Technology-oriented approach to quantitative assessment of water–energy–food nexus

Andrews-Speed, P., Bleischwitz, R., Boersma, T., Johnson, C., Kemp, G., & VanDeveer, S. D. (2012). The global resource nexus: The struggles for land, energy, food, water, and minerals. Washington DC: Transatlantic Academy.

Chang, Y., Li, G., Yao, Y., Zhang, L., & Yu, C. (2016). Quantifying the water–energy–food nexus: current status and trends. Energies,9, 1–17.

Chen, P. C., Alvarado, V., & Hsu, S. C. (2018). Water energy nexus in city and hinterlands: Multi-regional physical input–output analysis for Hong Kong and South China. Applied Energy,225, 986–997.

Chini, C. M., & Stillwell, A. S. (2018). The state of U.S. urban water: Data and the energy–water nexus. Water Resources Research,54, 1796–1811.

Daccache, A., Ciurana, J. S., Rodriguez Diaz, J. A., & Knox, J. W. (2014). Water and energy footprint of irrigated agriculture in the Mediterranean region. Environmental Research Letters,9, 1–12.

FAO. (1992). Crop water requirements. Food and Agriculture Organisation of the United Nations, irrigation and drainage paper No. 24, Rome.

FAO. (2012). GAEZ: Global Agro-Ecological Zones. Food and Agriculture Organization of the United Nations Web. https://www.fao.org/nr/gaez/publications/en/. Accessed 06 August 2018.

FAO. (2014). Walking the nexus talk: Assessing the water–energy–food nexus in the context of the sustainable energy for all initiative. Rome: Food and Agriculture Organisation of the United Nations.

Gleick, P. H. (1994). Water and energy. Annual Review of Energy and the Environment,19, 267–299.

Hoff, H. (2011). Understanding the Nexus. Background Paper for the Bonn 2011 Conference: The Water, Energy and Food Security Nexus. Stockholm Environment Institute (SEI), Stockholm.

International Energy Agency (IEA). (2012). Water for energy—Is energy becoming a thirstier resource?. Paris: IEA.

International Renewable Energy Agency (IRENA). (2018). Water use in India’s power generation: Impact of renewables and improved cooling technologies to 2030. United Arab Emirates: IRENA.

Karnib, A. (2018). Bridging science and policy in water–energy–food nexus: Using the Q-nexus model for informing policy making. Water Resources Management Journal. https://doi.org/10.1007/s11269-018-2059-5.

Karnib, A. (2017a). Quantitative assessment framework for water, energy and food nexus. Computational Water, Energy, and Environmental Engineering Journal, Scientific Research Publishing Inc, 6, 11–23.

Karnib, A. (2017b). Evaluation of technology change effects on quantitative assessment of water, energy and food nexus. Journal of Geoscience and Environment Protection, Scientific Research Publishing Inc, 5, 1–13.

Karnib, A. (2017c). Water–energy–food nexus: A coupled simulation and optimization framework. Journal of Geoscience and Environment Protection, Scientific Research Publishing Inc, 5, 84–98.

Karnib, A. (2017). Water, energy and food nexus: The Q-Nexus model. European Water,60, 89–97.

Mathioudakis, V., Gerbens-Leenes, P. W., Van der Meer, T. H., & Hoekstra, A. Y. (2017). The water footprint of second-generation bioenergy. Journal of Cleaner Production,148, 571–582.

Siddiqi, A., & Wescoat, J. L. (2013). Energy use in large-scale irrigated agriculture in the Punjab province of Pakistan. Water International,38, 571–586.

Siddiqi, A., & Anadon, L. D. (2011). The water–energy nexus in Middle East and North Africa. Energy Policy,39, 4529–4540.

UNESCO. (2014). The United Nations world water development report 2014—water and energy—facts and figures. Italy: UNESCO.

UNESCWA. (2015). The water, energy and food security nexus in the Arab Region, ESCWA Water Development Report 6. Lebanon: Beirut.

Waskom, R., Akhbari, M., Grigg, N. (2014). U.S. perspective on the water–energy–food Nexus. Colorado Water Institute, Completion Report No. 116, Colorado.