Location: Zimbabwe

For more information, contact CIMMYT’s Zimbabwe office.

Farmers going home for breakfast in Motoko district, Zimbabwe. (Photo: Peter Lowe/CIMMYT)

CIMMYT and IITA collaborate to increase adoption of conservation agriculture in southern Africa

Written by Rodrigo Ordóñez on September 21, 2020. Posted in Press releases.

The International Institute of Tropical Agriculture (IITA) and the International Maize and Wheat Improvement Center (CIMMYT) recently launched a project that aims to research the drivers and barriers to adoption of conservation agriculture in southern Africa, and to develop strategies for achieving adoption and impact at scale.

The project, Understanding and Enhancing Adoption of Conservation Agriculture in Smallholder Farming Systems of Southern Africa (ACASA), will apply social and scaling science to understand the biophysical, socioeconomic, institutional, and policy drivers and barriers to the adoption of conservation agriculture technologies and practices.

The ACASA project is supported by the Norwegian Agency for Development Cooperation (Norad) and will be implemented in Malawi, Zambia, and Zimbabwe in collaboration with partners and farmers in the region.

The project was officially launched online on September 16, 2020. Zambia’s Minister of Agriculture, Michael Katambo, noted that it is a timely intervention, as the livelihoods and food security of smallholder farmers in southern Africa are increasingly being threatened by climate change and variability, which have led to a steady decline in the production of food staples and an increase in the number of food and nutrition-insecure people.

“It is now clear that current productivity and production levels cannot be expected to meet our requirements for food and nutrition security,” Katambo said in a speech read on his behalf by Moses Mwale, Director of the Department of Agriculture. “Conservation agriculture has a proven potential to increase and stabilize crop yields, and to support sustainable and resilient production systems and rural livelihoods.”

Proven benefits

Conservation agriculture — a farming system that promotes minimum soil disturbance, permanent soil cover and diversification of plant species — can efficiently increase agricultural productivity while reducing land degradation and improving soil health for more productive, profitable, and sustainable farming.

Substantial on-farm evidence has been generated on the agronomic and economic benefits of conservation agriculture, first introduced in the 1970s in South Africa. Consequently, donors and governments have made a lot of investments to promote and scale conservation agriculture technologies and practices among smallholder farmers in the region. Despite all these efforts, however, the adoption rate among smallholder farmers remains low.

“We should not let the low adoption of conservation agriculture discourage us. Let us use this opportunity to reflect and identify the missing link and come up with more sustainable solutions to the problem,” said the IITA Director for Southern Africa, David Chikoye.

“Although adoption of improved practices by most resource-poor farmers is primarily determined by the potential immediate benefits on crop yields, profits, risk, and livelihoods, there are a number of biophysical, socioeconomic, institutional, and policy factors that promote or hinder adoption of conservation agriculture. The project, therefore, aims to identify the adoption drivers and barriers, and to develop pathways and strategies for inclusive scaling of conservation agriculture practices,” said Arega Alene, Agricultural Economist at IITA and leader of the ACASA project.

Christian Thierfelder, Principal Cropping Systems Agronomist at CIMMYT, highlighted some of the bottlenecks for conservation agriculture adoption, noting they were linked more to socioeconomic and cultural factors rather than biophysical. “Conservation agriculture is a viable and proven climate-smart farming system. Future research efforts should go towards understanding farmers’ decision-making and behavioral change, as well as profitability,” Thierfelder said.

Other key partners include the Food and Agriculture Organization of the United Nations (FAO), the African Conservation Tillage Network (ACT) and Centre for Coordination of Agricultural Research and Development for Southern Africa (CCARDESA).

The project launch was attended by policymakers, donors, members of national and regional conservation agriculture taskforces, national and international research institutions, universities, international development institutions, private seed companies, non-governmental organizations, and farmer organizations.

Interview opportunities:

Arega Alene, Agricultural Economist, IITA.

Christian Thierfelder, Principal Cropping Systems Agronomist, CIMMYT

For more information, or to arrange interviews, contact the media team:

Genevieve Renard, Director of Communications, CIMMYT. g.renard@cgiar.org

Katherine Lopez, Head of Communication, IITA. k.lopez@cgiar.org

About CIMMYT:

The International Maize and What Improvement Center (CIMMYT) is the global leader in publicly-funded maize and wheat research and related farming systems. Headquartered near Mexico City, CIMMYT works with hundreds of partners throughout the developing world to sustainably increase the productivity of maize and wheat cropping systems, thus improving global food security and reducing poverty. CIMMYT is a member of the CGIAR System and leads the CGIAR programs on Maize and Wheat and the Excellence in Breeding Platform. The Center receives support from national governments, foundations, development banks and other public and private agencies. For more information visit staging.cimmyt.org.

About IITA:

The International Institute of Tropical Agriculture (IITA) is a not-for-profit institution that generates agricultural innovations to meet Africa’s most pressing challenges of hunger, malnutrition, poverty, and natural resource degradation. Working with various partners across sub-Saharan Africa, we improve livelihoods, enhance food and nutrition security, increase employment, and preserve natural resource integrity. IITA is a member of CGIAR, a global agriculture research partnership for a food-secure future.

CIMMYT researcher Demewoz Negera at the Ambo Research Center in Ethiopia. (Photo: Peter Lowe/CIMMYT)

Collaborating to accelerate genetic gains in maize and wheat

Written by Marta Millere on September 11, 2020. Posted in Features.

Stakeholders in the Accelerating Genetic Gains in Maize and Wheat for Improved Livelihoods (AGG) project have pledged to strengthen efforts to deliver desirable stress tolerant, nutritious and high-yielding maize and wheat varieties to smallholder farmers in a much shorter time. The alliance, comprising funders, national agricultural research systems (NARS), private seed companies, non-governmental organizations, the International Maize and Wheat Improvement Center (CIMMYT) and, for the maize component the International Institute for Tropical Agriculture (IITA), made these assurances during virtual events held in July and August 2020, marking the inception of the 5-year AGG project.

The initiative seeks to fast-track the development of higher-yielding, climate resilient, demand-driven, gender-responsive and nutritious seed varieties for maize and wheat, two of the world’s most important staple crops. The project is funded by the Bill & Melinda Gates Foundation, the Foreign, Commonwealth & Development Office (FCDO), the U.S. Agency for International Development (USAID), and the Foundation for Food and Agriculture Research (FFAR).

Tackling current and emerging threats

Jeff Rosichan, scientific program director of the Foundation for Food and Agricultural Research (FFAR), acknowledged the significant and ambitious aim of the project in tackling the challenges facing maize and wheat currently and in the future. “We are seeing the emergence of new pests and pathogens and viral diseases like never before. A lot of the work of this project is going to help us to tackle such challenges and to be better prepared to tackle emerging threats,” he said.

AGG builds on gains made in previous initiatives including Drought Tolerant Maize for Africa (DTMA), Improved Maize for African Soils (IMAS), Water Efficient Maize for Africa (WEMA), Stress Tolerant Maize for Africa (STMA) and Delivering Genetic Gain in Wheat (DGGW), with support from partners in 17 target countries in sub-Saharan Africa (SSA) and South Asia.

Hailu Wordofa, agricultural technology specialist at the USAID Bureau for Resilience and Food Security, underscored his expectation for CIMMYT’s global breeding program to use optimal breeding approaches and develop strong collaborative relationships with NARS partners, “from the development of product profiles to breeding, field trials and line advancement.”

Similarly, Gary Atlin, senior program officer at the Bill & Melinda Gates Foundation lauded the move toward stronger partnerships and greater emphasis on the CIMMYT and IITA breeding programs. “The technical capacity of partners has increased through the years. It is prudent to ensure that national partnerships continue. It is always a challenging environment, this time multiplied by the COVID-19 crisis, but through this collaboration, there is a greater scope to strengthen such partnerships even more,” he said.

Anne Wangui, Maize Seed Health Technician, demonstrates how to test maize plants for maize dwarf mosaic virus (MDMV). (Photo: Joshua Masinde/CIMMYT)

Symbiotic partnerships with great impact

“From the NARS perspective, we are committed to doing our part as primary partners to deliver the right seed to the farmers,” said Godfrey Asea, director of the National Crops Resources Research Institute at the National Agriculture Research Organization (NARO), Uganda. “We see an opportunity to review and to use a lot of previous historical data, both in-country and regionally and to continue making improved decisions. We also reiterate our commitment and support to continuously make improvement plans in our breeding programs.”

Martin Kropff, director general of CIMMYT, recognized the tremendous impact arising from the longstanding cooperation between CIMMYT’s maize and wheat programs and national programs in countries where CIMMYT works. “A wheat study in Ethiopia showed that 90% of all the wheat grown in the country is CIMMYT-related, while an impact study for the maize program shows that 50% of the maize varieties in Africa are CIMMYT-derived. We are very proud of that – not for ourselves but for the people that we work for, the hundreds of millions of poor people and smallholder farmers who really rely on wheat and maize for their living and for their incomes,” he said.

Founder and Chief Executive Officer of East Africa-based Western Seed Company Saleem Esmail expressed optimism at the opportunities the project offers to improve livelihoods of beneficiaries. “I believe we can do this by sharing experiences and by leveraging on the impacts that this project is going to bring, from new technologies to new science approaches, particularly those that help save costs of seed production.”

He, however, observed that while the target of fast-tracking varietal turnover was great, it was a tough call, too, “because farmers are very risk averse and to change their habits requires a great deal of effort.”

On his part, director of Crop Research at the Oromia Agricultural Research Institute (OARI) in Ethiopia Tesfaye Letta revealed that from collaborative research work undertaken with CIMMYT, the institute has had access to better-quality varieties especially for wheat (bread and durum). These have helped millions of farmers to improve their productivity even as Ethiopia aims for wheat self-sufficiency by expanding wheat production under irrigation.

“We expect more support, from identifying wheat germplasm suitable for irrigation, developing disease resistant varieties and multiplying a sufficient quantity of early generation seed, to applying appropriate agronomic practices for yield improvement and organizing exposure field visits for farmers and experts,” he said.

Challenges and opportunities in a time of crisis

Alan Tollervey, head of agriculture research at Foreign, Commonwealth and Development Office (FCDO) and the UK representative to the CGIAR System Council, emphasized the need for continued investment in agricultural research to build a resilient food system that can cope with the demands and pressures of the coming decades. This way, organizations such as CIMMYT and its partners can adequately deliver products that are relevant not only to the immediate demands of poor farmers in developing countries – and the global demand for food generally – but also to address foreseen threats.

“We are at a time of intense pressure on budgets, and that is when projects are most successful, most relevant to the objectives of any organization, and most able to demonstrate a track record of delivery. CIMMYT has a long track history of being able to respond to rapidly emerging threats,” he said.

Felister Makini, the deputy director general for crops at the Kenya Agricultural Research Organization (KALRO) lauded the fact that AGG not only brings together maize and wheat breeding and optimization tools and technologies, but also considers gender and socioeconomic insights, “which will be crucial to our envisioned strategy to achieve socioeconomic change.”

Zambia Agriculture Research Organization (ZARI) maize breeder Mwansa Kabamba noted that the inclusion of extension workers will help to get buy-in from farmers especially as far as helping with adoption of the improved varieties is concerned.

In its lifecycle, the AGG project aims to reduce the breeding cycles for both maize and wheat from 5-7 years currently to 3-4 years. By 2024, at least 150,000 metric tons of certified maize seed is expected to be produced, adopted by 10 million households, planted on 6 million hectares and benefit 64 million people. It also seeks to serve over 30 million households engaged in wheat farming the target countries.

Cover photo: CIMMYT researcher Demewoz Negera at the Ambo Research Center in Ethiopia. (Photo: Peter Lowe/CIMMYT)

Farmers evaluate traits of wheat varieties, Ethiopia. (Photo: Jeske van de Gevel/Bioversity International)

Reaching women with improved maize and wheat

Written by Marcia MacNeil on September 8, 2020. Posted in Features.

By 2050, global demand for wheat is predicted to increase by 50 percent from today’s levels and demand for maize is expected to double. Meanwhile, these profoundly important and loved crops bear incredible risks from emerging pests and diseases, diminishing water resources, limited available land and unstable weather conditions – with climate change as a constant pressure exacerbating all these stresses.

Accelerating Genetic Gains in Maize and Wheat for Improved Livelihoods (AGG) is a new 5-year project led by the International Maize and Wheat Improvement Center (CIMMYT) that brings together partners in the global science community and in national agricultural research and extension systems to accelerate the development of higher-yielding varieties of maize and wheat.

Funded by the Bill & Melinda Gates Foundation, the UK Foreign, Commonwealth & Development Office, the U.S. Agency for International Development (USAID) and the Foundation for Food and Agriculture Research (FFAR), AGG fuses innovative methods to sustainably and inclusively improve breeding efficiency and precision to produce seed varieties that are climate-resilient, pest- and disease-resistant, highly nutritious, and targeted to farmers’ specific needs.

AGG seeks to respond to the intersection of the climate emergency and gender through gender-intentional product profiles for its improved seed varieties and gender-intentional seed delivery pathways.

AGG will take into account the needs and preferences of female farmers when developing the product profiles for improved varieties of wheat and maize. This will be informed by gender-disaggregated data collection on current varieties and preferred characteristics and traits, systematic on-farm testing in target regions, and training of scientists and technicians.

Farmer Agnes Sendeza harvests maize cobs in Malawi. (Photo: Peter Lowe/CIMMYT)

To encourage female farmers to take up climate-resilient improved seeds, AGG will seek to understand the pathways by which women receive information and improved seed and the external dynamics that affect this access and will use this information to create gender-intentional solutions for increasing varietal adoption and turnover.

“Until recently, investments in seed improvement work have not actively looked in this area,” said Olaf Erenstein, Director of CIMMYT’s Socioeconomics Program at a virtual inception meeting for the project in late August 2020. Now, “it has been built in as a primary objective of AGG to focus on […] strengthening gender-intentional seed delivery systems so that we ensure a faster varietal turnover and higher adoption levels in the respective target areas.”

In the first year of the initiative, the researchers will take a deep dive into the national- and state-level frameworks and policies that might enable or influence the delivery of these new varieties to both female and male farmers. They will analyze this delivery system by mapping the seed delivery paths and studying the diverse factors that impact seed demand. By understanding their respective roles, practices, and of course, the strengths and weaknesses of the system, the researchers can diagnose issues in the delivery chain and respond accordingly.

Once this important scoping step is complete, the team will design a research plan for the following years to understand and influence the seed information networks and seed acquisition. It will be critical in this step to identify some of the challenges and opportunities on a broad scale, while also accounting for the related intra-household decision-making dynamics that could affect access to and uptake of these improved seed varieties.

“It is a primary objective of AGG to ensure gender intentionality,” said Kevin Pixley, Director of CIMMYT’s Genetic Resources Program and AGG project leader. “Often women do not have access to not only inputs but also information, and in the AGG project we are seeking to help close those gaps.”

Cover photo: Farmers evaluate traits of wheat varieties, Ethiopia. (Photo: Jeske van de Gevel/Bioversity International)

Nancy Wawira (29) stands among ripening maize cobs of high yielding, drought-tolerant maize varieties on a demonstration farm in Embu County, Kenya. Involving young people like Wawira helps to accelerate the adoption of improved stress-tolerant maize varieties. (Photo: Joshua Masinde/CIMMYT)

The future of agriculture in sub-Saharan Africa

Written by Shiela Chikulo on August 17, 2020. Posted in Features.

The theme for International Youth Day 2020, Youth Engagement for Global Action, highlights the various ways in which the engagement of young people at local, national and global levels enriches national and multilateral institutions and processes.

Up to 60% of Africa’s youth face challenges such as limited employment opportunities, financial constraints to access land and adequate technical equipment. However, agriculture is increasingly providing options. Through it, young people are participating and leveraging on new technologies that can optimize farming systems and create employment.

This photo essay depicts youth in on-farm and off-farm activities across East and Southern Africa. These young men and women are innovators and adopters of improved technologies such as small scale mechanization, appropriate farming practices, employment opportunities and research innovations implemented by the International Maize and Wheat Improvement Center (CIMMYT).

In Embu County, Kenya, 25-year-old Jackline Wanja stands in a demonstration plot of high-yielding, drought-resilient and fast-maturing maize varieties. (Photo: Joshua Masinde/CIMMYT)

Beyene Chufamo (28) is a two-wheel tractor technology service provider based in Meki, Ethiopia. In 2016, with the support of CIMMYT, he started providing repair and maintenance services to service providers in different areas. (Photo: Ephrem Tadesse/CIMMYT)

Beyene Chufamo (center, in green t-shirt) provides technical training on operation, safety, repair and maintenance to machinery hire service providers in different CIMMYT operation sites. His participation in small mechanization supply chain enables service providers and farmers to effectively use their machinery and significantly reduce the downtime of their machinery. (Photo: Ephrem Tadesse/CIMMYT)

Nancy Wawira (29) stands among ripening maize cobs of high yielding, drought-tolerant maize varieties on a demonstration farm in Embu County, Kenya. Involving young people like Wawira helps to accelerate the adoption of improved stress-tolerant maize varieties. (Photo: Joshua Masinde/CIMMYT)

Rose Salimanja (34) from Nyanga District, Zimbabwe, operates a two-wheel tractor and trailer during a trailer operations training course. Under the Zimbabwe Building Resilience Fund (ZRBF), CIMMYT is implementing appropriate small-scale mechanized solutions and services for smallholder farmers and service providers. (Photo: Dorcas Matangi/CIMMYT)

Targeting youth in interventions such as the Farm Mechanization and Conservation Agriculture for Sustainable Intensification (FACASI) project provides pathways for training in appropriate mechanized solutions to support farmers in rural areas. The enterprising Mwanga Youth Group members Pinnot Karwizi (28), Shepherd Karwizi (26) and Masimba Mawire (32) provide grain shelling services to farmers in Makonde District, Zimbabwe. (Photo: Shiela Chikulo/CIMMYT)

Zvikomborero Karimudengu skillfully operates a two-wheel tractor and trailer during a training session in Nyanga South district, Zimbabwe. Small scale mechanization services are proving to be immensely useful during the COVID-19 pandemic as services can be provided while adhering to social distancing regulations and without requiring additional labour. (Photo: Dorcas Matangi/CIMMYT)

Drought tolerant maize route out of poverty for community-based seed producer, Kenya. (Photo: Anne Wangalachi/CIMMYT)

New project to ramp up genetic gains in maize for better livelihoods

Written by Alison Doody on July 28, 2020. Posted in News.

As plant pests and diseases continue to evolve, with stresses like drought and heat intensifying, a major priority for breeders and partners is developing better stress tolerant and higher yielding varieties faster and more cost effectively.

A new project, Accelerating Genetic Gains in Maize and Wheat for Improved Livelihoods (AGG), seeks to achieve these results by speeding up genetic gains in maize and wheat breeding to deliver improved, stress resilient, nutritious seed to smallholders in 13 countries in sub-Saharan Africa (SSA) and four in South Asia. The 5-year AGG project is funded by the Bill & Melinda Gates Foundation, the UK Department for International Development (DFID), the U.S. Agency for International Development (USAID), and the Foundation for Food and Agriculture Research (FFAR).

The maize component of the project brings together diverse partners, including the International Maize and Wheat Improvement Center (CIMMYT) and the International Institute of Tropical Agriculture (IITA) as co-implementers; national agricultural research systems (NARS); and small and medium-sized (SME) seed companies.

Ambitious targets

At the inception meeting of the maize component of AGG on July 10, 2020, project leaders, partners and funders lauded the ambitious targets that aim to bolster the resilience and better the livelihoods, food and nutritional security of millions of smallholder farmers in SSA. At least 150,000 metric tons of certified seed is expected to be produced, adopted by 10 million households, planted on 6 million hectares by 2024 and benefiting 64 million people.

“We are developing climate resilient, nutritious, efficient, productive maize varieties for the farming community in sub-Saharan Africa. We will continue to work closely with our partners to develop product profiles, which are centered on the varieties that are really needed,” said CIMMYT Interim Deputy Director for Research Kevin Pixley.

AGG draws a solid foundation from previous projects such as Drought Tolerant Maize for Africa (DTMA), Improved Maize for Africa Soils (IMAS), Water Efficient Maize for Africa (WEMA) and Stress Tolerant Maize for Africa (STMA). Several high-yielding maize varieties that tolerate and/or resist diseases such as maize lethal necrosis (MLN), gray leaf spot (GLS), northern corn leaf blight, maize streak virus (MSV), turcicum leaf blight (TLB) and are drought-tolerant (DT), were developed and released to farmers across SSA. Varieties with nutritional traits such as nitrogen use efficiency (NUE) and quality protein maize (QPM) were also developed in the preceding initiatives.

Drought Tolerant Maize for Africa (DTMA) project monitoring and evaluation takes place in Tanzania. (Photo: Florence Sipalla/CIMMYT)

A matter of “life or death”

“When farmers are confronted by aggressive farming challenges, they want products that address those challenges at the earliest opportunity. Waiting for years could mean the difference between life and death,” remarked David Chikoye, the director of Southern Africa Hub at IITA.

A key focus of AGG is to incorporate gender-intentionality – special attention to the needs of women farmers and consumers – from the traits bred into new varieties, through the communication and technology deployment strategies.

“AGG provides an excellent opportunity to reorient our maize breeding, seed scaling and delivery strategies for greater impact on the livelihoods of smallholder farmers, especially women and the disadvantaged communities that are not well reached so far,” said B.M. Prasanna, director of CIMMYT’s Global Maize Program and the CGIAR Research Program on Maize. “Our vision is to accelerate genetic gains to 1.5-2 percent annually across different breeding pipelines in the 13 participating countries in SSA and to reach over 10 million households with improved varieties.”

AGG will strengthen the capacity of partners to achieve and sustain accelerated variety replacement — or turnover — and increase genetic gains in farmers’ fields.

Old vs new

Many improved varieties have been released in the past decade. However, the turnover of old and obsolete varieties with new and improved ones is not happening as quickly as anticipated.

“We are producing good products and getting them out, but not at the speed that farmers need. How do we make it possible and profitable for seed companies to quickly introduce new hybrids?” posed Gary Atlin, program officer at the Bill & Melinda Gates Foundation. “We need to move towards a breeding and seed system where we know that we can develop a new product in 4 or 5 years and then get it to the farmers much more quickly. This is a complex problem.”

To enhance AGG’s ability to identify new products that perform well for farmers under their challenging circumstances, on-farm testing will be scaled up significantly.

Guest of honor, Ethiopia’s Minister of State for Agriculture Mandefro Nigussie, lauded CIMMYT’s support in improving the resilience and productivity of maize and wheat in the country. He observed that this has helped improve maize productivity in Ethiopia from around 2 tons/ha to about 4 tons/ha over the past two decades.

“We consider such a huge accomplishment as a combination of efforts in germplasm development and breeding efforts of CIMMYT and the Ethiopian national programs. That partnership will flourish further in this new project,” he said.

Accelerating Genetic Gains in Maize and Wheat (AGG)

Written by Rodrigo Ordóñez on July 24, 2020. Posted in Uncategorized.

Accelerating Genetic Gains in Maize and Wheat (AGG), a project led by the International Maize and Wheat Improvement Center (CIMMYT), brings together partners in the global science community and in national agricultural research and extension systems to accelerate the development of higher-yielding varieties of maize and wheat — two of the world’s most important staple crops.

Specifically focusing on supporting smallholder farmers in low- and middle-income countries, the project uses innovative methods that improve breeding efficiency and precision to produce varieties that are climate-resilient, pest- and disease-resistant, and highly nutritious, targeted to farmers’ specific needs.

The maize component of the project serves 13 target countries: Ethiopia, Kenya, Malawi, Mozambique, South Africa, Tanzania, Uganda, Zambia and Zimbabwe in eastern and southern Africa; and Benin, Ghana, Mali, and Nigeria in West Africa. The wheat component of the project serves six countries: Bangladesh, India, Nepal, and Pakistan in South Asia; and Ethiopia and Kenya in sub-Saharan Africa.

This project builds on the impact of the Delivering Genetic Gain in Wheat (DGGW) and Stress Tolerant Maize for Africa (STMA) projects.

Objectives

The project aims to accelerate the development and delivery of more productive, climate-resilient, gender-responsive, market-demanded, and nutritious maize and wheat varieties in support of sustainable agricultural transformation in sub-Saharan Africa and South Asia.

To encourage adoption of new varieties, the project works to improve equitable access, especially by women, to seed and information, as well as capacity building in breeding, disease surveillance, and seed marketing.

Funders

Project funding is provided by the Bill & Melinda Gates Foundation, the UK Foreign, Commonwealth & Development Office, the United States Agency for International Development and the Foundation for Food and Agricultural Research (FFAR).

Key partners

The primary partners for this project are the national agricultural research systems in the project target countries and, for the maize component, the International Institute for Tropical Agriculture (IITA) and small and medium enterprise (SME) seed companies.

Scientific and technical steering committees

We are grateful to our excellent maize and wheat scientific and technical steering committees for their suggestions and thoughtful question on key issues for the success of AGG. Read about the recommendations from the maize steering committee here and the wheat steering committee here.

Year 1 Executive Summary

In its first year of operation, AGG has made great strides in collaboration with our national partners towards the project goals –despite the unprecedented challenges of working through a global pandemic. For specific milestones achieved, we invite you to review our AGG Year 1 Executive Summary and Impact Report (PDF).

Year 2 Executive Summary

AGG has made progress towards all outcomes. Our scientists are implementing substantial modifications to breeding targets and schemes. AGG is also in a continuous improvement process for the partnership modalities, pursuing co-ownership and co-implementation that builds the capacities of all involved. For specific milestones achieved, we invite you to review our AGG Year 2 Executive Summary and Impact Report (PDF).

CIMMYT’s adult plant resistance breeding strategy

Download a summary of CIMMYT’s breeding strategy for adult plant resistance (PDF).

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Starwheel planter in Zimbabwe. (Photo: Jérôme Bossuet/CIMMYT)

Small is beautiful

Written by Alison Doody on July 9, 2020. Posted in Features.

Can Africa’s smallholder farmers adopt and reap the benefits of farm mechanization? The Farm Mechanization and Conservation Agriculture for Sustainable Intensification (FACASI) team set out in 2013 to test this proposition. With the project nearing closure, the International Maize and Wheat Improvement Center (CIMMYT) project leader Frédéric Baudron believes the answer is yes.

“We have demonstrated that small-scale mechanization is a pathway to sustainable intensification and rural transformation, and can have positive gender outcomes as well,” he explained.

Here are some of the key lessons learned along the way, according to the people involved.

1. Appropriate mechanization is essential

With many farms in Africa measuring no more than two hectares, FACASI focused on bringing two-wheel tractors to regions where smallholdings dominate, especially in Zimbabwe and Ethiopia. For most small farmers, conventional farm machinery is out of reach due to its size, costs, and the skills needed to operate it. The typical path to mechanization would be for farmers to consolidate their farms, which could lead to social and environmental upheaval. Instead, the FACASI team scaled-down the equipment to suit the local context.

FACASI has obtained evidence to dispel commonly held myths about farm power in smallholder farming systems,” said Eric Huttner, research program manager for crops at the Australian Centre for International Agricultural Research (ACIAR).

2. Test, develop and adapt technologies… together

From start to finish, the project tested and developed technologies in collaboration with farmers, local manufacturers, engineers, extension agents. Together, they adapted and refined small-scale machinery used in other parts of the world to accommodate the uneven fields and hard soils of African smallholder farms. This co-construction of technologies helped cultivate a stronger sense of local ownership and buy-in.

“We gained many valuable insights by continuously refining technologies in the context of efficiency, farmer preference and needs,” said Bisrat Getnet, FACASI national project coordinator in Ethiopia, and director of the Agricultural Engineering Research Department in the Ethiopian Institute of Agricultural Research (EIAR).

Jane Mautsa and her husband operating the sheller. (Photo: Shiela Chikulo/CIMMYT)

3. Make it useful

The basic two-wheel tractor is a highly flexible and adaptable technology, which can be used to mechanize a range of on-farm tasks throughout the seasons. With the right attachments, the tractor makes short work of sowing, weeding, harvesting, shelling, water pumping, threshing and transportation.

“This multi-functional feature helps to ensure the tractor is useful at all stages of the annual farming cycle, and helps make it profitable, offsetting costs,” said Raymond Nazare, FACASI national project coordinator in Zimbabwe and lecturer at the Soil and Engineering Department of the University of Zimbabwe.

4. Less pain, more profit

Reducing the unnecessary drudgery of smallholder farming can be financially rewarding and open new doors. Mechanization can save farmers the costs of hiring additional labor, and vastly reduce the time and effort of many post-harvest tasks — often done by women — such as transport, shelling and grinding. FACASI researchers demonstrated the potential for mechanization to reduce this onerous labor, allowing women to channel their time and energy into other activities.

5. New, inclusive rural business models

New technologies need reliable supply chains and affordable support services. The FACASI team supported leasing and equipment-sharing schemes, trained people to operate and maintain machinery, and encouraged individuals and groups to become service providers. These efforts often focused on giving youth and women new business opportunities.

“The project demonstrated that small mechanization can create profitable employment,” said Tirivangani Koza, of Zimbabwe’s Ministry of Lands, Agriculture, Water and Rural Resettlement.

“Women and youth are using small mechanization to grow profitable businesses,” said Alice Woodhead in Australia.

“They have advanced from dependent family members to financially independent entrepreneurs. Their new skills, such as servicing the tractors, marketing and shelling, have increased their family’s income. FACASI has also inspired community members to launch aligned businesses such as shelling services, inventing new two-wheel tractor implements for the growing customer base, or becoming artisan mechanics. In some districts, the two-wheel tractors are starting to create a cycle of innovation, business development, food diversification and sustainable economic growth,” she said.

6. Respond to farmer demands

Although the FACASI team set out to promote mechanization as a way to help farmers take up conservation agriculture techniques such as direct seeding, they opened the Pandora’s box for other beneficial uses. By the project’s end, it was clear that transport and mechanization of post-harvest tasks like shelling and threshing, had become far more popular among farmers than mechanization of crop production. This result is a sign of the team’s success in demonstrating the value of small-scale mechanization, and adapting technologies to respond to farmers’ needs.

7. Embrace new research models

Agricultural research for development has long forgotten about labour and mechanization issues; the FACASI team helped put these front and center by involving engineers, business enterprises, agriculturalists, and partners from across the supply chain.

“FACASI demonstrates an important change in how to do agricultural research to achieve meaningful impacts,” Woodhead said.

“Rather than focus only on the farm environment and on extension services, they worked from the outset with partners across the food, agriculture and manufacturing sectors, as well as with the public institutions that can sustain long-term change. The project’s results are exciting because they indicate that sustainable growth can be achieved by aligning conservation agriculture goals, institutions and a community’s business value propositions,” she explained.

What’s next?

Demonstration of a minitiller, Naivasha, Kenya. (Photo: Matt O' Leary/CIMMYT) — Demonstration of a minitiller, Naivasha, Kenya. (Photo: Matt O’ Leary/CIMMYT)

Although the project has ended, its insights and lessons will carry on.

“We have built a solid proof of concept. We know what piece of machinery works in a particular context, and have tested different delivery models to understand what works where,” explained Frédéric Baudron.

“We now need to move from piloting to scaling. This does not mean leaving all the work to development partners; research still has a big role to play in generating evidence and making sure this knowledge can be used by local manufacturers, engineers, local dealers and financial institutions,” he said.

As an international research organization, CIMMYT is strategically placed to provide critical answers to farming communities and the diversity of actors in the mechanization value chain.

A number of other organizations have taken up the mantle of change, supporting mechanization as part of their agricultural investments. This includes an initiative supported by the German Development Agency (GIZ) in Ethiopia, an IFAD-supported project to boost local wheat production in Rwanda and Zambia, and an intervention in Zimbabwe supported by the Zimbabwe Resilience Building Fund.

“ACIAR provided us generous and visionary support, at a time when very few resources were going to mechanization research in Africa,” Baudron acknowledged. “This allowed CIMMYT and its partners from the national research system and the private sector to develop unique expertise on scale-appropriate mechanization. The legacy of FACASI will be long-lived in the region,” he concluded.

Cover photo: Starwheel planter in Zimbabwe. (Photo: Jérôme Bossuet/CIMMYT)

Kiyasi Gwalale walking through her baby trial in Chebvute, Masvingo. Photo: C. Thierfelder/CIMMYT

When mothers learn from babies

Written by Alison Doody on July 8, 2020. Posted in Blogs.

It was an early morning on March 12, 2020, when we entered Kiyasi Gwalale’s field in the Chebvute area of Masvingo, southern Zimbabwe. Gwalale participates in the Zambuko Livelihoods Initiative, funded by the United States Agency for International Development (USAID).

The Zambuko initiative aims to increase rural resilience against the negative effects of climate change. More than 70% of smallholders in Zimbabwe farm on sandy soils that are low in soil fertility and are increasingly affected by the vagaries of climate. The Gwalale family is an example of one of the millions affected.

In Chebvute, the International Maize and Wheat Improvement Center (CIMMYT) has established trials to test the effectiveness and productivity of conservation agriculture and climate resilient crop species since 2018. This has been in the form of “mother and baby” trials.

A traditional tool of breeders, “mother trials” show different technologies to farmers to allow them to select the best option. In Chebvute, these trials were amplified to demonstrate farmers’ crop management practices such as conservation agriculture, crop rotation with legumes and different drought-resilient crop varieties.

A baby trial with DT maize, cowpea and white sorghum in Chebvute. Photo: C. Thierfelder/CIMMYT

Baby trial farmers taking after their ‘mothers’

Since 2019, the best options have been taken on by follower farmers in so called “baby trials”, where they use a subset from the mother trials to gain first-hand experience with the technology. Learning by doing is a central concept of this approach.

Gwalale as a “baby trial farmer” learned from the mother trials that drought-tolerant maize varieties out-yield traditional varieties under conservation agriculture, but need to be rotated with legumes to also improve the soil and the nutrition of the farm household. In addition, she realized that planting white sorghum is a drought-resilient strategy in this area as small grains are less affected by in-season dry-spells.

Gwalale and her family have been resident in Chebvute for 15 years but farm only on 0.4 ha of land. With her husband and three children, she grows maize, sorghum, groundnuts and Bambara nuts. What she gets from these fields is barely enough to survive.

In the 2019/20 cropping season, a devastating drought lasting from mid-December to mid-January destroyed all her hopes that this year would be a better season. Instead, she went on an educational journey to find out how improved farming practices can make a difference in her own life.

“We planted this baby trial for the first time in December 2019, as we had seen from the nearby mother trials that these varieties planted under no-tillage seem to grow better than our own. We planted the baby at the same times as our own crops, but instead of tilling the soil and clearing the land, which we are used to, we just planted in riplines without tillage and covered the soil with mulch,” explains Gwalale.

“When the drought came, all my other crops in the tilled fields started to wilt and die — some did not even germinate. We could not believe what was happening in this baby trial”.

CIMMYT scientist Christian Thierfielder pleased with the results in another baby trial plot in Chebvute. Photo: C. Thierfelder/CIMMYT

Resounding results in the baby trial

All crops in the baby trial survived the dry-spell and when the rains started to fall again in January, they continued to grow very well. Gwalale replanted the crops in the affected fields but they never caught up with the baby trial. Even after using the ripper to make more riplines, it was too late to experience the same wonder seen in the baby trial. “For now, we are yet to see how much we will get from this small field, but we learned a big lesson and want to expand our land area with this way of planting next year,” she says.

More than 200 baby trial farmers in Chebvute, the majority of which are women, have experienced the same in their own baby trials and realized that it does not take much effort to achieve food security.

Timely planting, conserving the soil and the moisture with conservation agriculture, effective weeding and application of adequate plant nutrients are the key ingredients of success. This can be learned effectively in a small plot such as a baby trial. Farmers have realized that it is possible to make a difference when they apply the principles of sustainable agriculture in their farming systems. The interventions introduced will help them to become more climate-resilient and ultimately more food secure.

Demonstration of a minitiller, Naivasha, Kenya. (Photo: CIMMYT)

African small-scale mechanization project winds down after strong results

Written by Mary Donovan on June 24, 2020. Posted in Features.

Smallholder farmers in Zimbabwe and Ethiopia have embraced small-scale mechanization thanks to an innovative CIMMYT-led project, which is now drawing to a close. Since 2013, the Farm Mechanization and Conservation Agriculture for Sustainable Intensification (FACASI) project has helped farmers access and use two-wheel tractors that significantly reduce the time and labor needed to grow, harvest and process their crops. To ensure long-term sustainability, the project and its partners helped support and develop local enterprises which could supply, service and operate the machines, and encouraged the development of supportive government policies. The project was funded by the Australian Centre for International Agricultural Research (ACIAR), as well as the CGIAR Research Programs on Maize and Wheat.

“Mechanization is a system not a technology”

From its inception, FACASI went beyond simply providing machinery to farmers, and instead envisioned mechanization as a way out of poverty. “Mechanization is a system, not only a technology,” said Bisrat Getnet, the project’s national coordinator in Ethiopia and director of the Agricultural Engineering Research Department at the Ethiopian Institute of Agricultural Research. “Mechanization needs infrastructure such as roads, fuel stations, spare part dealerships, maintenance centers, training centers and appropriate policies. This project assessed which measures are needed to sustain a new technology and addressed these with direct interventions,” he explained.

The FACASI project worked to introduce and develop new small-scale machines, including two-wheel tractors, small shellers and threshers, and small pumps, in African rural settings, collaborating with local engineers, farmers and manufacturers. This included adapting a range of attachments that could be used to mechanize on-farm tasks such as planting, harvesting, transporting and shelling. In parallel, the project developed local business opportunities around the supply, maintenance and use of the machines, to ensure that users could access affordable services and equipment in their communities.

The project initially worked in four countries: Ethiopia, Kenya, Tanzania and Zimbabwe. Researchers saw significant potential for mechanization to reduce the labor intensity associated with smallholder farming, while encouraging application of conservation agriculture techniques and developing rural service provision businesses. In its second phase, which began in 2017, the project focused on strengthening its efforts in Zimbabwe and Ethiopia.

“In my view the most innovative aspect enabling FACASI’s success was the concept of combining engineering and business modelling, with an understanding of the political, legislative and policy situations in the four countries,” said Professor John Blackwell, an Adjunct Professor at Charles Sturt University who reviewed FACASI and also invented and helped commercialize several successful machines in South Asia, including the famous Happy Seeder.

“FACASI has proven that small mechanization is viable in smallholder settings,” said CIMMYT scientist and project coordinator Frédéric Baudron. “It has shown smallholders that they don’t have to consolidate their farms to benefit from conventional machines, but that machines can instead be adapted to their farm conditions. This, to me, defines the concept of ‘appropriate mechanization’,” he said.

Conservation agriculture planter manufacturing in Arusha, Tanzania. (Photo: CIMMYT)

Benefits to local communities

During its course, the project improved the efficiency and productivity of smallholder farming, reducing labor requirements and creating new pathways for rural women and youth.

The reduction in the labor and drudgery of farming tasks has opened many doors. Farmers can save the costs of hiring additional labor and reinvest that money into their enterprises or households. With a small double-cob sheller producing one ton of kernels in an hour compared to up to 12 days by hand, women can do something else valuable with their time and energy. Entrepreneurs offering mechanization services — often young people who embrace new technologies — can earn a good income while boosting the productivity of local farms.

Mechanization has shown to sustainably improve yields. In Ethiopia, farmers using two-wheel tractors were able to reduce the time needed to establish a wheat crop from about 100 hours per hectare to fewer than 10 hours. In trials, maize and wheat respectively yielded 29% and 22% more on average, compared with using conventional crop establishment methods.

Local female artisan, Hawassa, Ethiopia. (Photo: CIMMYT)

Impacts now and into the future

According to its national partners, FACASI has laid the groundwork for cheap and practical two-wheel tractors to proliferate. In Ethiopia, there are currently 88 service providers whose skills has been directly developed through FACASI project interventions. “This has been a flagship project,” said Ethiopia national coordinator Bisrat Getnet. “It tested and validated the potential for small-scale mechanization and conservation agriculture, it proved that new business models could be profitable, and it opened new pathways for Ethiopian agriculture policy,” he said.

In Zimbabwe, the project has also set the wheels of change in motion. “FACASI demonstrated an opportunity for creating employment and business opportunities through small-scale mechanization,” said Tirivangani Koza, of Zimbabwe’s Ministry of Lands, Agriculture, Water and Rural Resettlement. “With the right funding and policies, there is a very wide and promising scope to scale-up this initiative,” he said.

Read more:
Explore the FACASI Hello Tractor knowledge platform to learn more about conservation agriculture and small-scale mechanization

Cover photo: Demonstration of a minitiller, Naivasha, Kenya. (Photo: CIMMYT)

Kiyasi Gwalale stands on her baby trial plot.

Conservation agriculture feeds people and protects the environment

Written by Shiela Chikulo on June 4, 2020. Posted in Features.

On June 5, 2020, the world celebrates World Environment Day as COVID-19 continues to cause challenges and restrictions. Existing threats of climate change with the new challenges of a global pandemic adversely affect the agricultural sector, a mainstay of most sub-Saharan African economies. This situation calls for increased attention to how agriculture is practiced and natural resources — such as soil and water — are cared for.

Smallholder farmers in Zimbabwe are custodians of these natural resources, yet climate variability of shifting rainfall seasons, El Niño and droughts threaten successful rain-fed farming. Coupled with conventional farming practices such as tillage and deforestation, the soil structure and chemical quality are gradually degrading. Each passing year has resulted in declining yields, food insecurity and increased household vulnerabilities, particularly in drought-prone, low rainfall areas of southern Zimbabwe.

With support from the Swiss Agency for Development and Cooperation (SDC), the R4 Rural Resilience Initiative, led by the World Food Programme (WFP), aims to enable vulnerable, smallholder farmers to increase their food security, income and resilience by managing climate-related risks. Building on R4, WFP has just launched the Zambuko Livelihoods Initiative, focusing on social cohesion of communities, improved crop and livestock production and improved access to finance, with support from the United States Agency for International Development (USAID). The International Maize and Wheat Improvement Center (CIMMYT) is a partner to implement the project component on appropriate seeds and agricultural practices.

We discuss the R4 Rural Resilience Initiative with Christian Thierfelder, the Principal Cropping Systems Agronomist and a Strategic Leader for Africa at CIMMYT, and Munaye Makonnen, the Project Lead from WFP in Zimbabwe.

Promising high yields of white sorghum on a field in the mother trials in Mwenezi, Zimbabwe.

How is the R4 Rural Resilience Initiative responding to climate change challenges in the sites of intervention – Chebvute and Mwenezi?

Thierfelder: The R4 and Zambuko initiatives pursue an integrated approach to increase resilience of smallholder farming communities. Different partner organizations have come together in these projects to pursue different interventions such as building dams and vegetable gardens as community assets, financial education, promotion of improved climate-smart technologies such as drought-tolerant seed in combination with conservation agriculture, insurance, and linking farmers to markets. The combined actions address all needs and shortfalls in the target communities. We see a transformational change from mere subsistence farming to a more commercially oriented farming by targeted smallholders.

Makonnen: Recognizing the need to address livelihoods holistically, R4 offers farmers a set of integrated tools so that communities can better manage climate risks. Farmers participate in activities that enhance the natural resource base at watershed level, helping them adapt to climate change. They also benefit from a weather index insurance cover that protects them against drought and incentivizes them to engage in high-risk high-return investments. In the case of minor shocks, farmers have their savings groups to draw up on and can access small credit for income generating activities. With the aim of increasing productivity and income, conservation agriculture practices are promoted. For their surplus production, participants are also supported in accessing markets. The project also plans to include a component on climate services that will allow communities to mitigate the impacts of disaster risk, increase production and enhance adaptation to climate change.

Since inception, how have the farming communities responded to the technologies and practices introduced in their respective sites?

Thierfelder: Farming communities were very skeptical initially about this new approach. However, the varieties and cropping systems displayed in our 10 mother trials showed dramatically higher yields than farmers observed in their own fields, so it was not difficult to get 200 baby trial farmers to experiment with the technology. During the 2019/2020 cropping season, farmers got even more excited to see maize and legume yields thrive in their baby trials while crops planted under conventional agriculture failed. In the next cropping season, we hope to reach the tipping point of farmers trying and experimenting with these climate-smart agriculture technologies to achieve a transformational change towards more resilience.

Makonnen: Looking at the performance of the trials, farmers can see for themselves that the agricultural practices promoted by the project result in higher yields. They also get practical experience by trying these out on their own fields. Such an approach has worked well in terms of getting farmers to become interested in and eventually adopt conservation agriculture principles because it is not just based on theory — farmers can actually see and experience the change for themselves.

Even in times of COVID-19, the work must continue, observing social distancing and using facemasks. Christian Thierfelder outlines trials with farmers in Mwenezi, Zimbabwe.

In the wake of the COVID-19 pandemic and disturbance to agri-food systems, how is the R4 Rural Resilience Initiative addressing the emerging challenges?

Thierfelder: We have created the base of more resilient farming systems that should positively respond to all external shocks – droughts, floods and maybe a virus as well. In our technology package we do promote self-pollinating legumes such as cowpea and groundnuts which can be grown even when farmers are cut off from supply chains for seed and fertilizer. We therefore hope that this can be a contribution to reducing the negative impact of the COVID-19 crisis.

Makonnen: As COVID-19 is compromising food security, it is now more important than ever to ensure that agricultural production continues to function smoothly. R4 continues to provide all the services in its integrated risk management package despite the pandemic. As farmers face challenges in production, including limited access to labor, we hope that high yielding and less labor-intensive conservation agriculture practices promoted by R4 really come into their own. Ensuring the safety of our beneficiaries, staff and partners is a priority for WFP so we have developed guidelines for R4 implementation in the context of COVID-19. For instance, trainings are taking place in smaller groups, social distancing is observed in all activities, messages on COVID-19 prevention are shared with beneficiaries and we are also looking into digital solutions to continue implementation during these unprecedented times.

Looking ahead, how will the adoption of appropriate agricultural practices and seed varieties strengthen the resilience of the farming communities?

Thierfelder: Our approach has been multi-faceted addressing different areas of concern to the farmers: income generation, credit, improved productivity, insurance and marketing. We believe that with this mix of interventions farming can more effectively withstand external stresses. However, we also realize that adoption does not happen overnight and requires a significant experimentation and learning process with farmers. WFP has seen the need for longer term investments, and this is now beginning to pay off.

Makonnen: Adoption of appropriate agricultural practices and seeds is just one of the components of R4. We know resilience requires a holistic approach which is why we have a set of interventions within R4 involving multiple partners. R4 will continue to work across the entire value chain bringing together natural resource management, access to financial services, access to inputs and markets and promotion of appropriate agricultural practices so that the farmers we work with are well equipped to manage risks and become resilient to the changing climate and risks to their food security.

Sign Phiri from CIMMYT inspects maize crops.

Cover photo: Kiyasi Gwalale stands on her baby trial plot.

Establishment of demo trial in Nyanga, Zimbabwe. (Photo: CIMMYT)

Farm mechanization under COVID-19

Written by Emma Orchardson on June 2, 2020. Posted in Features.

The COVID-19 pandemic continues to transform the way the world operates, and agricultural production systems are not exempt.

Even in countries that have identified the agricultural sector as an essential one, ongoing restrictions on transport and freedom of movement are causing disruptions across the value chain — with potentially devastating impact on already fragile food systems in Latin America, sub-Saharan Africa and South Asia.

With this in mind, systems agronomists and mechanization specialists at the International Maize and Wheat Improvement Center (CIMMYT), discuss the impact of restrictions on agricultural labor and production, and the role farm mechanization can play in addressing new challenges.

What are the implications of the agricultural labor shortages that are emerging in Africa and Latin America as a result of COVID-19 restrictions?

A woman demonstrates the use of a mini-tiller in Naivasha, Kenya. (Photo: Matt O’Leary/CIMMYT)

Frédéric Baudron: The pandemic has demonstrated that food production systems around the world — even in countries where agriculture is thought to be highly mechanized — are highly dependent on farm labor.

Africa is often presented as being dominated by farms which rely mainly on the labor of family members. Therefore, one could expect that Africa would be spared from the consequences of unavailability and/or unaffordability of hired labor. However, a recent CIMMYT study shows that farming systems in Africa are far more dependent on hired labor than commonly thought, and that the quasi total dependence of smallholder farming on family labor is a myth. Depending on the farming system, a complete loss of hired labor could lead to a productivity decrease of up to 20% in Eastern and Southern Africa. Hired labor is also likely to be replaced by child labor.

Because most production on the continent is rainfed during a single season, most farmers only plant and harvest once per year, making the timing of each task critical. A delay in planting because of labor shortages — as will soon occur Ethiopia — could lead to dramatically reduced yields. A delay in harvesting — as is currently experienced in Zimbabwe — means a large fraction of the crop is likely to be spoilt in the field.

Jelle Van Loon: The situation is similar for Mexico and the general Central American corridor, although the main production cycle is only just starting. Proper land preparation and timely sowing are critical, not only in terms of food production and achieving proper yields, but also to ensure that farmers have a stable income at the end of the year. This is especially important now, as financial and food reserves are shrinking at a faster pace due to COVID-19 restrictions that heavily affect demand on informal markets.

An operator demonstrates the use of a reaper in Bangladesh. (Photo: CIMMYT)

Are you seeing a similar situation in South Asia?

Timothy Krupnik: Depending on the country, we’ve seen either abrupt interruptions in the movement of agricultural laborers — for example in India where millions of migrant laborers have not been able to travel home during lockdown — or an influx of people from urban areas who fled to their villages when lockdown began.

In the latter case, one might expect this to increase labor availability for farming, but we tended to observe the reverse. People remain largely frightened of coming out of their homes, so even in rural areas which saw an influx of people, labor availability has not necessarily increased. Where laborers are willing to work, our initial scan of the evidence indicates that daily wage labor costs have also increased considerably due to risks of infection spreading. In either situation, smallholder farmers who need to hire labor to assure crucial crop management activities like planting or harvesting are suffering. There are reports emerging also of increased child labor in the region as schools are closed and resource-poor farmers are allocating family members and children to work where they can’t afford to hire labor.

M.L. Jat: I would like to cite the specific example of intensive rice-wheat rotation in India’s breadbasket and the Green Revolution corridors in the western Indo-Gangetic plains, which provide the bulk of cereals to the national food basket. An ex-ante analysis on the consequences of the reverse migration of the agricultural workforce and social distancing due to COVID-19 revealed that a delay in the transplanting of rice seedlings by two weeks is likely, which will delay rice harvesting and consequently delay the planting of wheat. This will potentially lead to rice and wheat production losses of 10-25%, worth up to $1.5 billion.

In addition, the shorter turn around between harvesting rice and planting wheat may further increase the incidence of rice residue burning. This is a major problem which creates significant health issues and may exacerbate the threat of COVID-19 by increasing both infection rates and disease severity.

Krupnik: The situation has increased interest and policy to support use of scale-appropriate machinery for operations like harvesting. In Bangladesh, for example, there was a recent and very serious risk of losing much of the rice harvest as the monsoon has started early and flash flooding has been a concern. Without manual laborers to harvest the crop, CIMMYT-led projects like the Cereal Systems Initiative for South Asia – Mechanization and Extension Activity (CSISA-MEA) have played a key role in assisting the movement of combine harvesters and crop reapers to areas at risk of crop losses and helping to assure the rice crop is harvested on time.

An operator demonstrates the use of a starwheel planter in Zimbabwe. (Photo: Frederic Baudron/CIMMYT)

It sounds like these machines were instrumental in avoiding crop losses. Does this mean that mechanization has a key role to play in lessening the impact of these labor shortages?

Krupnik: During the COVID-19 crisis, scale-appropriate machinery has become even more important for mitigating labor shortages. We work to facilitate the availability of scale-appropriate machinery not only so that farmers can buy and use equipment, but also by encouraging those who own machineries to become entrepreneurial service providers who offer efficient and mechanized land preparation, planting, irrigation, harvesting and post-harvesting to other farmers on an affordable fee-for-service basis.

This is a win-win situation for farmers who can’t access or afford the escalating costs of labor. In the COVID-19 crisis, these arrangements assist in responding to the labor crunch in locations where resource-poor farmers are most in need, and also allow farmers to get crucial work done while maintaining and encouraging social distancing.

Baudron: Over the past seven years, CIMMYT and its partners have fine-tuned technologies and developed delivery models — based on rural service providers supported by private sector companies — to scale the use of small machines in East and Southern Africa. These are profitable for both farmers and service providers and reduce labor requirements tremendously.

In Zimbabwe, we found that labor requirements were 15 times lower when establishing a maize field with a direct seeder pulled by a two-wheel tractor, and 23 times lower using a similar technology for establishing wheat in Rwanda, compared to the conventional method based on labor and draft power. A ton of maize that would take 12 people a full day to shell manually, can be shelled in one hour using a small double-cob sheller that costs about $300.

Jat: Rapid policy decisions by sub-national and national governments on facilitating more mechanized operations in labor intensive rice-wheat production regions will address labor availability issues while contributing to productivity enhancement of succeeding wheat crop in rotation, as well as overall system sustainability. Our ex-ante analysis on the implications of labor shortages in rice-wheat rotation in the western Indo-Gangetic plains due to COVID-19 indicates that adoption of scale-appropriate farm mechanization has the potential to stabilize the food production as well as reducing the income losses and air pollution surges in northwest India.

Harvesting maize in Mexico. (Photo: CIMMYT)

The situation in the regions each of you have mentioned is unique, but are there any global trends that you’ve noticed? And if so, can other regions learn from these localized experiences?

Krupnik: A huge part of what we do as a research and training institute is facilitate exchanges of information across continents and countries. Different types and designs of machinery that can be used in similar circumstances can be shared, as can business models supporting service providers.

Importantly, part of the concept of ‘scale-appropriate mechanization’ is also learning when and where machinery makes sense — where labor is not scarce and rural communities are highly dependent on income from labor to sustain their communities, some forms of mechanization may not be appropriate. We work to understand these dynamics and target the right machines in the right time and right places.

Van Loon: In addition to reducing pressure on available labor and alleviating drudgery, modern farm equipment tailored to the needs of smallholders can also increase competitiveness, as it allows for higher precision and efficiency.

In this sense, scale-appropriate mechanization can stimulate rural transformation incentivizing short and efficient value chains while ensuring stable food provision — aspects that have become essential to navigating the present crisis.

Has the current pandemic brought up any new perspectives in terms of how you consider labor and mechanization?

Baudron: We often look at yield and area planted in staple crops to assess the food security situation of a country during a particular year. This pandemic has shown us that we need to pay more attention to labor productivity. In many countries, policy-makers and development agents fear that mechanization will displace labor, but the dependency of staple crops on labor is a threat to food security, as we currently see in Africa and South Asia.

If the production of fruit, vegetables, cash crops, and so on will continue to depend on manual labor, it is essential in my view for critical tasks in the production of staples to be mechanized — particularly planting and harvesting. This will ensure the resilience of national food systems in the case of a future disruption similar to the COVID-19 pandemic.

Cover photo: Establishment of demo trial in Nyanga, Zimbabwe. (Photo: CIMMYT/ZRBF)

Unlike white maize varieties, vitamin A maize is rich in beta-carotene, giving it a distinctive orange color. This biofortified variety provides consumers with up to 40% of their daily vitamin A needs. (Photo: HarvestPlus/Joslin Isaacson)

Biofortified Maize for Improved Human Nutrition

Written by Emma Orchardson on April 27, 2020. Posted in Uncategorized.

The Biofortified Maize for Improved Human Nutrition project conducts field research both at CIMMYT and with partners on breeding for increased pro-vitamin A and Zinc content in both Africa and Latin America. The project grant is renewed annually and has been in operation since 2004.

Key activities include supporting early and mid-late product development, evaluation and release in Mexico and target countries in southern Africa, food science and retention studies. Molecular breeding and biochemical analysis are key components for successful breeding, and the project also involves technical backstopping for partners in both regions.

Objectives

Conduct field research on breeding for increased pro-vitamin A for target countries in Africa
Conduct field research on breeding for increased Zinc for product evaluation and release
Conduct essential research to deploy analytical tools and marker assisted selection or genomic selection methods in micronutrient breeding work
Facilitate the dissemination, promotion and consumption of biofortified crops

New publication: Scaling agricultural mechanization services in smallholder farming systems

Written by Emma Orchardson on February 27, 2020. Posted in Publications.

A new study by researchers at the International Maize and Wheat Improvement Center (CIMMYT) assesses how three large projects have scaled service provision models for agricultural mechanization in Bangladesh, Mexico and Zimbabwe. In what is possibly the first cross-continental assessment of these issues to date, the study gauges the extent to which each initiative fits with the needs of its environment to enable sustained machinery use by farmers at a large scale, while acknowledging the influence of project design on outcomes.

Each of the projects has made considerable progress towards increasing the adoption of agricultural machinery in their target area. In Bangladesh and Mexico, mechanization service providers and machinery dealers have been able to strengthen their business cases because the projects use geospatial and market data to provide targeted information on client segmentation and appropriate cropping systems. In Zimbabwe, CIMMYT and partners have worked to strengthen the market for two-wheeled tractors by creating demand among smallholders, developing the capacity of existing vocational training centers, and spurring private sector demand.

However, despite these initial successes, it can often be difficult to gauge the sustained change and transformative nature of such interventions.

Applying a scaling perspective

To address this challenge, research teams held a series of workshops with project partners in each country, including regional government representatives, national and local private sector stakeholders, and direct project collaborators such as extension agents and site managers. Participants were asked to answer a series of targeted questions and prompts using the Scaling Scan, a user-friendly tool which facilitates timely, structured feedback from stakeholders on issues that matter in scaling. Responses given during this exercise allowed project designers to analyze, reflect on, and sharpen their scaling ambition and approach, focusing on ten scaling ‘ingredients’ that need to be considered to reach a desired outcome, such as knowledge and skills or public sector governance.

Local service provider uses a bed planter for crop production in Horinofolia, Bangladesh. (Photo: Ranak Martin)

“Although at first sight the case studies seem to successfully reach high numbers of end users, the assessment exposes issues around the sustainable and transformative nature of the project interventions,” says Lennart Woltering, a scaling advisor at CIMMYT.

The added value of this approach, explains Jelle Van Loon, lead author and CIMMYT mechanization specialist, is that lessons learned from project-focused interventions can be amplified to generate broader, actionable knowledge and implement thematic strategies worldwide. “This is especially important for CIMMYT as we do exactly that, but often face different constraints depending on the local context.”

The use of a scaling perspective on each of these projects exposed important lessons on minimizing project dependencies. For example, though each project has invested considerably in both capacity and business development training, in all three case studies the large-scale adoption of recommended service provision models has been limited by a lack of finance and insufficient collaboration among the value chain actors to strengthen and support mechanization service provider entrepreneurs.

“While provision of market and spatial information helps local businesses target their interventions, local stakeholders are still dependent on the projects in terms of transitioning from project to market finance, facilitating collaboration along the value chain, and provision of leadership and advocacy to address issues at governance level,” Woltering explains. This, Van Loon adds, demonstrates a need for the inclusion of properly planned exit strategies from projects, as well as a degree of flexibility during the project development phase.

In all three regions, the supply of appropriate mechanization services is struggling to meet demand and few solutions have been found to support the transition from project to market finance. Continued capacity development is required at all stages of the value chain to ensure the provision of high-quality services and it has been suggested that incentivizing potential clients to access mechanization services and linking service providers with machinery dealers and mechanics might produce more satisfying results than simply supporting equipment purchases.

Read the full study: Scaling agricultural mechanization services in smallholder farming systems: Case studies from sub-Saharan Africa, South Asia, and Latin America. 2020. Van Loon, J., Woltering, L., Krupnik, T.J., Baudron, F., Boa, M., Govaerts, B. In: Agricultural Systems v. 180.

See more recent publications by CIMMYT researchers:

An R Package for Bayesian analysis of multi-environment and multi-trait multi-environment data for genome-based prediction. Montesinos-Lopez, O.A., Montesinos-Lopez, A., Luna-Vazquez, F.J., Toledo, F.H., Perez-Rodriguez, P., Lillemo, M., Crossa, J. In: G3: genes – genomes – genetics v. 9, no. 5, p. 1355-1369.
New deep learning genomic-based prediction model for multiple traits with binary, ordinal, and continuous phenotypes. Montesinos-Lopez, O.A., Martin-Vallejo, J., Crossa, J., Gianola, D., Hernandez Suárez, C.M., Montesinos-Lopez, A., JULIANA P., Singh, R.P. In: G3: genes – genomes – genetics v. 9, no. 5, p. 1545-1556.
QTL mapping for micronutrients concentration and yield component traits in a hexaploid wheat mapping population. Jia Liu, Bihua Wu, Singh, R.P., Velu, G. In: Journal of Cereal Science v.88, p. 57-64.
Climate Smart Agriculture practices improve soil organic carbon pools, biological properties and crop productivity in cereal-based systems of North-West India. 2019. Jat, H.S., Datta, A., Choudhary, M., Sharma, P.C., Yadav, A.K., Choudhary, V., Gathala, M.K., Jat, M.L., McDonald, A. In: Catena v. 181: 104059.
A cost-benefit analysis of climate-smart agriculture options in Southern Africa: balancing gender and technology. 2019. Mutenje, M., Farnworth, C.R., Stirling, C., Thierfelder, C., Mupangwa, W., Nyagumbo, I. In: Ecological Economics v.163, p. 126-137.
Yield and labor relations of sustainable intensification options for smallholder farmers in sub-Saharan Africa. A meta-analysis. 2019. Dahlin, S., Rusinamhodzi, L. In: Agronomy for Sustainable Development v. 39, no. 3.
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Scaling out climate-smart agriculture in southern Africa

Written by Emma Orchardson on December 3, 2019. Posted in Infographics.

The United Nations Framework Convention on Climate Change estimates that temperatures in Africa are set to rise significantly in coming years, with devastating results for farmers. Some regions could experience two droughts every five years, and see drastic reductions in maize yields over the next three decades.

Research demonstrates that climate-smart agriculture (CSA) is good method of mitigating the effects of climate change, for both farmers and the planet. Associated practices, which increase soil moisture levels and soil biodiversity have been shown to decrease soil erosion by up to 64%. They also have the potential to increase maize yields by 136% and incomes in dry environments by more than twice as much.

However, adoption rates remain low in some of the countries which stand to benefit the most, such as Malawi, Zambia and Zimbabwe, where the adoption of complete conservation agriculture systems is currently at 2.5%.

A new series of infographics describes some of the farming constraints will have to be addressed in order to scale climate-smart agricultural practices successfully in the region, taking into account both benefits and challenges for farmers.

Download the infographics:

Can we scale out Climate-Smart Agriculture? An overview.

Feasibility study of Climate-Smart Agriculture for rural communities in southern Africa: the approach.

Identifying the two best-bet CSA options to test.

A perfect storm: climate change jeopardizes food security in Malawi, Zambia and Zimbabwe.

Benefits and challenges of climate-smart agriculture for farmers in southern Africa.

Gender-sensitive climate-smart agriculture in southern Africa.

There is a strong business case for scaling out CSA in Malawi, Zambia and Zimbabwe.

Zimbabwe: Farmer Combats ‘Hidden Hunger’. . . Grows Biofortified Crops

Written by Mary Donovan on November 26, 2019. Posted in In the media.

Since 2015, Harvest Plus, through the Livelihoods and Food Security Programme (LFSP), has collaborated with the International Maize and Wheat Improvement Centre (CIMMYT), Department of Research and Specialist Services (DR&SS), and more than 30 national and international partners, in breeding biofortified crop varieties of vitamin A orange maize.