This paper considers whether there will be sufficient water available to grow enough food for a predicted global population of 9 billion in 2050, based on three population and GDP growth modelling scenarios. Under the a low population growth with high GDP growth scenario, global consumptive water demand is forecast to increase significantly to over 6,000 km3, which is approximately 3,000 km3 greater that consumptive use in the year 2000. Also of concern is that rising global temperatures are going to increase potential evaporation, and t us irrigation water demand, by up to 17%. Sustainable intensification of agriculture can provide solutions to this predicament. However, productivity growth i not fast enough and we face considerable risks in the next 20 to 30 years. Concerted action to combat food insecurity and water scarcity is required based on agricultural research and development, policy reform and greater water productivity, if the world is to feed its growing population.

Nanotechnology is research and development that involves measuring and manipulating matter at the atomic, molecular, and supramolecular levels at scales measured in approximately 1 to 100 nanometers (nm) in at least one dimension.”Materials at such small scales often exhibit different electrical, magnetic, optical, mechanical, and other physical properties from their bulk material counterparts, leading to the development of potentially revolutionary technologies in a variety of industries,including agriculture and food. By increasing productivity, reducing postharvest loss, improving product quality, increasing the competitiveness of agricultural producers, and improving market access, advances in nanotechnology may present new opportunities to improve the livelihoods of the poor. But nanotechnology may also create new risks.Investments in agriculture and food nanotechnologies carry increasing weight because their potential benefits range from improved food quality and safety to reduced agricultural inputs and improved processing and nutrition. While most investment is made primarily in developed countries, research advancements provide glimpses of potential applications in agricultural, food, and water safety that could have significant impacts on rural populations in developing countries.Despite their promise, agricultural and food nanotechnologies, especially those that could reduce poverty or increase food and nutrition security, will likely face many challenges in each step of development—from investment in research and development (R&D) to adoption and use—before being commercialized and used by the rural poor. Many of these obstacles appear in the development of any new technology, but there are also issues specific to nanotechnology: intellectual property rights (IPR), the management of safety and environmental risks in the presence of wide uncertainties, and possible market displacement effects induced by these technologies, among other concerns. This brief presents a review of the potential opportunities and challenges of using nanotech applications for agriculture, food, and water in developing countries. | PR | IFPRI1; GRP1 | EPTD; MTID

IFPRI1; GRP1 | Gruère Guillaume P., 'Agriculture, food, and water nanotechnologies for the poor Opportunities and constraints', , IFPRI, 2011

PR | IFPRI3; ISI; CRP5 | EPTD; MTID | CGIAR Research Program on Water, Land and Ecosystems (WLE)

The world economy is under pressure for greater, more efficient and more sustainable use of natural resources to meet complementary and competing objectives in the food, water and energy sectors. Interactions between these three sectors have become increasingly affected by the bioeconomy—a concept that encompasses economic growth driven by the development of renewable biological resources and biotechnologies to produce sustainable products, employment and income. This article explores how water and the bioeconomy are interlinked, including how the constraints from growing water scarcity—in part caused by development of the bioeconomy—may influence bioeconomic growth. The article describes the impact of biofuel production on water quantity and quality and examines the potential for improved water use through the development of crop biotechnology and improved crop management. Then alternative scenarios for water in the bioeconomy are assessed, and policy conclusions are presented.

The water-energy-food (WEF) Nexus encompasses complex and interdependent relations and its examination requires content-specific concepts and approaches. Managing, conserving and maximizing the potential of each component is a major global concern considering the many challenges to be faced in the 21st century. The aim of this study was to identify, in the literature, recommendations for public policy, research and development, and practices for the WEF Nexus, aimed at promoting sustainable development considering stochastic and risk elements. In this regard, this paper presents a literature review of the contribution scientific studies have made toward better understanding the importance of the WEF Nexus in the context of sustainable development. Research indicates that the WEF Nexus cannot be discussed as independent sectors, highlighting the need for integrated policies and inter-sectoral and international cooperation to promote sustainable development. Therefore, the effective management of the WEF Nexus requires science-based data using risk and stochastic elements to assist policy and decision-making. Thus, in a situation of rapid global changes, decision-making processes for this Nexus must be assisted by multidisciplinary, multi-stakeholder and cross-sectoral approaches, aimed at avoiding the unintended effects of a single sector approach (e.g., energy policies stimulating hydroelectricity production need to consider factors affecting conservation and food production). With regard to the effects of climate change on the WEF Nexus, risk and stochastic elements must be considered when developing a science-based model for the sustainable management of WEF resources.

Hydrothermal processing of microalgae is regarded as a promising technology to generate multitude of energy based and value-added products. The niche of hydrothermal technologies is still under infancy in terms of the technical discrepancies related to research and development. Thus, the present review critically surveyed the recent advancements linked to the influencing factors governing the algal hydrothermal processing in terms of the product yield and quality. The sustainability of hydrothermal technologies as a standalone method and in broader aspects of circular bio-based economy for energy and value-added platform chemicals are comprehensively discussed. Process optimization and strategic integration of technologies has been suggested to improve efficiency, with reduced energy usage and environmental impacts for addressing the energy-food-water supply chains. Within the wider economic transition and sustainability debate, the knowledge gaps identified and the research hotspots fostering future perspective solutions proposed herewith would facilitate its real-time implementation.

In this commentary we describe a new framework for environmental security, one that draws food, water, and energy security into a unified socio-ecological research program. While traditional uses of environmental security carry statist and militaristic undertones, we propose that this "new" environmental security provides a more comprehensive perspective for research and development. Individually, food, water, and energy security research have made great progress, and as we describe here, the three have converged upon a core set of constituent properties: availability, access, utility, and stability. Yet, tradeoffs and interactions between food, water, and energy systems, which we argue tend to be place-based and which we illustrate using some examples from Alaska, are infrequently researched and not well captured in most global frameworks for integrated assessment. We present this integrative framework for environmental security, and conclude with suggestions regarding broad research themes and priorities.

Central Asian water planning following international policy recommendations and 'blue prints' has caused more harm rather than benefiting local communities. International research has not been sufficient to contribute in practical terms to water and food security. This paper reflects potential factors that limit understanding the complexity of water management in Central Asia. Five factors are identified which prevent cross linking of research across international boundaries and within countries. These are: (1) language, (2) access, (3) wikipediarism, (4) smattering and (5) outdating. To change the situation two factors are still missing - a lost generation of local experts and an internal critical review.

Since the adoption of the open-door policy, the Chinese dietary pattern has changed greatly. Based on the dietary changes, this study analyzed the arable land and water footprints (WFs) for the food consumption of urban and rural residents in China. The results showed that the arable land demand and WFs for meat, vegetable oil, soybeans and liquor exceeded those for other foods, and the per capita arable land and WFs for food consumption of urban residents were higher than those of rural residents. The total arable land and WFs for the food consumption of residents increased by 16.9 million ha (from 91.1 to 108 million ha) and 214.5 billion m³ (from 457.9 to 672.4 billion m³), respectively, from 1983 to 2017. Specifically, the total arable land and WFs for the food consumption of urban residents increased by 45.9 million hm² (from 22.6 to 68.5 million hm²) and 318.3 billion m³ (from 113.2 to 431.5 billion m³), respectively. Additionally, those of rural residents decreased by 29.7 million hm² (from 69.2 to 39.5 million hm²) and 103.9 billion m³ (344.8 to 240.9 billion m³), respectively, mainly due to the migration of the rural population to cities and the reductions in per capita arable land and WFs due to increased crop yields. The arable land and blue WFs required for food consumption will reach 127.7 million hm² and 221.1 billion m³, respectively, in 2030. However, these values will be reduced by approximately 23% and 20%, respectively, to 98.9 million hm² and 177.8 billion m³ under a balanced dietary pattern. Measures such as improving the investment in agricultural research and development, advocating a balanced diet, and increasing the import of resource-intensive foods could alleviate the pressure on land and water resources.