Water for Agriculture: Maintaining Food Security under Growing Scarcity

Rosegrant, Mark W.; Ringler, Claudia; Zhu, Tingju

doi:10.1146/annurev.environ.030308.090351

Cited by 511 publications

(293 citation statements)

References 64 publications

Supporting

Mentioning

284

Contrasting

Unclassified

Order By: Relevance

“…As clarified by , R&D investments lead to crop yield increases for the same amount of crop water demand per hectare, thus enhancing water productivity per ton. This is in line with findings that improved agronomic practices and yield increases are crucial for improving water productivity (Kijne et al, 2003;Molden et al, 2010;Rosegrant et al, 2009). Except R&D investments, increase in agricultural production can also be achieved via land expansion , reallocation of production into areas of higher productivity, or expansion of the irrigated area.…”

Section: The Magpie Modelsupporting

confidence: 84%

The impact of climate change mitigation on water demand for energy and food: An integrated analysis based on the Shared Socioeconomic Pathways

Mouratiadou

Biewald

Pehl

et al. 2016

Environmental Science & Policy

View full text Add to dashboard Cite

Section: The Magpie Modelsupporting

confidence: 84%

The impact of climate change mitigation on water demand for energy and food: An integrated analysis based on the Shared Socioeconomic Pathways

Mouratiadou

Biewald

Pehl

et al. 2016

Environmental Science & Policy

View full text Add to dashboard Cite

“…This conclusion has only been reinforced in the recent report of the 'Impacts, Adaptation and Vulnerabilities' working group in the 5 th Assessment Report of the IPCC (IPCC 2014). Second, climate change is taking place on top of an already significantly degraded resource base in which the availability of quality soils, water resources and other essential inputs into production processes is threatened (Rosegrant et al 2009). Third, the rapid pace of industrialization, market integration and consolidation in global food systems has greatly enhanced the connectivity and interdependence of lengthy food supply chains, and the relationships of food chains with other industries -such as that of energy -while typically concentrating key resources (technology, research and development, distribution channels, marketing) in fewer hands (Clapp 2011;Lang 2003).…”

Section: Introductionmentioning

confidence: 99%

Adapting a social-ecological resilience framework for food systems

2015

View full text Add to dashboard Cite

The purpose of applying social-ecological resilience thinking to food systems is twofold: First, to define those factors that help achieve a state in which food security for all and at all scales is possible. Second, to provide insights into how to maintain the system in this desirable regime. However, the resilience of food systems is distinct from the broader conceptualizations of resilience in social-ecological systems because of the fundamentally normative nature of food systems: humans need food to survive, and thus system stability is typically a primary policy objective for food system management. However, society also needs food systems that can intensify sustainably i.e., feed everybody equitably, provide livelihoods and avoid environmental degradation while responding flexibly to shocks and uncertainty. Today's failure in meeting food security objectives can be interpreted as the lack of current governance arrangements to consider the full and differential dimensions of food system functions -economic, ecological and social -at appropriate scales: in other words, the multifunctionality of food. We focus on functional and response diversity as two key attributes of resilient, multifunctional food systems; respectively, the number of different functional groups and the diversity of types of responses to disturbances within a functional group. Achieving food security will require functional redundancy and enhanced response diversity, creating multiple avenues to fulfill all food system objectives. We use the 2013-15 drought in California to unpack the potential differences between managing for a single function -economic profit -and multiple functions. Our analysis emphasizes how the evolution of the Californian food system has reduced functional and response diversity and created vulnerabilities. Managing for the resilience of food systems will require a shift in priorities from profit maximization to the management for all functions that create full food security at multiple scales.

show abstract

“…The irrigation and drainage and flood control infrastructure upstream in the farming area is a crucial conditioner of the impact of drought and flooding shocks. This kind of private and public infrastructure is present far more in Asia, particularly East and Southeast Asia and in some zones of South Asia, and far less in Africa (Rosegrant et al 2009). This discrepancy highlights the relative vulnerabilities by geography.…”

Section: Impacts On Food Supply Chains From Short-term Climate Changementioning

confidence: 99%

Climate Smart Food Supply Chains in Developing Countries in an Era of Rapid Dual Change in Agrifood Systems and the Climate

Reardon

Zilberman

2017

Climate Smart Agriculture

View full text Add to dashboard Cite

Food supply chains are essential to food security in developing regions where today the great majority of food consumed is purchased from rural-urban, rural-rural, and urban-rural supply chains. Disrupting those supply chains means disrupting food security. Yet short-term climate shocks and long-term climate change threaten to cause that disruption. This chapter does four things: (1) analyzes the types and determinants of vulnerabilities of food supply chains to climate shocks and change; (2) considers how those vulnerabilities are conditioned by urbanization, diet change, and rapid transformation of food systems; (3) discusses how supply chain actors, from farmers to processors and distributors and input suppliers, invest in mitigation of the risks of these shocks and reduction of their vulnerabilities; (4) discusses policy implications and lays out an agenda for research for climate smart food supply chains in developing regions.

show abstract

Water for Agriculture: Maintaining Food Security under Growing Scarcity

Cited by 511 publications

References 64 publications

The impact of climate change mitigation on water demand for energy and food: An integrated analysis based on the Shared Socioeconomic Pathways

The impact of climate change mitigation on water demand for energy and food: An integrated analysis based on the Shared Socioeconomic Pathways

Adapting a social-ecological resilience framework for food systems

Climate Smart Food Supply Chains in Developing Countries in an Era of Rapid Dual Change in Agrifood Systems and the Climate

Contact Info

Product

Resources

About