devastate Egyptian farmlands 25 Water conflict typically refers to violence or disputes associated with access to or control of water resources or the use of water or water systems as weapons or casualties of conflicts The term water war is colloquially used in media for some disputes over water and often is more limited to describing a conflict between countries states or groups over the rights to access water resources 26 27 The United Nations recognizes that water disputes result from opposing interests of water users public or private 28 A wide range of water conflicts appear throughout history though they are rarely traditional wars waged over water alone 29 Instead water has long been a source of tension and one of the causes for conflicts Water conflicts arise for several reasons including territorial disputes a fight for resources and strategic advantage 30 Water conflicts can occur on the intrastate and interstate levels Interstate conflicts occur between two or more countries that share a transboundary water source such as a river sea or groundwater basin For example the Middle East has only 1 of the world s fresh water shared among 5 of the world s population and most of the rivers cross international borders 31 Intrastate conflicts take place between two or more parties in the same country such as conflicts between farmers and urban water users Desired outcomes editThere are three groups of water security outcomes These include economic environmental and equity or social outcomes 1 Outcomes are things that are happening or that we want to see happen as a result of policy and management Economic outcomes Sustainable growth which takes changing water needs and threats into account 3 Sustainable growth includes job creation increased productivity and standards of living Environmental outcomes Quality and availability of water for the ecosystems services that depend on this water resource Loss of freshwater biodiversity and depletion of groundwater are examples of negative environmental outcomes 32 33 Equity or social outcomes Inclusive services so that consumers industry and agriculture can access safe reliable sufficient and affordable water These also mean they can dispose of wastewater safely This area includes gender issues empowerment participation and accountability 1 There are four major focus areas for water security and its outcomes It is about using water so that we increase economic and social welfare move towards long term sustainability or reduce risks tied to water 4 Decision makers and water managers must consider the linkages and trade offs between the varied types of outcomes 3 13 Improving water security is a key factor to achieve growth development that is sustainable and reduce poverty 2 Water security is also about social justice and fair distribution of environmental benefits and harms 34 Development that is sustainable can help reduce poverty and increase living standards This is most likely to benefit those affected by the impacts of insecure water resources in the region especially women and children Water security is important for attaining most of the 17 United Nations Sustainable Development Goals SDGs This is because access to adequate and safe water is a precondition for meeting many of the individual goals 8 4 8 It is also important for attaining development that is resilient to climate change 8 4 7 Planners take note of water security outcomes for various groups in society when they design strategies for climate change adaptation 3 19 21 Determining factors editThree main factors determine the ability of a society to sustain water security 2 Hydrologic environment Socio economic environment Changes in the future environment climate change Hydrologic environment edit The hydrologic environment is important for water security The term hydrologic environment refers to the absolute level of water resource availability But it also refers to how much it varies in time and location Inter annual means from one year to the next Intra annual means from one season to the next We can refer to location as spatial distribution 2 Scholars distinguish between a hydrologic environment that is easy to manage and one that is difficult 2 An easy to manage hydrologic environment would be one with low rainfall variability In this case rain is distributed throughout the year and perennial river flows sustained by groundwater base flows For example many of the world s industrialized nations have a hydrologic environment that they can manage quite easily This has helped them achieve water security early in their development 2 A difficult to manage hydrologic environment is one with absolute water scarcity such as deserts or low lying lands prone to severe flood risk Regions where rainfall is very variable from one season to the next or regions where rainfall varies a lot from one year to the next are also likely to face water security challenges We call this high inter annual climate variability An example would be East Africa where there have been prolonged droughts every two to three years since 1999 35 Most of the world s developing countries have challenges in managing hydrologies and have not achieved water security This is not a coincidence 2 The poverty and hydrology hypothesis states that regions with a difficult hydrology remain poor because the respective governments have not been able to make the large investments necessary to achieve water security Examples of such regions would be those with rainfall variability within one year and across several years This leads to water insecurity which constrains economic growth 2 There is a statistical link between increased changes in rainfall patterns and lower per capita incomes 36 Socio economic environment edit Relative levels of economic development and equality or inequality are strong determinants of community and household scale water security Whilst the poverty and hydrology hypothesis suggests that there is a link between poverty and difficult hydrologies there are many examples of difficult hydrologies that have not yet resulted in poverty and water insecurity 2 37 Social and economic inequalities are strong drivers of water insecurity especially at the community and household scales Gender race and caste inequalities have all been linked to differential access to water services such as drinking water and sanitation In particular women and girls frequently have less access to economic and social opportunities as a directly consequence of being primarily responsible for meeting household water needs The entire journey from water source to point of use is fraught with hazards largely faced by women and girls 38 There is strong evidence that improving access to water and sanitation is a good way of addressing such inequalities Climate change edit Further information Effects of climate change on the water cycle and Water security Reduced water quality due to climate change impactsImpacts of climate change that are tied to water affect people s water security on a daily basis They include more frequent and intense heavy precipitation which affects the frequency size and timing of floods 39 Also droughts can alter the total amount of freshwater and cause a decline in groundwater storage and reduction in groundwater recharge 40 Reduction in water quality due to extreme events can also occur 8 558 Faster melting of glaciers can also occur 41 Global climate change will probably make it more complex and expensive to ensure water security 2 It creates new threats and adaptation challenges 1 This is because climate change leads to increased hydrological variability and extremes Climate change has many impacts on the water cycle These result in higher climatic and hydrological variability which can threaten water security 11 vII Changes in the water cycle threaten existing and future water infrastructure It will be harder to plan investments for future water infrastructure as there are so many uncertainties about future variability for the water cycle 1 This makes societies more exposed to risks of extreme events linked to water and therefore reduces water security 11 vII It is difficult to predict the effects of climate change on national and local levels Water security will be affected by sea level rise in low lying coastal areas while populations dependent on snowmelt as their water source will be affected by the recession of glaciers and mountain snow 12 21 Future climate change must be viewed in context of other existing challenges for water security Other challenges existing climate variability in areas closer to the equator population growth and increased demand for water resources Others include political challenges increased disaster exposure due to settlement in hazard prone areas and environmental degradation 12 22 Water demand for irrigation in agriculture will increase due to climate change This is because evaporation rates and the rate of water loss from crops will be higher due to rising temperatures 7 4 Climate factors have a major effect on water security as various levels Geographic variability in water availability reliability of rainfall and vulnerability to droughts floods and cyclones are inherent hazards that affect development opportunities These play out at international to intra basin scales At local scales social vulnerability is a factor that increases the risks to water security no matter the cause 5 6 For example people affected by poverty may have less ability to cope with climate shocks 5 Challenges and threats editThere are many factors that contribute to low water security Some examples are 7 4 6 9 Water scarcity Water demand exceeds supply in many regions of the world This can be due to population growth higher living standards general economic expansion and or greater quantities of water used in agriculture for irrigation Increasing water pollution and low levels of wastewater treatment which is making local water unusable Poor planning of water use poor water management and misuse These can cause groundwater levels to drop rivers and lakes to dry out and local ecosystems to collapse Trans boundary waters and international rivers which belong to several countries Country borders often do not align with natural watersheds One reason is that international borders result from boundaries during colonialism 2 Climate change This makes water related disasters such as droughts and floods more frequent and intense rising temperatures and sea levels can contaminate freshwater sources 6 9 Water scarcity edit A major threat to water security is water scarcity About 27 of the world s population lived in areas affected by water scarcity in the mid 2010s This number will likely increase to 42 by 2050 42 This section is an excerpt from Water scarcity edit nbsp Map of global water stress a symptom of water scarcity in 2019 Water stress is the ratio of water use relative to water availability and is therefore a demand driven scarcity 43 Water scarcity closely related to water stress or water crisis is the lack of fresh water resources to meet the standard water demand There are two types of water scarcity namely physical and economic water scarcity 44 560 Physical water scarcity is where there is not enough water to meet all demands including that needed for ecosystems to function Arid areas for example Central Asia West Asia and North Africa often experience physical water scarcity 45 Economic water scarcity on the other hand is the result of lack of investment in infrastructure or technology to draw water from rivers aquifers or other water sources It also results from weak human capacity to meet water demand 44 560 Much of Sub Saharan Africa experiences economic water scarcity 46 11 There is enough freshwater available globally and averaged over the year to meet demand As such water scarcity is caused by a mismatch between when and where people need water and when and where it is available 47 The main drivers of the increase in global water demand are the increasing world population rise in living conditions changing diets to more animal products 48 and expansion of irrigated agriculture 49 50 Climate change including droughts or floods deforestation water pollution and wasteful use of water can also cause insufficient water supply 51 Scarcity varies over time as a result of natural variability in hydrology These variations in scarcity may also be a function of prevailing economic policy and planning approaches Water pollution edit Water pollution is a threat to water security It can affect the supply of drinking water and indirectly contribute to water scarcity This section is an excerpt from Water pollution edit Water pollution or aquatic pollution is the contamination of water bodies usually as a result of human activities so that it negatively affects its uses 52 6 Water bodies include lakes rivers oceans aquifers reservoirs and groundwater Water pollution results when contaminants mix with these water bodies Contaminants can come from one of four main sources sewage discharges industrial activities agricultural activities and urban runoff including stormwater 53 Water pollution is either surface water pollution or groundwater pollution This form of pollution can lead to many problems such as the degradation of aquatic ecosystems or spreading water borne diseases when people use polluted water for drinking or irrigation 54 Another problem is that water pollution reduces the ecosystem services such as providing drinking water that the water resource would otherwise provide Reduced water quality due to climate change edit nbsp Drinking water quality framework Environment including weather events infrastructure and management affect drinking water quality at the point of collection PoC and point of use PoU 55 Weather and its related shocks can affect water quality in several ways These depend on the local climate and context 55 Shocks that are linked to weather include water shortages heavy rain and temperature extremes They can damage water infrastructure through erosion under heavy rainfall and floods cause loss of water sources in droughts and make water quality deteriorate 55 Climate change can reduce lower water quality in several ways 8 582 Heavy rainfall can rapidly reduce the water quality in rivers and shallow groundwater It can affect water quality in reservoirs even if these effects can be slow 56 Heavy rainfall also impacts groundwater in deeper unfractured aquifers But these impacts are less pronounced Rainfall can increase fecal contamination of water sources 55 Floods after heavy rainfalls can mix floodwater with wastewater Also pollutants can reach water bodies by increased surface runoff Groundwater quality may deteriorate due to droughts The pollution in rivers that feed groundwater becomes less diluted As groundwater levels drop rivers may lose direct contact with groundwater 57 In coastal regions more saltwater may mix into freshwater aquifers due to sea level rise and more intense storms 11 16 4 This process is called saltwater intrusion Warmer water in lakes oceans reservoirs and rivers can cause more eutrophication This results in more frequent harmful algal blooms 8 140 Higher temperatures cause problems for water bodies and aquatic ecosystems because warmer water contains less oxygen 58 Permafrost thawing leads to an increased flux of contaminants 59 Increased meltwater from glaciers may release contaminants 60 As glaciers shrink or disappear the positive effect of seasonal meltwater on downstream water quality through dilution is disappearing 61 Poverty edit People in low income countries are at greater risk of water insecurity and may also have less resources to mitigate it This can result in human suffering sustained poverty constrained growth and social unrest 2 Food and water insecurity pose significant challenges for numerous individuals across the United States Strategies employed by households in response to these pressing issues encompass labor intensive methods such as melting ice earning wages and occasionally incurring debt all aimed at water conservation Additionally families may turn to foraging for water based plants and animals seeking alternative sources of sustenance Adjusting consumption patterns becomes imperative involving the rationing of servings and prioritizing nutritional value particularly for vulnerable members like small children The phenomenon of substituting more expensive nutritious food with cheaper alternatives is also observed 62 Furthermore individuals may consume from sources considered stigmatized by society such as urine or unfiltered water Migration emerges as a viable option with families fostering children to relatives outside famine zones and engaging in seasonal or permanent resettlement In certain instances resource preservation involves the challenging decision of abandoning specific family members This is achieved through withholding resources from non family members prioritizing the health of some family members over others and in extreme cases leaving individuals behind As the climate changes the impact of food and water insecurity is disproportionately felt necessitating a re evaluation of societal misconceptions about those making survival sacrifices Larger entities including the government and various organizations extend assistance based on available resources highlighting the importance of addressing information gaps in specific data 62 Destructive forces of water edit nbsp Flooded roads in Ponce Puerto Rico a week after Hurricane Maria devastated the island 2017 Water can cause large scale destruction due to its huge power 2 This destruction can result from sudden events Examples are tsunamis floods or landslides Events that happen slowly over time such as erosion desertification or water pollution can also cause destruction 2 Other threats edit Other threats to water security include Disasters caused by natural hazards such as hurricanes earthquakes and wildfires These can damage man made structures such as dams and fill waterways with debris Some climate change mitigation measures which need a lot of water Bioenergy with carbon capture and storage afforestation and reforestation may use relatively large amounts of water if done at inappropriate locations 8 4 8 We call this a high water footprint Terrorism such as water supply terrorism 63 Radiation due to a nuclear accident 63 New water uses such as hydraulic fracturing for energy resources 64 Armed conflict and migration Migration can be due to water scarcity at the origin or it can lead to more water scarcity at the target destinations 6 9 Management approaches editThere are different ways to tackle water insecurity Science and engineering approaches can increase the water supply or make water use more efficient Financial and economic tools can be used as a safety net for poorer people Higher prices may encourage more investments in water systems Finally management tools such as demand caps can improve water security 7 16 104 Decision makers invest in institutions information flows and infrastructure to achieve a high level of water security 1 Investment decisions edit Institutions edit The right institutions are important to improve water security 2 Institutions govern how decisions can promote or constrain water security outcomes for the poor 3 Strengthening institutions might involve reallocating risks and duties between the state market and communities in new ways This can include performance based models development impact bonds or blended finance from government donors and users These finance mechanisms are set up to work jointly with state private sector and communities investors 3 37 Sustainable Development Goal 16 is about peace justice and strong institutions It recognizes that strong institutions are a necessary condition for sustainable development including water security 3 35 Drinking water quality and water pollution are linked But policymakers often do not address them in a comprehensive way For example pollution from industries is often not linked to drinking water quality in developing countries 3 32 Keeping track of river groundwater and wastewater is important It can identify sources of contamination and guide targeted regulatory responses The WHO has described water safety plans as the most effective means of maintaining a safe supply of drinking water to the public 65 Information flows edit It is important for institutions to have access to information about water This helps them with their planning and decision making 1 It also helps with tracking how accountable and effective policies are Investments into climate information tools that are appropriate for the local context are useful 5 59 They cover a wide range of temporal and spatial scales They also respond to regional climate risks tied to water 5 58 Seasonal climate and hydrological forecasts can be useful to prepare for and reduce water security risks They are especially useful if people can apply them at the local scale 66 67 Applying knowledge of how climate anomalies relate to each other over long distances can improve seasonal forecasts for specific regions These teleconnections are correlations between patterns of rainfall temperature and wind speed between distant areas They are caused by large scale ocean and atmospheric circulation 68 69 In regions where rainfall varies with the seasons and from year to year water managers would like to have more accurate seasonal weather forecasts In some locations the onset of seasonal rainfall is particularly hard to predict This is because aspects of the climate system are difficult to describe with mathematical models For example the long rains in East Africa which fall March to May have been difficult to simulate with climate models When climate models work well they can produce useful seasonal forecasts 70 One reason for these difficulties is the complex topography of the area 70 Improved understanding of atmospheric processes may allow climate scientists to provide more relevant and localized information to water managers on a seasonal timescale They could also provide more detailed predictions for the effects of climate change on a longer timeframe 71 nbsp Annual rainfall pattern in two regions of Ethiopia The lines represent observations red dashed line and model results green line in a climate model study of the region 72 One example would be seasonal forecasts of rainfall in Ethiopia s Awash river basin These may become more accurate by understanding better how sea surface temperatures in different ocean regions relate to rainfall patterns in this river basin 69 At a larger regional scale a better understanding of the relationship between pressure systems in the Indian Ocean and the South Atlantic on the one hand and wind speeds and rainfall patterns in the Greater Horn of Africa on the other hand would be helpful This kind of scientific analysis may contribute to improved representation of this region in climate models to assist development planning 73 It could also guide people when they plan water allocation in the river basin or prepare emergency response plans for future events of water scarcity and flooding 69 Infrastructure edit Water infrastructure serves to access store regulate move and conserve water Several assets carry out these functions Natural assets are lakes rivers wetlands aquifers springs Engineered assets are bulk water management infrastructure such as dams 2 Examples include 1 Improved water storage using natural water storage systems such as aquifers and wetlands or built infrastructure such as storage tanks and dams Using new water sources to add to the existing water supplies This can be done through water reuse desalination rainwater harvesting and groundwater pumping Embankments or levee or dike for flood protection Public and private spending on water infrastructure and supporting institutions must be well balanced They are likely to evolve over time 2 This is important to avoid unplanned social and environmental costs from building new facilities For example in the case of Africa investments into groundwater use is an option to increase water security and for climate change adaptation 74 Water security in African countries could benefit from the distribution of groundwater storage and recharge on the continent Recharge is a process where water moves to groundwater Many countries that have low recharge have substantial groundwater storage Countries with low storage typically have high regular recharge 75 Consideration of scales edit People manage water security risks at different spatial scales These range from the household to community town city basin and region 3 11 At the local scale actors include county governments schools water user groups local water providers and the private sector At the next larger scale there are basin and national level actors These actors help to identify any constraints with regards to policy institutions and investments Lastly there are global actors such as the World Bank UNICEF FCDO WHO and USAID They help to develop suitable service delivery models 3 11 The physical geography of a country shows the correct scale that planners should use for managing water security risks Even within a country the hydrologic environment may vary a lot See for example the variations in seasonal rainfall across Ethiopia Reducing inequalities in water security edit Inequalities with regards to water security within a society have structural and historical roots They can affect people at different scales These range from the household to the community town river basin or the region 3 20 High risk social groups and regions can be identified during political debates but are often ignored Water inequality is often tied to gender in low income countries At the household level women are often the water managers But they have limited choices over water and related issues 3 21 Improving climate resilience of water and sanitation services editMany institutions are working to develop WASH services that are resilient to climate 3 27 37 76 77 This section is an excerpt from WASH Improving climate resilience edit Climate resilient water services or climate resilient WASH are services that provide access to high quality drinking water during all seasons and even during extreme weather events 78 Climate resilience in general is the ability to recover from or to mitigate vulnerability to climate related shocks such as floods and droughts 79 Climate resilient development has become the new paradigm for sustainable development This concept thus influences theory and practice across all sectors globally 79 This is particularly true in the water sector since water security is closely connected to climate change On every continent governments are now adopting policies for climate resilient economies International frameworks such as the Paris Agreement and the Sustainable Development Goals are drivers for such initiatives 79 Several activities can improve water security and increase resilience to climate risks Carrying out a detailed analysis of climate risk to make climate information relevant to specific users developing metrics for monitoring climate resilience in water systems this will help to track progress and guide investments for water security and using new institutional models that improve water security 80 Climate resilient policies can be useful for allocating water keeping in mind that less water may be available in future This requires a good understanding of the current and future hydroclimatic situation For example a better understanding of future changes in climate variability leads to a better response to their possible impacts 81 To build climate resilience into water systems people need to have access to climate information that is appropriate for their local context 80 59 Climate information products are useful if they cover a wide range of temporal and spatial scales and provide information on regional water related climate risks 80 58 For example government staff need easy access to climate information to achieve better water management 81 Four important activities to achieve climate resilient WASH services include First a risk analysis is performed to look at possible implications of extreme weather events as well as preventive actions 82 4 Such preventive actions can include for example elevating the infrastructure to be above expected flood levels Secondly managers assess the scope for reducing greenhouse gas emissions and put in place suitable options e g using more renewable energy sources Thirdly the water utilities ensure that water sources and sanitation services are reliable at all times during the year also during times of droughts and floods Finally the management and service delivery models are strengthened so that they can withstand a crisis 82 5 To put climate resilience into practice and to engage better with politicians the following guide questions are useful resilience of what to what for whom over what time frame by whom and at what scale 79 For example resilience of what means thinking beyond infrastructure but to also include resilience of water resources local institutions and water users Another example is that resilience for whom speaks about reducing vulnerability and preventing negative developments Some top down interventions that work around power and politics may undermine indigenous knowledge and compromise community resilience 79 Measurement tools edit nbsp Aggregated global water security index calculated using the aggregation of water availability accessibility safety and quality and management indices The value 0 1 with the continuous color red to blue represents low to high security 83 There is no single way to measure water security 8 562 There are no standard indicators to measure water security That is because it is a concept that focuses on outcomes 1 The outcomes that are regard as important can change depending on the context and stakeholders Instead it is common to compare relative levels of water security by using metrics for certain aspects of water security 8 562 For example the Global Water Security Index includes metrics on availability water scarcity index drought index groundwater depletion accessibility to water services access to sanitation and drinking water safety and quality water quality index global flood frequency management World Governance Index transboundary legal framework transboundary political tension 83 Scientists have been working on ways to measure water security at a variety of levels The metrics roughly fall into two groups There are those that are based on experiences versus metrics that are based on resources The former mainly focus on measuring the experiences of households and human well being Meanwhile the latter focuses on the amount of available freshwater 9 The Household Water Insecurity Experiences HWISE Scale measures several components of water insecurity at the household level These include adequacy reliability accessibility and safety 84 This scale can help to identify vulnerable subpopulations and ensure resources are allocated to those in need It can also measure how effective of water policies and projects are 84 Global estimates editThe IPCC Sixth Assessment Report summarises the current and future water security trends It says that increasing weather and extreme climate events have led to acute food insecurity and reduced water security for millions of people The largest impacts are seen in Africa Asia Central and South America Small Islands and the Arctic 10 9 The same report predicted that global warming of 2 C would expose roughly 1 4 billion people to water stress This would depend on regional patterns of climate change and the socio economic scenarios 8 558 On water scarcity which is one factor in water insecurity the report finds 1 5 2 5 billion people live water scarce areas 10 660 Water scarcity and water security are not always equal There are regions with high water security even though they also experience water scarcity Examples are parts of the United States Australia and Southern Europe This is due to efficient water services that have a high level of safety quality and accessibility 83 8 562 However even in those regions groups such as Indigenous peoples tend to have less access to water and face water insecurity at times 8 562 Country examples editBangladesh edit Further information Water supply and sanitation in Bangladesh and Climate change in Bangladesh nbsp nbsp Too much water can also cause water insecurity Left Flooding in Bangladesh right People on an island in a flooded river in Bangladesh Risks to water security in Bangladesh include 5 45 natural hazards that related to the climate climate hazards some impacts of urbanization impacts from climate change such as changes to precipitation patterns and sea level rise The country experiences water security risks in the capital Dhaka as well as in the coastal region 5 In Dhaka monsoonal pulses can lead to urban flooding This can pollute the water supply 5 A number of processes and events cause water risks for about 20 million people in the coastal regions These include aquifers that are getting saltier seasonal water scarcity fecal contamination and flooding from the monsoon and from storm surges due to cyclones 5 64 Different types of floods occur in coastal Bangladesh They are river floods tidal floods and storm surge floods due to tropical cyclones 85 These floods can damage drinking water infrastructure They can also lead to reduced water quality as well as losses in agricultural and fishery yields 5 There is a link between water insecurity and poverty in the low lying areas in the Ganges Brahmaputra tidal delta plain 85 Those low lying areas are embanked areas in coastal Bangladesh The government has various programs to reduce risks for people who live in coastal communities These programs also lead to increases in economic wellbeing 85 Examples include the Coastal Embankment Improvement Project 86 by World Bank in 2013 the BlueGold project 87 in 2012 UNICEF s Managed Aquifer Recharge program in 2014 and the Bangladesh Delta Plan in 2014 85 Such investments in water security aim to increase the continued use and upkeep of water facilities They can help coastal communities to escape the poverty trap caused by water insecurity 85 A program called the SafePani framework focuses on how the state shares risks and responsibilities with service providers and communities 5 This program aims to help decision makers to address climate risks through a process called climate resilient water safety planning 5 The program is a cooperation between UNICEF and the Government of Bangladesh Ethiopia edit Further information Climate change in Ethiopia and Water supply and sanitation in Ethiopia nbsp Rainfall regimes vary across Ethiopia Left figure Annual average rainfall in mm day with the interquartile range 25th 75th of monthly rainfall in mm day indicated by black contours 1981 2020 88 Right figure Three rainfall zones in Ethiopia with different seasonal rainfall patterns The green zone has two separate rainy seasons and the red zone has a single peak in rainfall in Jun to September Ethiopia has two main wet seasons per year It rains in the spring and summer These seasonal patterns of rainfall vary a lot across the country 69 89 Western Ethiopia has a seasonal rainfall pattern that is similar to the Sahel It has rainfall from February to November which is decreasing to the north and has peak rainfall from June to September Southern Ethiopia has a rainfall pattern similar to the one in East Africa There are two distinct wet seasons every year February to May and October to November 72 89 Central and eastern Ethiopia has some rainfall between February and November with a smaller peak in rainfall from March to May and a second higher peak from June to September 89 In 2022 Ethiopia had one of the most severe La Nina induced droughts in the last forty years It came about due to four consecutive rainy seasons which did not produce enough rain 90 This drought increased water insecurity for more than 8 million pastoralists and agro pastoralists in the Somali Oromia SNNP and South West regions About 7 2 million people needed food aid and 4 4 million people needed help to access water Food prices have increased a lot due to the drought conditions Many people in the affected area have experienced food shortages due to the water insecurity situation 90 In the Awash basin in central Ethiopia floods and droughts are common Agriculture in the basin is mainly rainfed without irrigation systems This applies to around 98 of total cropland as of 2012 So changes in rainfall patterns due to climate change will reduce economic activities in the basin 91 Rainfall shocks have a direct impact on agriculture A rainfall decrease in the Awash basin could lead to a 5 decline in the basin s overall GDP The agricultural GDP could even drop by as much as 10 91 Partnerships with the Awash Basin Development Office AwBDO and the Ministry of Water Irrigation and Electricity MoWIE have led to the development of new models of water allocation in the Awash basin This can improve water security for the 18 3 million residents in the basin With this they will have enough water for their domestic irrigation and industry needs 5 Kenya edit Further information Water supply and sanitation in Kenya and Climate change in Kenya Kenya ranked 46th out of 54 African countries in an assessment of water security in 2022 92 Major water security issues in Kenya include drinking water safety water scarcity lack of water storage poor wastewater treatment and drought and flood 92 Large scale climate patterns influence the rainfall patterns in East Africa Such climate patterns include the El Nino Southern Oscillation ENSO and the Indian Ocean Dipole IOD Cooling in the Pacific Ocean during the La Nina phase of ENSO is linked with dryer conditions in Kenya This can lead to drought as it did in 2016 17 On the other hand a warmer Western Indian Ocean due to a strong positive Indian Ocean Dipole caused extreme flooding in Kenya in 2020 93 Around 38 of Kenya s population and 70 of its livestock live in arid and semi arid lands 94 These areas have low rainfall which varies a lot from one season to the next This means that surface water and groundwater resources vary a lot by location and time of year Residents in Northern Kenya are seeing increased changes in rainfall patterns and more frequent droughts 95 These changes affect livelihoods in this region where people have been living as migratory herders They are used to herding livestock with a seasonal migration pattern 95 More people are now settling in small urban centers and there is increasing conflict over water and other resources 96 Water insecurity is a feature of life for both settled and nomadic pastoralists Women and children bear the burden for fetching water 97 Groundwater sources have great potential to improve water supply in Kenya However the use of groundwater is limited by low quality and knowledge pumping too much groundwater known as overdrafting and salt water intrusion along coastal areas 98 99 Another challenge is the upkeep of groundwater infrastructure mainly in rural areas 100 See also editGlobal Water Security amp Sanitation Partnership Human right to water and sanitation Water footprint Water security in Australia Water security in the United StatesReferences edit a b c d e f g h i j k l Sadoff Claudia Grey David Borgomeo Edoardo 2020 Water Security Oxford Research Encyclopedia of Environmental Science doi 10 1093 acrefore 9780199389414 013 609 ISBN 978 0 19 938941 4 a b c d e f g h i j k l m n o p q r s t u Grey David Sadoff Claudia W 2007 12 01 Sink or Swim Water security for growth and development Water Policy 9 6 545 571 doi 10 2166 wp 2007 021 hdl 11059 14247 ISSN 1366 7017 a b c d e f g h i j k l m n o p q REACH 2020 REACH Global Strategy 2020 2024 University of Oxford Oxford UK REACH program a b c d e Hoekstra Arjen Y Buurman Joost van Ginkel Kees C H 2018 Urban water security A review Environmental Research Letters 13 5 053002 doi 10 1088 1748 9326 aaba52 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License a b c d e f g h i j k l m Murgatroyd A Charles K J Chautard A Dyer E Grasham C Hope R Hoque S F Korzenevica M Munday C Alvarez Sala J Dadson S Hall J W Kebede S Nileshwar A Olago D Salehin M Ward F Washington R Yeo D and Zeleke G 2021 Water Security for Climate Resilience Report A synthesis of research from the Oxford University REACH programme University of Oxford UK REACH nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License a b c d UNICEF 2021 Reimagining WASH Water Security for All a b c d e f Peter Gleick Charles Iceland and Ayushi Trivedi 2020 Ending Conflicts over Water Solutions to Water and Security Challenges World Resources Institute a b c d e f g h i j k l m Caretta M A A Mukherji M Arfanuzzaman R A Betts A Gelfan Y Hirabayashi T K Lissner J Liu E Lopez Gunn R Morgan S Mwanga and S Supratid 2022 Chapter 4 Water In Climate Change 2022 Impacts Adaptation and Vulnerability Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change H O Portner D C Roberts M Tignor E S Poloczanska K Mintenbeck A Alegria M Craig S Langsdorf S Loschke V Moller A Okem B Rama eds Cambridge University Press Cambridge UK and New York NY USA pp 551 712 doi 10 1017 9781009325844 006 a b Octavianti Thanti Staddon Chad May 2021 A review of 80 assessment tools measuring water security WIREs Water 8 3 doi 10 1002 wat2 1516 S2CID 233930546 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License a b c d IPCC 2022 Summary for Policymakers H O Portner D C Roberts E S Poloczanska K Mintenbeck M Tignor A Alegria M Craig S Langsdorf S Loschke V Moller A Okem eds In Climate Change 2022 Impacts Adaptation and Vulnerability Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change H O Portner D C Roberts M Tignor E S Poloczanska K Mintenbeck A Alegria M Craig S Langsdorf S Loschke V Moller A Okem B Rama eds Cambridge University Press Cambridge UK and New York NY USA pp 3 33 doi 10 1017 9781009325844 001 a b c d e f g UN Water 2013 Water Security amp the Global Water Agenda A UN Water Analytical Brief ISBN 978 92 808 6038 2 United Nations University a b c WaterAid 2012 Water security framework WaterAid London What is Water Security Infographic UN Water n d Retrieved 2021 02 11 Global water security lessons learnt and long term implications Singapore World Water Council 2018 ISBN 978 981 10 7913 9 OCLC 1021856401 page needed World Water Council 2018 Water security for all Policy Recommendations a b Wetlands International 2017 WASH and Water Security Integration and the role of civil society Wetlands International The Netherlands Varady Robert G Albrecht Tamee R Staddon Chad Gerlak Andrea K Zuniga Teran Adriana A 2021 The Water Security Discourse and Its Main Actors Handbook of Water Resources Management Discourses Concepts and Examples pp 215 252 doi 10 1007 978 3 030 60147 8 8 ISBN 978 3 030 60145 4 S2CID 236726731 The CEO Water Mandate 2014 Driving Harmonization of Water Related Terminology Discussion Paper September 2014 Alliance for Water Stewardship Ceres CDP formerly the Carbon Disclosure Project The Nature Conservancy Pacific Institute Water Footprint Network World Resources Institute and WWF a b Bonnafous Luc Lall Upmanu Siegel Jason 2017 04 19 A water risk index for portfolio exposure to climatic extremes conceptualization and an application to the mining industry Hydrology and Earth System Sciences 21 4 2075 2106 Bibcode 2017HESS 21 2075B doi 10 5194 hess 21 2075 2017 a b The Water Crisis and Industries at Risk Morgan Stanley Retrieved 2020 04 06 Carr Acacia 3 December 2018 Water Risk Single Largest Risk Threatening People Planet and Profit GreenMoney Journal Retrieved 2020 04 06 Climate change is devastating the world s water supplies Why aren t we talking about it Climate amp Capital Media 2021 01 14 Retrieved 2021 01 15 New Water Risk Filter Scenarios will help companies and investors turn risk into resilience Grasham Catherine Fallon Charles Katrina Jane Abdi Tilahun Geneti 2022 Re orienting the Concept of Water Risk to Better Understand Inequities in Water Security Frontiers in Water 3 799515 doi 10 3389 frwa 2021 799515 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License In Africa War Over Water Looms As Ethiopia Nears Completion Of Nile River Dam NPR 27 February 2018 Tulloch James August 26 2009 Water Conflicts Fight or Flight Allianz Archived from the original on 2008 08 29 Retrieved 14 January 2010 Kameri Mbote Patricia January 2007 Water Conflict and Cooperation Lessons from the nile river Basin PDF Navigating Peace Woodrow Wilson International Center for Scholars 4 Archived from the original PDF on 2010 07 06 United Nations Potential Conflict to Cooperation Potential accessed November 21 2008 Peter Gleick 1993 Water and conflict International Security Vol 18 No 1 pp 79 112 Summer 1993 Heidelberg Institute for International Conflict Research Department of Political Science University of Heidelberg Conflict Barometer 2007 Crises Wars Coups d Etat Nagotiations Mediations Peace Settlements 16th annual conflict analysis 2007 Sutherland Ben March 18 2003 Water shortages foster terrorism BBC News Retrieved 14 January 2010 Vorosmarty C J McIntyre P B Gessner M O Dudgeon D Prusevich A Green P Glidden S Bunn S E Sullivan C A Liermann C Reidy Davies P M September 2010 Global threats to human water security and river biodiversity Nature 467 7315 555 561 Bibcode 2010Natur 467 555V doi 10 1038 nature09440 hdl 10983 13924 PMID 20882010 S2CID 4422681 Foster S Villholth Karen Scanlon B Xu Y 2021 07 01 Water security and groundwater International Association of Hydrogeologists hdl 10568 116815 Staddon Chad Scott Christopher 2021 Putting water security to work addressing global sustainable development challenges 1st ed London ISBN 9780367650193 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Funk Chris 4 October 2021 Scientists sound the alarm over drought in East Africa what must happen next The Conversation Retrieved 2022 07 07 Brown Casey Lall Upmanu 2006 Water and economic development The role of variability and a framework for resilience Natural Resources Forum 30 4 306 317 doi 10 1111 j 1477 8947 2006 00118 x Brown Casey Lall Upmanu 2006 Water and economic development The role of variability and a framework for resilience Natural Resources Forum 30 4 306 317 doi 10 1111 j 1477 8947 2006 00118 x Staddon Chad Brewis Alexandra 2024 04 01 Household Water Containers Mitigating risks for improved Modular Adaptive and Decentralized MAD water systems Water Security 21 100163 doi 10 1016 j wasec 2023 100163 ISSN 2468 3124 Flooding and Climate Change Everything You Need to Know www nrdc org 2019 04 10 Retrieved 2023 07 11 Petersen Perlman Jacob D Aguilar Barajas Ismael Megdal Sharon B 2022 08 01 Drought and groundwater management Interconnections challenges and policyresponses Current Opinion in Environmental Science amp Health 28 100364 Bibcode 2022COESH 2800364P doi 10 1016 j coesh 2022 100364 ISSN 2468 5844 Harvey Chelsea Glaciers May Melt Even Faster Than Expected Study Finds Scientific American Retrieved 2023 07 11 Boretti Alberto Rosa Lorenzo 2019 Reassessing the projections of the World Water Development Report npj Clean Water 2 1 1 6 doi 10 1038 s41545 019 0039 9 hdl 11380 1198301 ISSN 2059 7037 Kummu M Guillaume J H A de Moel H Eisner S Florke M Porkka M Siebert S Veldkamp T I E Ward P J 2016 The world s road to water scarcity shortage and stress in the 20th century and pathways towards sustainability Scientific Reports 6 1 38495 Bibcode 2016NatSR 638495K doi 10 1038 srep38495 ISSN 2045 2322 PMC 5146931 PMID 27934888 a b Caretta M A A Mukherji M Arfanuzzaman R A Betts A Gelfan Y Hirabayashi T K Lissner J Liu E Lopez Gunn R Morgan S Mwanga and S Supratid 2022 Chapter 4 Water In Climate Change 2022 Impacts Adaptation and Vulnerability Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change H O Portner D C Roberts M Tignor E S Poloczanska K Mintenbeck A Alegria M Craig S Langsdorf S Loschke V Moller A Okem B Rama eds Cambridge University Press Cambridge UK and New York NY USA pp 551 712 doi 10 1017 9781009325844 006 Rijsberman Frank R 2006 Water scarcity Fact or fiction Agricultural Water Management 80 1 3 5 22 Bibcode 2006AgWM 80 5R doi 10 1016 j agwat 2005 07 001 IWMI 2007 Water for Food Water for Life A Comprehensive Assessment of Water Management in Agriculture London Earthscan and Colombo International Water Management Institute Mekonnen Mesfin M Hoekstra Arjen Y 2016 Four billion people facing severe water scarcity Science Water Stress Advances 2 2 e1500323 Bibcode 2016SciA 2E0323M doi 10 1126 sciadv 1500323 ISSN 2375 2548 PMC 4758739 PMID 26933676 Liu Junguo Yang Hong Gosling Simon N Kummu Matti Florke Martina Pfister Stephan Hanasaki Naota Wada Yoshihide Zhang Xinxin Zheng Chunmiao Alcamo Joseph 2017 Water scarcity assessments in the past present and future Review on Water Scarcity Assessment Earth s Future 5 6 545 559 doi 10 1002 2016EF000518 PMC 6204262 PMID 30377623 Vorosmarty C J 2000 07 14 Global Water Resources Vulnerability from Climate Change and Population Growth Science 289 5477 284 288 Bibcode 2000Sci 289 284V doi 10 1126 science 289 5477 284 PMID 10894773 S2CID 37062764 Ercin A Ertug Hoekstra Arjen Y 2014 Water footprint scenarios for 2050 A global analysis Environment International 64 71 82 doi 10 1016 j envint 2013 11 019 PMID 24374780 Water Scarcity Threats WWF 2013 Archived from the original on 21 October 2013 Retrieved 20 October 2013 Von Sperling Marcos 2007 Wastewater Characteristics Treatment and Disposal IWA Publishing 6 doi 10 2166 9781780402086 ISBN 978 1 78040 208 6 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License Eckenfelder Jr WW 2000 Kirk Othmer Encyclopedia of Chemical Technology John Wiley amp Sons doi 10 1002 0471238961 1615121205031105 a01 ISBN 978 0 471 48494 3 Water Pollution Environmental Health Education Program Cambridge MA Harvard T H Chan School of Public Health July 23 2013 Archived from the original on September 18 2021 Retrieved September 18 2021 a b c d Charles Katrina J Howard Guy Villalobos Prats Elena Gruber Joshua Alam Sadekul Alamgir A S M Baidya Manish Flora Meerjady Sabrina Haque Farhana Hassan S M Quamrul Islam Saiful 2022 Infrastructure alone cannot ensure resilience to weather events in drinking water supplies Science of the Total Environment 813 151876 Bibcode 2022ScTEn 813o1876C doi 10 1016 j scitotenv 2021 151876 hdl 1983 92cc5791 168b 457a 93c7 458890f1bf26 PMID 34826465 Brookes Justin D Antenucci Jason Hipsey Matthew Burch Michael D Ashbolt Nicholas J Ferguson Christobel 2004 07 01 Fate and transport of pathogens in lakes and reservoirs Environment International 30 5 741 759 doi 10 1016 j envint 2003 11 006 PMID 15051248 Klove Bjorn Ala Aho Pertti Bertrand Guillaume Gurdak Jason J Kupfersberger Hans Kvaerner Jens Muotka Timo Mykra Heikki Preda Elena Rossi Pekka Uvo Cintia Bertacchi Velasco Elzie Pulido Velazquez Manuel 2014 Climate change impacts on groundwater and dependent ecosystems Journal of Hydrology Climatic change impact on water Overcoming data and science gaps 518 250 266 Bibcode 2014JHyd 518 250K doi 10 1016 j jhydrol 2013 06 037 hdl 10251 45180 ISSN 0022 1694 Chapra Steven C Camacho Luis A McBride Graham B January 2021 Impact of Global Warming on Dissolved Oxygen and BOD Assimilative Capacity of the World s Rivers Modeling Analysis Water 13 17 2408 doi 10 3390 w13172408 ISSN 2073 4441 Miner Kimberley R D Andrilli Juliana Mackelprang Rachel Edwards Arwyn Malaska Michael J Waldrop Mark P Miller Charles E 2021 Emergent biogeochemical risks from Arctic permafrost degradation Nature Climate Change 11 10 809 819 Bibcode 2021NatCC 11 809M doi 10 1038 s41558 021 01162 y ISSN 1758 678X S2CID 238234156 Milner Alexander M Khamis Kieran Battin Tom J Brittain John E Barrand Nicholas E Fureder Leopold Cauvy Fraunie Sophie Gislason Gisli Mar Jacobsen Dean Hannah David M Hodson Andrew J Hood Eran Lencioni Valeria olafsson Jon S Robinson Christopher T 2017 Glacier shrinkage driving global changes in downstream systems Proceedings of the National Academy of Sciences 114 37 9770 9778 Bibcode 2017PNAS 114 9770M doi 10 1073 pnas 1619807114 ISSN 0027 8424 PMC 5603989 PMID 28874558 Yapiyev Vadim Wade Andrew J Shahgedanova Maria Saidaliyeva Zarina Madibekov Azamat Severskiy Igor 2021 12 01 The hydrochemistry and water quality of glacierized catchments in Central Asia A review of the current status Journal of Hydrology Regional Studies 38 100960 doi 10 1016 j ejrh 2021 100960 S2CID 243980977 a b Wutich Amber Brewis Alexandra August 2014 Food Water and Scarcity Toward a Broader Anthropology of Resource Insecurity Current Anthropology 55 4 444 468 doi 10 1086 677311 hdl 2286 R I 25665 ISSN 0011 3204 S2CID 59446967 a b Water and Wastewater Systems Sector Homeland Security www dhs gov Retrieved 2017 05 07 Buono Regina M Lopez Gunn Elena McKay Jennifer Staddon Chad 2020 Regulating Water Security in Unconventional Oil and Gas 1st ed 2020 ed Cham ISBN 978 3 030 18342 4 OCLC 1129296222 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link page needed Guidelines for drinking water quality 4 ed World Health Organization 2022 p 45 ISBN 978 92 4 004506 4 Retrieved 1 April 2022 Andersson Lotta Wilk Julie Graham L Phil Wikner Jacob Mokwatlo Suzan Petja Brilliant 2020 06 01 Local early warning systems for drought Could they add value to nationally disseminated seasonal climate forecasts Weather and Climate Extremes 28 100241 Bibcode 2020WCE 2800241A doi 10 1016 j wace 2019 100241 S2CID 212854220 Portele Tanja C Lorenz Christof Dibrani Berhon Laux Patrick Bliefernicht Jan Kunstmann Harald 2021 05 19 Seasonal forecasts offer economic benefit for hydrological decision making in semi arid regions Scientific Reports 11 1 10581 Bibcode 2021NatSR 1110581P doi 10 1038 s41598 021 89564 y ISSN 2045 2322 PMC 8134578 PMID 34011949 Lledo Llorenc Cionni Irene Torralba Veronica Bretonniere Pierre Antoine Samso Margarida 2020 06 22 Seasonal prediction of Euro Atlantic teleconnections from multiple Environmental Research Letters 15 7 074009 Bibcode 2020ERL 15g4009L doi 10 1088 1748 9326 ab87d2 S2CID 216346466 a b c d Taye Meron Teferi Dyer Ellen Charles Katrina J Hirons Linda C 2021 Potential predictability of the Ethiopian summer rains Understanding local variations and their implications for water management decisions Science of the Total Environment 755 Pt 1 142604 Bibcode 2021ScTEn 755n2604T doi 10 1016 j scitotenv 2020 142604 PMID 33092844 S2CID 225052023 a b Dyer Ellen Washington Richard 2021 Kenyan Long Rains A Subseasonal Approach to Process Based Diagnostics Journal of Climate 34 9 3311 3326 Bibcode 2021JCli 34 3311D doi 10 1175 JCLI D 19 0914 1 S2CID 230528271 Pearson Charles July 2008 Short and medium term climate information for water management WMO Bulletin 57 3 173 Archived from the original on December 17 2023 via WMO a b Dyer Ellen Washington Richard Teferi Taye Meron May 2020 Evaluating the CMIP5 ensemble in Ethiopia Creating a reduced ensemble for rainfall and temperature in Northwest Ethiopia and the Awash basin International Journal of Climatology 40 6 2964 2985 Bibcode 2020IJCli 40 2964D doi 10 1002 joc 6377 S2CID 210622749 Dyer Ellen Hirons Linda Taye Meron Teferi 2022 July September rainfall in the Greater Horn of Africa the combined influence of the Mascarene and South Atlantic highs Climate Dynamics 59 11 12 3621 3641 Bibcode 2022ClDy 59 3621D doi 10 1007 s00382 022 06287 0 S2CID 248408369 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License WaterAid and BGS 2022 Groundwater The world s neglected defence against climate change MacDonald Alan M Lark R Murray Taylor Richard G Abiye Tamiru Fallas Helen C Favreau Guillaume Goni Ibrahim B Kebede Seifu Scanlon Bridget Sorensen James P R Tijani Moshood Upton Kirsty A West Charles 2021 Mapping groundwater recharge in Africa from ground observations and implications for water security Environmental Research Letters 16 3 034012 Bibcode 2021ERL 16c4012M doi 10 1088 1748 9326 abd661 ISSN 1748 9326 S2CID 233941479 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License Strategic Framework for WASH Climate Resilient Development Revised 2017 ed GWP and UNICEF 2014 ISBN 978 91 87823 08 4 UNICEF Guidance Note How UNICEF regional and country offices can shift to climate resilient WASH programming PDF UNICEF 2020 Charles Katrina J Howard Guy Villalobos Prats Elena Gruber Joshua Alam Sadekul Alamgir A S M Baidya Manish Flora Meerjady Sabrina Haque Farhana Hassan S M Quamrul Islam Saiful 2022 Infrastructure alone cannot ensure resilience to weather events in drinking water supplies Science of the Total Environment 813 151876 Bibcode 2022ScTEn 813o1876C doi 10 1016 j scitotenv 2021 151876 hdl 1983 92cc5791 168b 457a 93c7 458890f1bf26 PMID 34826465 a b c d e Grasham Catherine Fallon Calow Roger Casey Vincent Charles Katrina J de Wit Sara Dyer Ellen Fullwood Thomas Jess Hirons Mark Hope Robert Hoque Sonia Ferdous Jepson Wendy Korzenevica Marina Murphy Rebecca Plastow John Ross Ian 2021 Engaging with the politics of climate resilience towards clean water and sanitation for all npj Clean Water 4 1 42 Bibcode 2021npjCW 4 42G doi 10 1038 s41545 021 00133 2 ISSN 2059 7037 Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License a b c Murgatroyd A Charles KJ Chautard A Dyer E Grasham C Hope R et al 2021 Water Security for Climate Resilience Report A synthesis of research from the Oxford University REACH programme Report University of Oxford UK Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License a b Taye Meron Teferi Dyer Ellen 22 August 2019 Ethiopia s future is tied to water a vital yet threatened resource in a changing climate The Conversation Retrieved 4 August 2022 a b UNICEF and GWP 2022 Strategic Framework for WASH Climate Resilient Development 2022 Edition Prepared in cooperation with HR Wallingford in 2014 2017 and 2022 and with the Overseas Development Institute ODI in 2014 ISBN 978 91 87823 69 5 a b c Gain Animesh K Giupponi Carlo Wada Yoshihide 2016 Measuring global water security towards sustainable development goals Environmental Research Letters 11 12 124015 Bibcode 2016ERL 11l4015G doi 10 1088 1748 9326 11 12 124015 ISSN 1748 9326 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License a b Young Sera L Boateng Godfred O Jamaluddine Zeina Miller Joshua D Frongillo Edward A Neilands Torsten B Collins Shalean M Wutich Amber Jepson Wendy E Stoler Justin 2019 09 01 The Household Water InSecurity Experiences HWISE Scale development and validation of a household water insecurity measure for low income and middle income countries BMJ Global Health 4 5 e001750 doi 10 1136 bmjgh 2019 001750 PMC 6768340 PMID 31637027 a b c d e Borgomeo Edoardo Hall Jim W Salehin Mashfiqus 2018 Avoiding the water poverty trap insights from a conceptual human water dynamical model for coastal Bangladesh International Journal of Water Resources Development 34 6 900 922 doi 10 1080 07900627 2017 1331842 S2CID 28011229 Development Projects Coastal Embankment Improvement Project Phase I CEIP I P128276 World Bank Retrieved 2023 02 10 Blue Gold Program Bangladesh Mott MacDonald www mottmac com Retrieved 2023 02 10 CHIRPS Rainfall Estimates from Rain Gauge and Satellite Observations Climate Hazards Center UC Santa Barbara www chc ucsb edu Retrieved 2022 09 14 a b c Abebe Dawit 2010 Future climate of Ethiopia from PRECIS Regional Climate Model Experimental Design PDF Met Office UK Retrieved 21 August 2022 a b Ethiopia Drought Update No 4 June 2022 Ethiopia ReliefWeb reliefweb int 3 June 2022 Retrieved 2022 07 06 a b Borgomeo Edoardo Vadheim Bryan Woldeyes Firew B Alamirew Tena Tamru Seneshaw Charles Katrina J Kebede Seifu Walker Oliver 2018 The Distributional and Multi Sectoral Impacts of Rainfall Shocks Evidence From Computable General Equilibrium Modelling for the Awash Basin Ethiopia Ecological Economics 146 621 632 doi 10 1016 j ecolecon 2017 11 038 nbsp Text was copied from this source which is available under a Creative Commons Attribution 4 0 International License a b Oluwasanya G Perera D Qadir M Smakhtin V 2022 Water Security in Africa A Preliminary Assessment Issue 13 United Nations University Institute for Water Environment and Health Hamilton Canada Ferrer Nuria Folch Albert Lane Mike Olago Daniel Odida Julius Custodio Emilio 2019 04 15 Groundwater hydrodynamics of an Eastern Africa coastal aquifer including La Nina 2016 17 drought Science of the Total Environment 661 575 597 Bibcode 2019ScTEn 661 575F doi 10 1016 j scitotenv 2019 01 198 hdl 2117 134140 ISSN 0048 9697 PMID 30682610 S2CID 59274112 State Department for Arid and Semi Arid Lands Kenya State Department for Arid and Semi Arid Lands Kenya Retrieved 2023 01 25 a b Njoka J T Yanda P Maganga F Liwenga E Kateka A Henku A Mabhuye E Malik N and Bavo C 2016 Kenya country situation assessment PRISE working paper Center for Sustainable Dryland Ecosystems and Societies University of Nairobi https idl bnc idrc dspacedirect org bitstream handle 10625 58566 IDL 58566 pdf Reid Robin S Fernandez Gimenez Maria E Galvin Kathleen A 2014 10 17 Dynamics and Resilience of Rangelands and Pastoral Peoples Around the Globe Annual Review of Environment and Resources 39 1 217 242 doi 10 1146 annurev environ 020713 163329 ISSN 1543 5938 S2CID 154486594 Balfour Nancy Obando Joy Gohil Deepali 2020 01 01 Dimensions of water insecurity in pastoralist households in Kenya Waterlines 39 1 24 43 doi 10 3362 1756 3488 19 00016 ISSN 0262 8104 S2CID 216343833 Barasa M Crane E Upton K o Dochartaigh BE and Bellwood Howard I 2018 Africa Groundwater Atlas Hydrogeology of Kenya British Geological Survey Accessed 27 January 2023 https earthwise bgs ac uk index php Hydrogeology of Kenya Groundwater use Mumma Albert Lane Michael Kairu Edward Tuinhof Albert Hirji Rafik 2011 Kenya Groundwater Governance Case Study Water papers Washington DC World Bank License CC BY 3 0 IGO https openknowledge worldbank org handle 10986 17227 Foster Tim Hope Rob 2016 10 01 A multi decadal and social ecological systems analysis of community waterpoint payment behaviours in rural Kenya Journal of Rural Studies 47 85 96 doi 10 1016 j jrurstud 2016 07 026 ISSN 0743 0167 S2CID 156255059 External links editInternational Water Security Network Water Security an open source journal that started in 2017 Retrieved from https en wikipedia org w index php title Water security amp oldid 1204301545, wikipedia, wiki, book, books, library,

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