The project titled “The Water-Energy-Food Nexus: Global, Basin and Local Case Studies of Resource Use Efficiency under Growing Natural Resource Scarcity“ (2015-2018), which was supported by the Federal Ministry for Economic Cooperation and Development, Germany, and was undertaken as part of the CGIAR Research Program on Water, Land and Ecosystems. The project set out to develop research methodologies and insights globally as well as for the Eastern Nile Technical Regional Organization (ENTRO) of the Nile Basin Initiative (NBI) and Egypt, Ethiopia and Sudan to support efforts for enhanced water, energy and food security and environmental sustainability. The toolkit describes both qualitative and quantitative methods that have been used in the research project. It is not meant to be an exhaustive list of information and tools related to the analysis of the water, energy and food (WEF) nexus. The overall focus of the tools has been on economic analysis of the linkages across water, energy and food--to complement other studies and method developments that focus on biophysical linkages across the WEF nexus. The toolkit is aimed, primarily, at researchers interested in the analysis of the water, energy and food nexus. However, the studies summarized here also provide insights for practitioners implementing Nexus projects.

The project titled “The Water-Energy-Food Nexus: Global, Basin and Local Case Studies of Resource Use Efficiency under Growing Natural Resource Scarcity“ (2015-2018), which was supported by the Federal Ministry for Economic Cooperation and Development, Germany, and was undertaken as part of the CGIAR Research Program on Water, Land and Ecosystems. The project set out to develop research methodologies and insights globally as well as for the Eastern Nile Technical Regional Organization (ENTRO) of the Nile Basin Initiative (NBI) and Egypt, Ethiopia and Sudan to support efforts for enhanced water, energy and food security and environmental sustainability. The toolkit describes both qualitative and quantitative methods that have been used in the research project. It is not meant to be an exhaustive list of information and tools related to the analysis of the water, energy and food (WEF) nexus. The overall focus of the tools has been on economic analysis of the linkages across water, energy and food--to complement other studies and method developments that focus on biophysical linkages across the WEF nexus. The toolkit is aimed, primarily, at researchers interested in the analysis of the water, energy and food nexus. However, the studies summarized here also provide insights for practitioners implementing Nexus projects. | Non-PR | IFPRI1; CRP5; The Water Energy Food Nexus | EPTD; DSGD | CGIAR Research Program on Water, Land and Ecosystems (WLE)

Synthesis of contributions and policy dialogue at the International Conference on Policies for Water and Food Security in Dry Areas . Toward a framework for countries and development partners for long-term investment in water management for food security in the Middle East and North Africa region.

The Middle East and North Africa (MENA) region has the largest water deficit in the world. It also has the least food self-sufficiency. Increasing food imports and decreasing domestic food production can contribute to water savings and hence to increased water security. However, increased domestic food production is a better way to achieve food security, even if irrigation demands an increase in accordance with projected climate changes. Accordingly, the trade-off between food security and the savings of water and land through food trade is considered to be a significant factor for resource management, especially in the MENA region. Therefore, the aim of this study is to analyze the impact of food trade on food security and water-land savings in the MENA region. We concluded that the MENA region saved significant amounts of national water and land based on the import of four major crops, namely, barley, maize, rice, and wheat, within the period from 2000 to 2012, even if the food self-sufficiency is still at a low level. For example, Egypt imported 8.3&thinsp;million&thinsp;t&thinsp;yr<span classCombining double low lineinline-formula>ĝ'1</span> of wheat that led to 7.5&thinsp;billion&thinsp;m<span classCombining double low lineinline-formula>3</span> of irrigation water and 1.3&thinsp;million&thinsp;ha of land savings. In addition, we estimated the virtual water trade (VWT) that refers to the trade of water embedded in food products and analyzed the structure of VWT in the MENA region using degree and eigenvector centralities. The study revealed that the MENA region focused more on increasing the volume of virtual water imported during the period 2006-2012, yet little attention was paid to the expansion of connections with country exporters based on the VWT network analysis. © 2018 The Royal Society of Chemistry.

This paper combines Food and Agriculture Organization (FAO) Food Balance data with Water Footprint data to reveal how virtual water flows interact with food import tonnages to enhance or retard national decoupling based on food trade. Decoupling theorises breaking the links between economic and population growth and water demands for domestic food production. The detailed analysis applies a resource decoupling model in relation to the role and potential of food and virtual water trade in alleviating national and regional water limits in the Middle East and North Africa (MENA). The contrast between Egypt’s political denial of dependence, and Israel’s strategic adoption of food imports provides an example.

This paper combines Food and Agriculture Organization (FAO) Food Balance data with Water Footprint data to reveal how virtual water flows interact with food import tonnages to enhance or retard national decoupling based on food trade. Decoupling theorises breaking the links between economic and population growth and water demands for domestic food production. The detailed analysis applies a resource decoupling model in relation to the role and potential of food and virtual water trade in alleviating national and regional water limits in the Middle East and North Africa (MENA). The contrast between Egypt’s political denial of dependence, and Israel’s strategic adoption of food imports provides an example.

This paper introduces a modeling framework for the analysis of real and virtual water flows at national scale. The framework has two components: (1) a national water model that simulates agricultural, industrial and municipal water uses, and available water and land resources; and (2) an international virtual water trade model that captures national virtual water exports and imports related to trade in crops and animal products. This National Water, Food & Trade (NWFT) modeling framework is applied to Egypt, a water-poor country and the world's largest importer of wheat. Egypt's food and water gaps and the country's food (virtual water) imports are estimated over a baseline period (1986–2013) and projected up to 2050 based on four scenarios. Egypt's food and water gaps are growing rapidly as a result of steep population growth and limited water resources. The NWFT modeling framework shows the nexus of the population dynamics, water uses for different sectors, and their compounding effects on Egypt's food gap and water self-sufficiency. The sensitivity analysis reveals that for solving Egypt's water and food problem non-water-based solutions like educational, health, and awareness programs aimed at lowering population growth will be an essential addition to the traditional water resources development solution. Both the national and the global models project similar trends of Egypt's food gap. The NWFT modeling framework can be easily adapted to other nations and regions.

This article illustrates a method for applying the water-food-energy nexus approach to propose an optimal cropping pattern. The proposed cropping pattern maximizes economic water and energy productivity and minimizes water and energy use. Through this method a water-food-energy nexus index is applied. A case study from Egypt is applied to illustrate the method.