CGIAR is the only worldwide partnership addressing agricultural research for development, whose work contributes to the global effort to tackle poverty, hunger and major nutrition imbalances, and environmental degradation.
It is carried out by 15 Centers, that are members of the CGIAR Consortium, in close collaboration with hundreds of partners, including national and regional research institutes, civil society organizations, academia, development organizations and the private sector.
The 15 Research Centers generate and disseminate knowledge, technologies, and policies for agricultural development through the CGIAR Research Programs. The CGIAR Fund provides reliable and predictable multi-year funding to enable research planning over the long term, resource allocation based on agreed priorities, and the timely and predictable disbursement of funds. The multi-donor trust fund finances research carried out by the Centers through the CGIAR Research Programs.
We have almost 10,000 scientists and staff in 96 countries, unparalleled research infrastructure and dynamic networks across the globe. Our collections of genetic resources are the most comprehensive in the world.
What we do
We collaborate with research and development partners to solve development problems. To fulfill our mission we:
- Identify significant global development problems that science can help solve
- Collect and organize knowledge related to these development problems
- Develop research programs to fill the knowledge gaps to solve these development problems
- Catalyze and lead putting research into practice, and policies and institutions into place, to solve these development problems
- Lead monitoring and evaluation, share the lessons we learn and best practices we discover;
- Conserve, evaluate and share genetic diversity
- Strengthen skills and knowledge in agricultural research for development around the world
Making a difference
We act in the interests of the world’s poorest and most vulnerable. Our track record spans four decades of research.
Our research accounted for US$673 million or just over 10 percent of the US$5.1 billion spent on agricultural research for development in 2010. The economic benefits run to billions of dollars. In Asia, the overall benefits of CGIAR research are estimated at US$10.8 billion a year for rice, US$2.5 billion for wheat and US$0.8 billion for maize.
It has often been cited that one dollar invested in CGIAR research results in about nine dollars in increased productivity in developing countries.
Sweeping reforms for the 21st century
Political, financial, technological and environmental changes reverberating around the globe mean that there are many opportunities to rejuvenate the shaky global food system. Developments in agricultural and environmental science, progress in government policies, and advances in our understanding of gender dynamics and nutrition open new avenues for producing more food and for making entrenched hunger and poverty history.
The sweeping reforms that brought in the CGIAR Consortium in 2010 mean we are primed to take advantage of these opportunities. We are eagerly tackling the ever more complex challenges in agricultural development. We are convinced that the science we do can make even more of a difference. To fulfill our goals we aim to secure US$1 billion in annual investments to fund the current CGIAR Research Programs.
CGIAR has embraced a new approach that brings together its strengths around the world and spurs new thinking about agricultural research for development, including innovative ways to pursue scientific work and the funding it requires. CGIAR is bringing donors together for better results and enabling scientists to focus more on the research through which they develop and deliver big ideas for big impact. As a result, CGIAR is more efficient and effective, and better positioned than ever before to meet the development challenges of the 21st century.
We are no longer the ‘Consultative Group on International Agricultural Research’. In 2008 we underwent a major transformation, to reflect this and yet retain our roots we are now known simply as CGIAR.
Members:
Resources
Displaying 2521 - 2525 of 12598Water yam (Dioscorea alata L.) growth and tuber yield as affected by rotation and fertilization regimes across an environmental gradient in west Africa
Yam (Dioscorea spp.) is a staple food crop and a source of income for millions of people in West Africa. Traditionally, in West Africa, yams are grown without any external inputs, leading to low tuber yields. The rapid decrease of tuber yield observed after the first yam cropping season has been ascribed to nutrient depletion and/or to the accumulation of yam-specific pests and diseases. This has led farmers to grow yam on new surfaces under fallow each year.
Building resilient maize production systems with stress-adapted varieties : Farmers' priorities in western Kenya
Maize cropping systems in Kenya, as is true in many other places in Africa, face multiple biotic and abiotic stressors not least climatic ones. Guided by farmers' priorities, maize breeding programs can contribute to the needed resilience against these changes by developing and mainstreaming new generations of maize varieties adapted to these challenges. Using data from 1,400 farmers and applying a multi-criteria choice analysis, this study reports on smallholder farmers' relative valuation of stress tolerance traits.
Gender, caste, and heterogeneous farmer preferences for wheat varietal traits in rural India
germplasm for the benefit of farmers and consumers of the Global South during and after the Green Revolution. Understanding farmers’ heterogeneous preferences for varietal traits in different market segments and incorporating the prominent ones in crop breeding programs are expected to facilitate a faster diffusion of these new varieties. Albeit knowing little about farmers’ trait preferences in South Asia, public-sector breeding programs prioritize yield enhancement and risk reduction over other varietal traits.
Influence of simultaneous intercropping of maize-bean with input of inorganic or organic fertilizer on growth, development, and dry matter partitioning to yield components of two lines of common bean
Intercropping is a common practice among smallholder farmers cultivating common bean (Phaseolus vulgaris L.) and maize (Zea mays L.). It affects agronomic performance, dry matter partition- ing, and grain yield. Simultaneous intercropping of common bean with maize can influence growth, development, and dry matter partitioning of grain of common bean.