The International Maize and Wheat Improvement Center (CIMMYT) has released a set of 12 new maize lines adapted to the tropical environments targeted by CIMMYT and partner institutions.
Read more: https://seedworld.com/cimmyt-releases-12-new-maize-lines/
The International Maize and Wheat Improvement Center (CIMMYT) is pleased to announce the release of a set of 12 new CIMMYT maize lines (CMLs). These lines were developed at various breeding locations of CIMMYT’s Global Maize program by a multi-disciplinary team of scientists in sub-Saharan Africa and Asia. The lines are adapted to the tropical maize production environments targeted by CIMMYT and partner institutions.
CIMMYT seeks to develop improved maize inbred lines in different product profiles, with superior performance and multiple stress tolerance to improve maize productivity for smallholder farmers. CMLs are released after intensive evaluation in hybrid combinations under various abiotic and biotic stresses, besides optimum conditions. Suitability as either seed or pollen parent is also thoroughly evaluated.
To increase the utilization of the CMLs in maize breeding programs of partner institutions, all the new CMLs have been tested for their heterotic behavior and have been assigned to specific heterotic groups of CIMMYT: A and B. As a new practice, the heterotic group assignment is included in the name of each CML, after the CML number — for example, CML604A or CML605B.
Release of a CML does not guarantee high combining ability or per se performance in all environments. Rather, it indicates that the line is promising or useful as a parent for pedigree breeding or as a potential parent of hybrid combinations for specific mega-environments. The description of the lines includes heterotic group classification, along with information on their specific strengths, and their combining ability with some of the widely used CMLs or CIMMYT lines.
More information:
Summary of the characteristics of the 12 new CMLs (PDF).
Pedigree and characterization data of all the CMLs released to date, including the latest set (CIMMYT Research Data repository).
Seed requests:
A limited quantity of seed of the CMLs can be obtained by sending a request to the CIMMYT Maize Germplasm Bank. CMLs are freely available to both public and private sector breeders worldwide under the Standard Material Transfer Agreement.
Contact:
For further details regarding the released CMLs, please contact B.M. Prasanna, Director of the Global Maize Program, CIMMYT, and the CGIAR Research Program on Maize.
This tribute to the life and work of Sanjaya Rajaram, one of Norman Borlaug’s most impactful collaborators, also flags CIMMYT’s contribution to improving livelihoods and fostering more productive sustainable maize and wheat farming in low- and middle-income countries.
An op-ed published in El Sol de México recognizes CIMMYT’s contribution to tackling food insecurity through improved nutrient-rich, high-yielding varieties and sustainable agronomic practices.
Read more: https://www.elsoldemexico.com.mx/analisis/cimmyt-alimentando-al-mundo-6672151.html
Last month, the CGIAR Excellence in Breeding (EiB) platform handed over digitization equipment to the Kenya Agricultural and Livestock Research Organization (KALRO) as part of ongoing efforts to modernize the public agency’s crop breeding programs. The handover of the equipment, valued at roughly $85,000, took place at KALRO headquarters in Nairobi on March 8, 2021, with representatives from the International Maize and Wheat Improvement Center (CIMMYT), EiB and KALRO in attendance.
KALRO received 23 units of equipment including seed counters, label printers, handheld data collectors, tablets and package printers. These will help the organization speed up and enhance the accuracy of various breeding processes, including seed preparation, data collection and data analysis. They will also support inventory management within KALRO’s maize, wheat, rice, sorghum, bean, soybean and potato breeding programs at six of its research centers in Kenya.
Dispensing with laborious systems
A lack of digitization equipment hampers the research efforts of many national agricultural research systems (NARS) across Africa. This adverse situation is compounded by unreliable institutional memory, which constrains NARS efforts to breed an assortment of crop varieties efficiently.
“Currently, KALRO uses very laborious systems including manual layouts and collection, followed by manual data entry into computers. This old age process is prone to data entry errors and delays in analysis, publication and reporting,” says KALRO Director General Eliud Kireger.
“With the equipment we are receiving, information and data can be recalled by a click of a button. The equipment will also significantly reduce research costs related to labor, thus freeing our scientists to focus on core research activities.”
The equipment will also support KALRO’s ongoing efforts to digitize its historical data, especially for the maize and wheat programs using the Breeding Management System (BMS). So far, 20 years of maize historical data has been uploaded onto the BMS platform for ease of access.
Prepped for emerging challenges
The CGIAR EiB platform was established in 2017 to help modernize public breeding programs in the CGIAR and NARS to increase their rates of genetic gain. In recent years, there has been an upsurge in challenges including climate change, population growth, rapid urbanization, changing dietary inclinations, transboundary movement of pests and diseases. These have exerted an enormous strain on food production systems and elicited the urgency to prioritize the adoption of new plant breeding techniques and technologies to address current and emerging threats. This calls for a holistic approach to tackle the issues including better agronomy and policy, according to EiB NARS Coordinator Biswanath Das.
“Modernizing our plant breeding programs to develop new, climate smart, market driven varieties will be at the heart of the solution,” says Das. “We must ensure that public plant breeding programs are not left behind because for many crops in Africa, there is limited private sector interest. Public breeding programs must shoulder the responsibility for ensuring the development and adoption of the next generation of crop varieties.”
Already, KALRO breeding programs, in collaboration with international CGIAR centers, have played a leading role in supporting farmers in sub–Saharan Africa to address many emerging plant threats such as wheat rust (UG99), maize lethal necrosis (MLN) and fall armyworm.
As part of its commitment to supporting NARS partners, EiB provided over 10 million Kenyan shillings ($92,000) worth of material and in-kind support to various KALRO breeding operations in 2020. This included genotyping support for maize and wheat, support to adopt the BMS digital data management system, technical support and training of KALRO breeders. Much of the digitization work is driven by EiB’s Operations and Phenoytyping module, led by Gustavo Teixeira. “We’ll continue to consider a whole range of devices and solutions,” says Teixeira. “It’s a part of our culture of continuous improvement, so breeding programs can focus on what really adds value to their clients.”
EiB will continue to support NARS across Africa and beyond to digitize their operations, and is working with partners to secure more equipment, training and resources. With this digitization project, EiB has targeted 24 breeding programs in 14 African countries. These include programs run by AfricaRice, CIMMYT, the International Institute of Tropical Agriculture (IITA) and the International Rice Research Institute (IRRI).
“We want to do more to support centers to improve their operations so they can achieve the most effective and cost efficient phenotypic processes — agronomic practices, seed processing and other areas,” explains Teixeira. “We aim to expand to more programs and partners.”
EiB and partners are supported by CGIAR Trust Fund Contributors and the Crops to End Hunger initiative, via the Bill and Melinda Gates Foundation, GIZ, BMZ, USAID, UK Aid, ACIAR and other partners.
The International Maize and Wheat Improvement Center (CIMMYT) and the John Innes Centre (JIC) have announced a strategic collaboration for joint research, knowledge sharing and communications, to further the global effort to develop the future of wheat.
Wheat, a cornerstone of the human diet that provides 20% of all calories and protein consumed worldwide, is threatened by climate change-related drought and heat, as well as increased frequency and spread of pest and disease outbreaks. The new collaboration, building on a history of successful joint research achievements, aims to harness state-of-the-art technology to find solutions for the world’s wheat farmers and consumers.
“I am pleased to formalize our longstanding partnership in wheat research with this agreement,” said CIMMYT Deputy Director General for Research Kevin Pixley. “Our combined scientific strengths will enhance our impacts on farmers and consumers, and ultimately contribute to global outcomes, such as the Sustainable Development Goal of Zero Hunger.”
Director of the John Innes Centre, Professor Dale Sanders commented, “Recognizing and formalizing this long-standing partnership will enable researchers from both institutes to focus on the future, where the sustainable development of resilient crops will benefit a great many people around the world.”
Thematic areas for collaboration
Scientists from CIMMYT and JIC will work jointly to apply cutting-edge approaches to wheat improvement, including:
Plans for future collaborations include establishing a new laboratory in Norwich, United Kingdom, as part of the Health Plants, Healthy People, Healthy Plant (HP3) initiative.
Bringing innovations to farmers
An important goal of the collaboration between CIMMYT and JIC is to expand the impact of the joint research breakthroughs through knowledge sharing and capacity development. Stakeholder-targeted communications will help expand the reach and impact of these activities.
“A key element of this collaboration will be deploying our innovations to geographically diverse regions and key CIMMYT partner countries that rely on smallholder wheat production for their food security and livelihoods,” said CIMMYT Global Wheat Program Director Alison Bentley.
Capacity development and training will include collaborative research projects, staff and student exchanges and co-supervision of graduate students, exchange of materials and data, joint capacity building programs, and shared connections to the private sector. For example, plans are underway for a wheat improvement summer school for breeders in sub-Saharan African countries and an internship program to work on the Mobile And Real-time PLant disease (MARPLE) portable rust testing project in Ethiopia.
INTERVIEW OPPORTUNITIES:
Alison Bentley – Director, Global Wheat Program, International Maize and Wheat Improvement Center (CIMMYT)
Dale Sanders – Director, John Innes Centre
OR MORE INFORMATION, OR TO ARRANGE INTERVIEWS, CONTACT THE MEDIA TEAM:
Marcia MacNeil, Head of Communications, CIMMYT. m.macneil@cgiar.org
Rodrigo Ordóñez, Communications Manager, CIMMYT. r.ordonez@cgiar.org
ABOUT CIMMYT:
The International Maize and Wheat 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 Research 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 THE JOHN INNES CENTRE:
The John Innes Centre is an independent, international centre of excellence in plant science, genetics and microbiology. Our mission is to generate knowledge of plants and microbes through innovative research, to train scientists for the future, to apply our knowledge of nature’s diversity to benefit agriculture, the environment, human health, and wellbeing, and engage with policy makers and the public.
We foster a creative, curiosity-driven approach to fundamental questions in bio-science, with a view to translating that into societal benefits. Over the last 100 years, we have achieved a range of fundamental breakthroughs, resulting in major societal impacts. Our new vision Healthy Plants, Healthy People, Healthy Planet (www.hp3) is a collaborative call to action. Bringing knowledge, skills and innovation together to create a world where we can sustainably feed a growing population, mitigate the effects of climate change and use our understanding of plants and microbes to develop foods and discover compounds to improve public health.
The John Innes Centre is strategically funded by the UKRI-BBSRC (Biotechnology and Biological Sciences Research Council), and is supported by the John Innes Foundation through provision of research accommodation, capital funding and long-term support of the Rotation PhD programme.
For more information about the John Innes Centre visit our website: www.jic.ac.uk.
During the presentation of Mexico’s 2021 Agri-Food Expectations, Bram Govaerts, Director General of CIMMYT, flagged a number of initiatives aimed at supporting the country’s food self-sufficiency and safeguarding the cultural heritage of its agricultural sector.
Matthew Reynolds, Distinguished Scientist and Head of Wheat Physiology at CIMMYT, talked to The Guardian producer Patrick Greenfield about the process to create climate- and heat-resistant crops.
The International Maize and Wheat Improvement Center (CIMMYT) announced a new three-year public–private partnership with the German development agency GIZ and the beverage company Grupo Modelo (AB InBev) to recharge aquifers and encourage water-conserving farming practices in key Mexican states.
The partnership, launched today, aims to contribute to a more sustainable use of water in agriculture. The project will promote sustainable farming and financing for efficient irrigation systems in the states of Hidalgo and Zacatecas, where Grupo Modelo operates. CIMMYT’s goal is to facilitate the adoption of sustainable intensification practices on more than 4,000 hectares over the next three years, to reduce the water footprint of participant farmers.
Mexico is at a high risk of facing a water crisis in the next few years, according to the World Resources Institute. The country needs to urgently begin reducing its use of available surface and ground water supplies if it is to avert the looming crisis.
Farming accounts for nearly 76% of Mexico’s annual water consumption, as estimated by Mexico’s Water Commission (CONAGUA). Farmers, therefore, have a key role to play in a more sustainable use of this valuable natural resource.
“We need to take care of the ecosystem and mitigate agriculture’s impact on the environment to address climate change by achieving more sustainable agri-food systems,” said Bram Govaerts, chief operating officer, deputy director general of research a.i. and director of the Integrated Development program at CIMMYT.
The project, called Aguas Firmes (Spanish for “Firm Waters”), also seeks to recharge two of Mexico’s most exploited aquifers, by restoring forests and building green infrastructure.
“Our priority is water, which is the basis of our business but, above all, the substance of life,” said Cassiano De Stefano, chair of Grupo Modelo, one of the Mexico’s leading beer companies. “We’ve decided to lead by example by investing considerably in restoring two aquifers that are essential to Zacatecas and Hidalgo’s development.”
The German development agency GIZ, one of CIMMYT’s top funders, is also investing in this alliance that will benefit 46,000 farmers in Hidalgo and 700,000 farmers in Zacatecas.
“We are very proud of this alliance for sustainable development that addresses a substantial problem in the region and strengthens our work on biodiversity conservation and sustainable use of natural resources in Mexico,” said Paulina Campos, Biodiversity director at GIZ Mexico.
CIMMYT undertakes participatory agricultural research activities with local farmers to collaboratively develop and implement sustainable farming practices and technologies that help reduce water consumption in grain production by up to 30%.
INTERVIEW OPPORTUNITIES:
Bram Govaerts – Chief Operating Officer, Deputy Director General of Research a.i. and Director of the Integrated Development program, CIMMYT
FOR MORE INFORMATION, OR TO ARRANGE INTERVIEWS, CONTACT:
Ricardo Curiel, Senior Communications Specialist for Mexico, CIMMYT. r.curiel@cgiar.org, +52 (55) 5804 2004 ext. 1144
ABOUT CIMMYT:
The International Maize and Wheat 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 Research 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.
Scientists at CIMMYT expect to sharply ramp up new wheat varieties enriched with zinc that can boost the essential mineral for millions of poor people with deficient diets, the institute’s head told Reuters.
It’s often joked that specialists learn more and more about less and less until they know everything about nothing, while for generalists it’s just the opposite.
In the case of Natalia Palacios, neither applies. She may have the word specialist in her title — she is a maize quality specialist at the International Maize and Wheat Improvement Center (CIMMYT) — but throughout her career she has had to learn more and more about a growing range of topics.
As leader of the Nutrition Chapter of the Integrated Development Program and head of the Maize Quality Laboratory, Palacios’ job is to coordinate CIMMYT’s efforts to ensure that maize-based agri-food systems in low- and middle-income countries are as healthy and nutritious as possible. The scope of this work spans the breadth of maize-based agri-food systems — from seed to supper.
“What ultimately matters for human health and nutrition is the nutritional quality of the final product,” says Palacios. “High quality, nutritious grain is an important part of the puzzle, but so are the nutritional effects of various post-harvest storage, processing, and cooking techniques.”
Seeing the forest and the trees
Originally from Bogota, Colombia, Palacios studied microbiology at the Universidad de los Andes before pursuing a PhD in plant biology at the University of East Anglia and the John Innes Centre in the United Kingdom.
“I had the opportunity to work as research assistant at the International Center for Tropical Agriculture (CIAT) in Cali, Colombia,” she explains. “The exposure to interdisciplinary and international teams working for agricultural development and the leadership of my boss at that time, Joe Tohme, not only helped convince me to pursue post graduate studies in plant biology, they fostered an excitement around the real-world applications of scientific research.”
When she joined CIMMYT in 2005, Palacios worked on maize biofortification, supporting efforts to breed maize varieties rich in provitamin A and zinc. With time, she found her attention shifting towards the effect of food processing on the nutritional quality of maize-based food products, as well as to the importance of maize safety. For example, for a recent project, Palacios and her team have been analyzing the effect of a traditional thermal alkaline maize treatment known as nixtamalization on the physical composition of the grain and the nutritional quality of end products. Because of its important benefits, they are promoting this ancient technique in other geographies.
For Palacios, shifts such at this are completely in keeping with the overall goal of her work. “The main challenge we face as agricultural researchers is contributing to a nutritious, affordable diet produced within planetary boundaries,” she says. “Tackling any part of this challenge requires us to communicate between disciplines, to look at agri-food systems as a whole, and to link production and consumption.”
At the same time, for Palacios, the beauty of her work lies in going deep into a specific research question before bringing her focus back to the big picture. This movement between the specific and the general keeps her motivated, generates new questions and avenues of research, and keeps her from falling into silver-bullet thinking.
For example, her work on provitamin A biofortified maize led her to ask questions about how much of the vitamin reached consumers depending on how the grain was stored and handled. The vitamin is prone to degradation through oxidation. This led to storage and processing recommendations meant to maximize the crop’s nutritional value, including storing provitamin A maize as grain and milling it as late as possible before consumption. Researchers also worked to identify germplasm with more stable provitamin A carotenoids to be used in the breeding program.
In one study, Palacios and her coauthors found that feeding biofortified maize to hens increased the provitamin A value of their eggs, suggesting that for rural households the nutritional benefits of the improved grain could be spread out across different foodstuffs.
Bringing it all together
In a paper published last spring, Palacios and her co-authors bring together the insights of these various avenues of research into one comprehensive review. The point, Palacios explains “was to identify opportunities to exploit the nutritional benefits of maize — a grain largely consumed in Africa, Latin America and some parts of Asia as important part of a diet — from understanding how to leverage the its genetic diversity for the development of more nutritious varieties to mapping all the different parts of the food system where nutritional gains can be made.”
The paper encompasses sections on the biochemistry of maize, maize breeding, maize-based foodways and culture, and traditional agronomic practices like milpa intercropping. It exemplifies Palacios’ interdisciplinary approach and her commitment to exploring multiple, interconnected pathways towards more nutritious maize agri-food systems.
As CGIAR’s 2030 Research and Innovation Strategy makes clear with its emphasis on the need for a systems-level transformation of food, land and water systems, this approach is timely and much needed.
In Palacios’ words: “Food security, nutrition and food safety are inextricably linked, and we must address them from the field to the plate and in a sustainable way.”
An international team of scientists has strengthened our understanding of how better fertilizer management could help minimize nitrous oxide (N2O) emissions while still achieving high crop yields in the new publication: Meta-analysis of yield and nitrous oxide outcomes for nitrogen management in agriculture. This research was conducted through a meta-analysis, where the results of multiple scientific studies were statistically combined.
To meet the world’s growing demand for food, farmers need fertile soil. Nitrogen, an essential element in plant fertilizer, can have extremely deleterious effects on the environment when not managed effectively. Numerous studies have confirmed that improving nitrogen use in agriculture is key to securing a food secure future and environmental sustainability.
“Society needs nuanced strategies based upon tailored nutrient management approaches that keep nitrogen balances within safe limits,” said Tai M Maaz, researcher at University of Hawaii at Manoa and lead author of the study.
When farmers apply nitrogen fertilizer to their crop, typically only 30-40% of it is taken up by the plant and the rest is lost the the environment. One byproduct is nitrous oxide (N2O), one of the most potent greenhouse gases in the atmosphere. Global agriculture is a major contributor of greenhouse gas emissions, especially those derived from nitrous oxide emissions.
Although farmers are now commonly told to practice fertilizer rate reduction, or simply put, to apply less fertilizer, there are cases where that strategy is either not possible or not advisable.
Alternative predictors of emissions
The study found that output indicators such as partial nitrogen balance (PNB), an indicator for the amount of nitrogen prone to loss, and partial factor productivity (PFP), a measure of input-use efficiency, predicted nitrous oxide emissions as well as or better than the application rate alone. This means that in some cases, where nitrogen rate reduction is not possible, nitrous oxide emission can still be reduced by increasing yield through implementation of improved fertilizer management practices, such as the “4Rs:” right source, right timing, right placement and right application rate.
Tek B Sapkota, climate scientist at the International Maize and Wheat Improvement Center (CIMMYT) and co-author of the study, emphasized that “rate reduction is still important in the cropping systems where the current level of nitrogen application is excessively high. But, when comparing the systems at the same nitrogen application rates, nitrous oxide emission can be reduced by increasing yield.”
“The 4R nutrient management practices must be tailored to specific regions to help close yield gaps and maintain environmental sustainability: the win-win scenario. The future will require public and private institutions working together to disseminate such nutrient management information for specific cropping systems in specific geographies,” said Sapkota, who is also a review editor of the Intergovernmental Panel on Climate Change (IPCC) sixth assessment report.
The article was a collaborative effort from the International Maize and Wheat Improvement Center (CIMMYT), the University of Hawaii, the Environmental Defense Fund, Plant Nutrition Canada and the African Plant Nutrition Institute. It was funded by the CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS).
Read the full study:
Meta-analysis of yield and nitrous oxide outcomes for nitrogen management in agriculture
FOR MORE INFORMATION, OR TO ARRANGE INTERVIEWS, CONTACT:
Marcia MacNeil, Communications Officer, CGIAR Research Program on Wheat, CIMMYT. m.macneil@cgiar.org
About CIMMYT
The International Maize and Wheat 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 Research 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
Through regenerative agriculture prices, Grupo Bimbo, a partner of CIMMYT, is revitalizing and ensuring the sustainability of Mexico’s agricultural sector.
Read more: https://www.forbes.com.mx/ad-agricultura-regenerativa-ruta-sustentable-grupo-bimbo/
Health has certainly been in the spotlight over the past year. And how could it not be?
The ongoing COVID-19 pandemic has thrown into sharp relief the fact that many groups across the world struggle to make ends meet with little daily income, have poorer housing conditions and education, fewer employment opportunities, and have little or no access to safe environments, clean water and air, food security and health services.
In light of this, the World Health Organization (WHO) is calling on leaders worldwide to ensure that everyone has living and working conditions that are conducive to good health. For many the focus will, understandably, be on access to quality health care services. But there are myriad other factors that influence our ability to lead healthy lives — from how we care for our soil, to what we eat and the air we breathe.
Joining this year’s World Health Day campaign, the International Maize and Wheat Improvement Center (CIMMYT) is highlighting five areas where it pays to think about health, and the solutions we can use to help build a healthier world for everyone.
Crop yields fall dramatically when soil conditions aren’t right, but digital nutrient management tools providing tailored fertilizer recommendations can boost farmers’ profits and productivity while reducing emissions.
How do we ensure that germplasm reserves are not potential vectors of pest and disease transmission? The second instalment in the CGIAR International Year of Plant Health Webinar Series tackles the often-overlooked issue of germplasm health.
By growing maize simultaneously for both human consumption and quality animal feed, farmers can get the most out of their crops and conserve natural resources like land and water.
The traditional milpa intercrop — in which maize is grown together with beans, squash or other vegetable crops — can furnish a vital supply of food and nutrients for marginalized, resource-poor communities in the Americas.
Compared to conventional tillage practices, sowing wheat directly into just-harvested rice fields without burning or removing straw or other residues can reduce severe air pollution while lessening irrigation needs.
Interested in learning more about CIMMYT’s health-related work? Check out our archive of health and nutrition content.
Featured image: A farmer inspects a drought-tolerant bean plant on a trial site in Malawi. (Photo: Neil Palmer/CIAT)
A new digital soil map for Nepal provides access to location-specific information on soil properties for any province, district, municipality or a particular area of interest. The interactive map provides information that will be useful to make new crop- and site-specific fertilizer recommendations for the country.
Produced by the International Maize and Wheat Improvement Center (CIMMYT), in collaboration with Nepal Agricultural Research Council’s (NARC) National Soil Science Research Center (NSSRC), this is the first publicly available soil map in South Asia that covers the entire country.
The Prime Minister of Nepal, K.P. Sharma Oli, officially launched the digital soil map at an event on February 24, 2021. Oli highlighted the benefits the map would bring to support soil fertility management in the digital era in Nepal. He emphasized its sustainability and intended use, mainly by farmers.
CIMMYT and NSSRC made a live demonstration of the digital soil map. They also developed and distributed an informative booklet that gives an overview of the map’s major features, operation guidelines, benefits, management and long-term plans.
The launch event was led by the Ministry of Agriculture and Livestock Development and organized in coordination with NARC, as part of the Nepal Seed and Fertilizer (NSAF) project, implemented by CIMMYT. More than 200 people participated in the event, including government officials, policymakers, scientists, professors, development partner representatives, private sector partners and journalists. The event was also livestreamed.
Better decisions
Immediately after the launch of the digital soil map, its CPU usage grew up to 94%. Two days after the launch, 64 new accounts had been created, who downloaded different soil properties data in raster format for use in maps and models.
The new online resource was prepared using soil information from 23,273 soil samples collected from the National Land Use Project, Central Agricultural Laboratory and Nepal Agricultural Research Council. The samples were collected from 56 districts covering seven provinces. These soil properties were combined with environmental covariates (soil forming factors) derived from satellite data and spatial predictions of soil properties were generated using advanced machine learning tools and methods.
The platform is hosted and managed by NARC, who will update the database periodically to ensure its effective management, accuracy and use by local government and relevant stakeholders. The first version of the map was finalized and validated through a workshop organized by NSSRC among different stakeholders, including retired soil scientists and university professors.
“The ministry can use the map to make more efficient management decisions on import, distribution and recommendation of appropriate fertilizer types, including blended fertilizers. The same information will also support provincial governments to select suitable crops and design extension programs for improving soil health,” said Padma Kumari Aryal, Minister of Agriculture and Livestock Development, who chaired the event. “The private sector can utilize the acquired soil information to build interactive and user-friendly mobile apps that can provide soil properties and fertilizer-related information to farmers as part of commercial agri-advisory extension services,” she said.
“These soil maps will not only help to increase crop yields, but also the nutritional value of these crops, which in return will help solve problems of public health such as zinc deficiency in Nepal’s population,” explained Ivan Ortiz-Monasterio, principal scientist at CIMMYT, in a video message.
Yogendra Kumar Karki, secretary of the Ministry of Agriculture and Livestock Development, presented the program objectives and Deepak Bhandari, executive director of NARC, talked about the implementation of the map and its sustainability. Special remarks were also delivered by USAID Nepal’s mission director, the secretary of Livestock, scientists and professors from Tribhuwan University, the International Fertilizer Development Center (IFDC) and the International Centre for Integrated Mountain Development (ICIMOD).
Benefits of digital soil mapping
Soil properties affect crop yield and production. In Nepal, access to soil testing facilities is rather scarce, making it difficult for farmers to know the fertilizer requirement of their land. The absence of a well-developed soil information system and soil fertility maps has been lacking for decades, leading to inadequate strategies for soil fertility and fertilizer management to improve crop productivity. Similarly, existing blanket-type fertilizer recommendations lead to imbalanced application of plant nutrients and fertilizers by farmers, which also negatively affects crop productivity and soil health.
This is where digital soil mapping comes in handy. It allows users to identify a domain with similar soil properties and soil fertility status. The digital platform provides access to domain-specific information on soil properties including soil texture, soil pH, organic matter, nitrogen, available phosphorus and potassium, and micronutrients such as zinc and boron across Nepal’s arable land.
Farmers and extension agents will be able to estimate the total amount of fertilizer required for a particular domain or season. As a decision-support tool, policy makers and provincial government can design and implement programs for improving soil fertility and increasing crop productivity. The map also allows users to identify areas with deficient plant nutrients and provide site-specific fertilizer formulations; for example, determining the right type of blended fertilizers required for balanced fertilization programs. Academics can also obtain periodic updates from these soil maps and use it as a resource while teaching their students.
As digital soil mapping advances, NSSRC will work towards institutionalizing the platform, building awareness at the province and local levels, validating the map, and establishing a national soil information system for the country.
Nepal’s digital soil map is readily accessible on the NSSRC web portal:
https://soil.narc.gov.np/soil/soilmap/