As a fast growing region with increasing challenges for smallholder farmers, Asia is a key target region for CIMMYT. CIMMYT’s work stretches from Central Asia to southern China and incorporates system-wide approaches to improve wheat and maize productivity and deliver quality seed to areas with high rates of child malnutrition. Activities involve national and regional local organizations to facilitate greater adoption of new technologies by farmers and benefit from close partnerships with farmer associations and agricultural extension agents.
The FAO official pointed out that a number of factors help to shield Bangladesh, including the direction of the wind, the monsoon, and India’s robust locust monitoring system.
Read more here: https://www.dhakatribune.com/bangladesh/2020/06/11/fao-no-threat-of-desert-locust-invasion-in-bangladesh
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?
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.
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.
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.
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)
Dipak Kafle is a Business Development Analyst with CIMMYT’s Global Maize Program, based in Nepal.
Darbin Joshi is an Assistant Research Associate with CIMMYT’s Global Maize Program, based in Nepal.
Aashif Iqubal Khan is an Assistant Research Associate with CIMMYT’s Nepal Seed and Fertilizer Project, based in Nepal.
Nepalese and CIMMYT wheat scientists, working at the Nepal Agricultural Research Council (NARC) and the International Maize and Wheat Improvement Centre (CIMMYT) suspect new races of stripe and leaf rust infected the wheat crop in the Nepal hills and terai in the recent 2020 wheat season. This was reported after detailed survey and surveillance activities of rust diseases in the terai and hill regions were carried out during March and April, before the COVID-19 pandemic forced the cessation of many field activities.
Read more here: https://www.seedquest.com/news.php?type=news&id_article=117729&id_region=&id_category=&id_crop=
The tremendous diversity of crops in Pakistan has been documented in a new publication that will foster more effective and targeted policies for national agriculture.
Using official records and geospatial modeling to describe the location, extent, and management of 25 major and minor crops grown in 144 districts of Pakistan, the publication “Cropping Pattern Zonation of Pakistan” offers an invaluable tool for resource planning and policymaking to address opportunities, challenges and risks for farm productivity and profitability, according to Muhammad Imtiaz, crop scientist and country representative in Pakistan for the International Maize and Wheat Improvement Center (CIMMYT).
“With rising temperatures, more erratic rainfall and frequent weather extremes, cropping pattern decisions are of the utmost importance for risk mitigation and adaptation,” said Imtiaz, a co-author of the new publication.
Featuring full-color maps for Pakistan’s two main agricultural seasons, based on area sown to individual crops, the publication was put together by CIMMYT and the Climate, Energy and Water Research Institute (CEWRI) of the Pakistan Agricultural Research Council (PARC), with technical and financial support from the Agricultural Innovation Program (AIP) for Pakistan, which is funded by the U.S. Agency for International Development (USAID).
Pakistan’s main crops–wheat, rice, cotton and sugarcane—account for nearly three-quarters of national crop production. Various food and non-food crops are grown in “Rabi,” the dry winter season, October-March, and “Kharif,” the summer season characterized by high temperatures and monsoon rains.
Typically, more than one crop is grown in succession on a single field each year; however, despite its intensity, farming in Pakistan is largely traditional or subsistence agriculture dominated by the food grains, according to Ms. Rozina Naz, Principal Scientific Officer, CEWRI-PARC.
“Farmers face increasing aridity and unpredictable weather conditions and energy shortage challenges that impact on their decisions regarding the type and extent of crops to grow,” said the scientist, who is involved in executing the whole study. “Crop pattern zoning is a pre-requisite for the best use of land, water and capital resources.”
The study used 5 years (2013-14 to 2017-18) of data from the Department of Agricultural Statistics, Economics Wing, Ministry of National Food Security and Research, Islamabad. “We greatly appreciate the contributions of scientists and technical experts of Crop Science Institute (CSI) and CIMMYT,” Imtiaz added.
View or download the publication:
Cropping Pattern Zonation of Pakistan. Climate, Energy and Water Research Institute, National Agricultural Research Centre, Pakistan Agricultural Research Council, and the International Maize and Wheat Improvement Center. 2020. CDMX: CEWRI, PARC, and CIMMYT.
See more recent publications from CIMMYT researchers:
1. Plant community strategies responses to recent eruptions of Popocatépetl volcano, Mexico. 2019. Barba‐Escoto, L., Ponce-Mendoza, A., García-Romero, A., Calvillo-Medina, R.P. In: Journal of Vegetation Science v. 30, no. 2, pag. 375-385.
2. New QTL for resistance to Puccinia polysora Underw in maize. 2019. Ce Deng, Huimin Li, Zhimin Li, Zhiqiang Tian, Jiafa Chen, Gengshen Chen, Zhang, X, Junqiang Ding, Yuxiao Chang In: Journal of Applied Genetics v. 60, no. 2, pag. 147-150.
3. Hybrid wheat: past, present and future. 2019. Pushpendra Kumar Gupta, Balyan, H.S., Vijay Gahlaut, Pal, B., Basnet, B.R., Joshi, A.K. In: Theoretical and Applied Genetics v. 132, no. 9, pag. 2463-2483.
4. Influence of tillage, fertiliser regime and weeding frequency on germinable weed seed bank in a subhumid environment in Zimbabwe. 2019. Mashavakure, N., Mashingaidze, A.B., Musundire, R., Gandiwa, E., Thierfelder, C., Muposhi, V.K., Svotwa, E.In: South African Journal of Plant and Soil v. 36, no. 5, pag. 319-327.
5. Identification and mapping of two adult plant leaf rust resistance genes in durum. 2019. Caixia Lan, Zhikang Li, Herrera-Foessel, S., Huerta-Espino, J., Basnet, B.R., In: Molecular Breeding v. 39, no. 8, art. 118.
6. Genetic mapping reveals large-effect QTL for anther extrusion in CIMMYT spring wheat. 2019. Muqaddasi, Q.H., Reif, J.C., Roder, M.S., Basnet, B.R., Dreisigacker, S. In: Agronomy v. 9 no. 7, art. 407.
7. Growth analysis of brachiariagrasses and ‘tifton 85’ bermudagrass as affected by harvest interval. 2019. Silva, V. J. da., Faria, A.F.G., Pequeno, D.N.L., Silva, L.S., Sollenberger, L.E., Pedreira, C. G. S. In: Crop Science v. 59, no. 4, pag. 1808-1814.
8. Simultaneous biofortification of wheat with zinc, iodine, selenium, and iron through foliar treatment of a micronutrient cocktail in six countries. 2019. Chunqin Zou, Yunfei Du, Rashid, A., Ram, H., Savasli, E., Pieterse, P.J., Ortiz-Monasterio, I., Yazici, A., Kaur, C., Mahmood, K., Singh, S., Le Roux, M.R., Kuang, W., Onder, O., Kalayci, M., Cakmak, I. In: Journal of Agricultural and Food Chemistry v. 67, no. 29, pag. 8096-8106.
9. Economic impact of maize stem borer (Chilo partellus) attack on livelihood of maize farmers in Pakistan. 2019. Ali, A., Issa, A.B. In: Asian Journal of Agriculture and Biology v. 7, no. 2, pag. 311-319.
10. How much does climate change add to the challenge of feeding the planet this century?. 2019. Aggarwal, P.K., Vyas, S., Thornton, P.K., Campbell, B.M. In: Environmental Research Letters v. 14 no. 4, art. 043001.
11. A breeding strategy targeting the secondary gene pool of bread wheat: introgression from a synthetic hexaploid wheat. 2019. Ming Hao, Lianquan Zhang, Laibin Zhao, Shoufen Dai, Aili Li, Wuyun Yang, Die Xie, Qingcheng Li, Shunzong Ning, Zehong Yan, Bihua Wu, Xiujin Lan, Zhongwei Yuan, Lin Huang, Jirui Wang, Ke Zheng, Wenshuai Chen, Ma Yu, Xuejiao Chen, Mengping Chen, Yuming Wei, Huaigang Zhang, Kishii, M, Hawkesford, M.J, Long Mao, Youliang Zheng, Dengcai Liu In: Theoretical and Applied Genetics v. 132, no. 8, pag. 2285-2294.
12. Sexual reproduction of Zymoseptoria tritici on durum wheat in Tunisia revealed by presence of airborne inoculum, fruiting bodies and high levels of genetic diversity. 2019. Hassine, M., Siah, A., Hellin, P., Cadalen, T., Halama, P., Hilbert, J.L., Hamada, W., Baraket, M., Yahyaoui, A.H., Legreve, A., Duvivier, M. In: Fungal Biology v. 123, no. 10, pag. 763-772.
13. Influence of variety and nitrogen fertilizer on productivity and trait association of malting barley. 2019. Kassie, M., Fantaye, K. T. In: Journal of Plant Nutrition v. 42, no. 10, pag. 1254-1267.
14. A robust Bayesian genome-based median regression model. 2019. Montesinos-Lopez, A., Montesinos-Lopez, O.A., Villa-Diharce, E.R., Gianola, D., Crossa, J. In: Theoretical and Applied Genetics v. 132, no. 5, pag. 1587-1606.
15. High-throughput phenotyping platforms enhance genomic selection for wheat grain yield across populations and cycles in early stage. 2019. Jin Sun, Poland, J.A., Mondal, S., Crossa, J., Juliana, P., Singh, R.P., Rutkoski, J., Jannink, J.L., Crespo-Herrera, L.A., Velu, G., Huerta-Espino, J., Sorrells, M.E. In: Theoretical and Applied Genetics v. 132, no. 6, pag. 1705-1720.
16. Resequencing of 429 chickpea accessions from 45 countries provides insights into genome diversity, domestication and agronomic traits. 2019. Varshney, R.K., Thudi, M., Roorkiwal, M., Weiming He, Upadhyaya, H., Wei Yang, Bajaj, P., Cubry, P., Abhishek Rathore, Jianbo Jian, Doddamani, D., Khan, A.W., Vanika Garg, Annapurna Chitikineni, Dawen Xu, Pooran M. Gaur, Singh, N.P., Chaturvedi, S.K., Nadigatla, G.V.P.R., Krishnamurthy, L., Dixit, G.P., Fikre, A., Kimurto, P.K., Sreeman, S.M., Chellapilla Bharadwaj, Shailesh Tripathi, Jun Wang, Suk-Ha Lee, Edwards, D., Kavi Kishor Bilhan Polavarapu, Penmetsa, R.V., Crossa, J., Nguyen, H.T., Siddique, K.H.M., Colmer, T.D., Sutton, T., Von Wettberg, E., Vigouroux, Y., Xun Xu, Xin Liu In: Nature Genetics v. 51, pag. 857-864.
17. Farm typology analysis and technology assessment: an application in an arid region of South Asia. 2019. Shalander Kumar, Craufurd, P., Amare Haileslassie, Ramilan, T., Abhishek Rathore, Whitbread, A. In: Land Use Policy v. 88, art. 104149.
18. MARPLE, a point-of-care, strain-level disease diagnostics and surveillance tool for complex fungal pathogens. 2019. Radhakrishnan, G.V., Cook, N.M., Bueno-Sancho, V., Lewis, C.M., Persoons, A., Debebe, A., Heaton, M., Davey, P.E., Abeyo Bekele Geleta, Alemayehu, Y., Badebo, A., Barnett, M., Bryant, R., Chatelain, J., Xianming Chen, Suomeng Dong, Henriksson, T., Holdgate, S., Justesen, A.F., Kalous, J., Zhensheng Kang, Laczny, S., Legoff, J.P., Lesch, D., Richards, T., Randhawa, H. S., Thach, T., Meinan Wang, Hovmoller, M.S., Hodson, D.P., Saunders, D.G.O. In: BMC Biology v. 17, no. 1, art. 65.
19. Genome-wide association study for multiple biotic stress resistance in synthetic hexaploid wheat. 2019. Bhatta, M.R., Morgounov, A.I., Belamkar, V., Wegulo, S.N., Dababat, A.A., Erginbas-Orakci, G., Moustapha El Bouhssini, Gautam, P., Poland, J.A., Akci, N., Demir, L., Wanyera, R., Baenziger, P.S. In: International Journal of Molecular Sciences v. 20, no. 15, art. 3667.
20. Genetic diversity and population structure analysis of synthetic and bread wheat accessions in Western Siberia. 2019. Bhatta, M.R., Shamanin, V., Shepelev, S.S., Baenziger, P.S., Pozherukova, V.E., Pototskaya, I.V., Morgounov, A.I. In: Journal of Applied Genetics v. 60, no. 3-4, pag. 283-289.
21. Identifying loci with breeding potential across temperate and tropical adaptation via EigenGWAS and EnvGWAS. 2019. Jing Li, Gou-Bo Chen, Rasheed, A., Delin Li, Sonder, K., Zavala Espinosa, C., Jiankang Wang, Costich, D.E., Schnable, P.S., Hearne, S., Huihui Li In: Molecular Ecology v. 28, no. 15, pag. 3544-3560.
22. Impacts of drought-tolerant maize varieties on productivity, risk, and resource use: evidence from Uganda. 2019. Simtowe, F.P., Amondo, E., Marenya, P. P., Rahut, D.B., Sonder, K., Erenstein, O. In: Land Use Policy v. 88, art. 104091.
23. Do market shocks generate gender-differentiated impacts?: policy implications from a quasi-natural experiment in Bangladesh. 2019. Mottaleb, K.A., Rahut, D.B., Erenstein, O. In: Women’s Studies International Forum v. 76, art. 102272.
24. Gender differences in the adoption of agricultural technology: the case of improved maize varieties in southern Ethiopia. 2019. Gebre, G.G., Hiroshi Isoda, Rahut, D.B., Yuichiro Amekawa, Hisako Nomura In: Women’s Studies International Forum v. 76, art. 102264.
25. Tracking the adoption of bread wheat varieties in Afghanistan using DNA fingerprinting. 2019. Dreisigacker, S., Sharma, R.K., Huttner, E., Karimov, A. A., Obaidi, M.Q., Singh, P.K., Sansaloni, C.P., Shrestha, R., Sonder, K., Braun, H.J. In: BMC Genomics v. 20, no. 1, art. 660.
Ispahani and AgBiTech are pleased to announce the formal registration of a biological control for Fall Armyworm in Bangladesh.
This rapid assessment and registration despite the ongoing lockdown due to Covid-19 is the result of months of collaborative hard work and support from members representing multiple organizations including USAID, CIMMYT, the Ministry of Agriculture, Bangladesh Agricultural Research Institute, Plant Protection Wing of Agricultural Extension, and the Fall Armyworm National Task Force.
Read more here: https://www.prnewswire.com/news-releases/fawligen-registered-in-bangladesh-301061228.html
A major farmer survey is gathering data to understand how smallholders in Laos are responding to fall armyworm invasion and develop agroecological management options to control its spread.
The study, led by the International Maize and Wheat Improvement Center (CIMMYT) in partnership with the Lao Farmer Network (LFN) and the National Agriculture and Forestry Research Institute (NAFRI), is CIMMYT’s first official research initiative in the country.
Farmer surveys are being conducted in some of the country’s key maize farming areas, recording attempts to manage the pest and laying the groundwork to raise awareness on sustainable best-bet agroecological strategies that promote a healthy system approach to maize farming, says Horst Weyerhaeuser, a scientific program consultant working with CIMMYT.
“Currently, researchers, policy makers and extension officers possess little information on fall armyworm pest management and control in Laos,” he explains. “The survey is working to build a knowledge-base.”
In June 2019, CIMMYT and national research scientists confirmed that fall armyworm, a global pest that affects the food security of millions of maize farmers, was present in the country.
Working with CIMMYT, LFN trained lead farmers to conduct surveys and collect data from farmers in their local areas. The network has also been distributing a series of infographics and videos in local languages, developed by CIMMYT and translated with major support from HELVETAS Swiss Intercooperation and the Lao Farmer Rural Advisory Project, to describe appropriate pesticide use and sustainable farming practices to limit impact on harvests.
“The survey data explores how farmers respond to the armyworm in their maize fields, so that integrated pest management strategies can be promoted for successful pest control and especially to limit excessive use of harmful pesticides,” says Phoutthasinh Phimmachanh, who leads the LFN secretariat. “The survey also asks about farmers’ plans for the upcoming rainy season and if they experienced a fall armyworm infestation in 2019 will it change their crop selection and planting schemes.”
The initiative is part of a larger strategy to work with government and farmers in southeast Asia to build a knowledge base on sustainable maize farming through the CGIAR program on MAIZE. Due to the impact of COVID-19, researchers are currently exploring options to continue these and additional surveys digitally and via telephone.
As maize farming increases, so does the risk fall armyworm poses to farmer livelihoods
Maize is becoming an increasingly important cash crop in southeast Asia as diets change and consumer preferences for white meat and pork drive a transition from subsistence to commercial maize feed production. Farmer focus groups in northern Laos suggest that maize sales deliver more than 60% of smallholders’ annual cash income.
“Maize is the only cash crop for thousands of smallholder farmers in Laos. Fall armyworm poses a credible threat to their livelihoods and could push them to a vicious circle of poverty and damage to the environment,” explains CIMMYT economist Amjath Babu.
“We want to confirm anecdotal accounts suggesting uninformed farmers are buying whatever pesticides they can get their hands on in a bid to control the pest’s impact on harvests. This reaction mimics that of initial farmer responses in sub-Saharan Africa when the pest first broke out there in 2016.” In this sense, he adds, CIMMYT’s partnership with LFN helps to measure the implications of fall armyworm and the potential for this pest to reduce farmers’ profit margins while encouraging unsustainable pesticide use.
Pesticides must be used with extreme caution and only appropriately if they are to be a part of any fall armyworm management regime, warns CIMMYT Senior Scientist Tim Krupnik.
“The pest has particular habits — like living under leaves, hiding in hard to reach places of the plant, and feeding mainly at night,” he explains. “This makes indiscriminate application of insecticides relatively less useful.” It could also inadvertently contribute to the loss of biodiversity and ecosystem services through overuse of pesticides that cause mortality for natural enemies and parasitoids.
Scientists want to explore whether the higher production costs farmers may incur through additional insecticide purchase is encouraging a shift from maize cash crop monocultures to a more diverse production including replacement or rotations with cassava, fodder crops, and rotational grazing, where feasible.
“By building an evidence base we can work with the National Agriculture and Forestry Research Institute,the agricultural department and farmers to build sustainable, resilient maize farming systems that ensure farmers continue to cash in on maize while diversifying production into sensible alternative crops, with emphasis on protecting their health and the environment,” Babu adds.
Fall armyworm survey part of a larger increase in maize research in southeast Asia
The expansion of maize in Laos has been accompanied by a progressive decrease in landscape and agricultural biodiversity, as farmers respond to opportunities to export maize at relatively profitable prices, largely to neighboring Vietnam and China, by resorting to an expansion of slash-and-burn agriculture with shortened fallows. The rapidly growing demand for maize has resulted in unsustainable farming systems intensification, explains Krupnik, with many farmers clearing forests to plant, and using excessive amounts of herbicides to keep weeds at bay.
“Combined with the fall armyworm invasion, potentially dangerous pesticides have been added to this scenario, with quite concerning potential consequences for further biodiversity loss and contamination of mountain streams by agrochemicals,” he says.
“Projects run by Helvetas, which has helped support our research through coordination and convening efforts, have measured dangerous levels of pesticides in the blood of samples taken from farmers and their families and government officials.”
Maize is important for income generation, but more sustainable and diverse cropping systems are needed to reduce the impact on biodiversity, while avoiding the worst pesticides that comprise human health. The data generated from this research will help design strategies to respond to these problems with more appropriate agricultural practices.
The ministry of agriculture has welcomed support from CIMMYT’s maize systems experts to aid in building a base of knowledge to inform the development of agricultural policy, says Chay Bounphanousay, director general of the National Agriculture and Forestry Research Institute. “With the rise of maize farming and the associated challenges and opportunities it brings, an increase in research will inform agricultural policy to improve farmer livelihoods while protecting the environment.”
Cover photo: Traditional mixed maize farming system in northern Laos. (Photo: H. Weyerhaeuser/CIMMYT)
Highland maize production systems in Southeast Asia are crucial in that they generate considerable income for otherwise impoverished farmers in remote upland areas. However, they are largely unsustainable, involving destructive slash and burn agriculture, with increasingly short fallow times between crops. Additionally, and in response to historically favorable maize markets, many farmers now plan to expand maize cultivation areas, which is anticipated to have serious consequences for biodiversity loss and ecosystem services.
The arrival of fall armyworm adds additional pressures that could lead to intensification of management practices and over-use of insecticides; a partial transition away from maize as farmers respond to the pest by growing other crops and initiating new land use practices; and increased use of sustainable intensification practices that employ agroecological options for fall armyworm management.
Responding to fall armyworm (Spodoptera frugiperda J.E. Smith) with data, evidence and agroecological management options in Lao PDR is a research project funded through the CGIAR Research Program on Maize (MAIZE). It sees CIMMYT partner with the Laos Farmer Network (LFN) and the National Agriculture and Forestry Research Institute (NAFRI) to understand how smallholders in the country are responding to fall armyworm invasion and develop agroecological management options to control its spread.
Working with CIMMYT, LFN will train lead farmers to conduct surveys and collect data from farmers in their local areas. The network will also distribute a series of infographics and videos in local languages, developed by CIMMYT and translated with major support from HELVETAS Swiss Intercooperation and the Lao Farmer Rural Advisory Project, to outline appropriate pesticide use and sustainable farming practices to limit impact on harvests. An estimated 2,000 farmers will receive information on research results and fall armyworm management advice.
The results will offer evidence-based insights allowing LFN and the Lao Upland Rural Advisory Service (LURAS) project to plan future extension and development activities more effectively, while also identifying crucial additional research needs given these urgent issues and circumstances.
This research will yield actionable lessons and position LFN and the LURAS project to provide farmers with context-specific and agroecological fall armyworm management advice that responds to insights derived from farmer surveys that characterize pest incidence and severity, and relates them to farmers’ management practices, farm- and landscape-biodiversity, and location.
The use of small-scale mechanization in smallholder farming systems in South Asia has increased significantly in recent years. This development is a positive step towards agricultural transformation in the region. Small-scale mechanization is now seen as a viable option to address labor scarcity and offset the impact of male outmigration in rural areas, as well as other shortages that undermine agricultural productivity.
However, most existing farm mechanization technologies are either gender blind or gender neutral. This is often to the detriment of women farmers, who are increasingly taking on additional agricultural work in the absence of male laborers. Minimizing this gender disparity among smallholders has been a key concern for policymakers, but there is little empirical literature available on gender and farm mechanization.
A new study by researchers at the International Maize and Wheat Improvement Center (CIMMYT) addresses this gap, using data from six districts in the highlands of Nepal to assess the impact of the gender of household heads on the adoption of mini-tillers — small machinery used to prepare and cultivate land before planting.
Their findings reveal that, when it comes to mini-tiller adoption, there is a significant gender gap. Compared to male-headed households, explain the authors, the rate of adoption is significantly lower among female-headed households. Moreover, they add, when male- and female-headed households have similar observed attributes, the mini-tiller adoption rate among the food insecure female-headed households is higher than in the food secure group.
The authors argue that this gender-differentiated mini-tiller adoption rate can be minimized in the first instance by increasing market access. Their findings suggest that farm mechanization policies and programs targeted specifically to female-headed households can also help reduce this adoption gap in Nepal and similar hill production agroecologies in South Asia, which will enhance the farm yield and profitability throughout the region.
Read the full article in Technology in Society:
Gender differentiated small-scale farm mechanization in Nepal hills: An application of exogenous switching treatment regression.
See more recent publications from CIMMYT researchers:
The Asia Regional Resilience to a Changing Climate (ARRCC) program is managed by the UK Met Office, supported by the World Bank and the UK’s Department for International Development (DFID). The four-year program, which started in 2018, aims to strengthen weather forecasting systems across Asia. The program will deliver new technologies and innovative approaches to help vulnerable communities use weather warnings and forecasts to better prepare for climate-related shocks.
Since 2019, as part of ARRCC, CIMMYT has been working with the Met Office and Cambridge University to pilot an early warning system to deliver wheat rust and blast disease predictions directly to farmers’ phones in Bangladesh and Nepal.
The system was first developed in Ethiopia. It uses weather information from the Met Office, the UK’s national meteorological service, along with field and mobile phone surveillance data and disease spread modeling from the University of Cambridge, to construct and deploy a near real-time early warning system.
Phase I: 12-Month Pilot Phase
Around 50,000 smallholder farmers are expected to receive improved disease warnings and appropriate management advisories in the first 12 months as part of a proof-of-concept modeling and pilot advisory extension phase focused on three critical diseases:
Phase II: Scaling-out wheat rust early warning advisories, introducing wheat blast forecasting and refinement model refinement
Subject to funding approval the second year of the project will lead to validation of the wheat rust early warnings, in which researchers compare predictions with on-the-ground survey results, increasingly supplemented with farmer response on the usefulness of the warnings facilitated by national research and extension partners. Researchers shall continue to introduce and scale-out improved early warning systems for wheat blast. Concomitantly, increasing the reach of the advice to progressively larger numbers of farmers while refining the models in the light of results. We anticipate that with sufficient funding, Phase II activities could reach up to 300,000 more farmers in Nepal and Bangladesh.
Phase III: Demonstrating that climate services can increase farmers’ resilience to crop diseases
As experience is gained and more data is accumulated from validation and scaling-out, researchers will refine and improve the precision of model predictions. They will also place emphasis on efforts to train partners and operationalize efficient communication and advisory dissemination channels using information communication technologies (ICTs) for extension agents and smallholders. Experience from Ethiopia indicates that these activities are essential in achieving ongoing sustainability of early warning systems at scale. Where sufficient investment can be garnered to support the third phase of activities, it is expected that an additional 350,000 farmers will receive disease management warnings and advisories in Nepal and Bangladesh, totaling 1 million farmers over a three-year period.
Objectives
A new fact sheet captures the impact of CIMMYT after six decades of maize and wheat research in Pakistan.
Dating back to the 1960s, the research partnership between Pakistan and CIMMYT has played a vital role in improving food security for Pakistanis and for the global spread of improved crop varieties and farming practices.
Norman Borlaug, Nobel Peace Prize laureate and first director of CIMMYT wheat research, kept a close relationship with the nation’s researchers and policymakers. CIMMYT’s first training course participant from Pakistan, Manzoor A. Bajwa, introduced the high-yielding wheat variety “Mexi-Pak” from CIMMYT to help address the national food security crisis. Pakistan imported 50 tons of Mexi-Pak seed in 1966, the largest seed purchase of its time, and two years later became the first Asian country to achieve self-sufficiency in wheat, with a national production of 6.7 million tons.
In 2019 Pakistan harvested 26 million tons of wheat, which roughly matches its annual consumption of the crop.
In line with Pakistan’s National Food Security Policy and with national partners, CIMMYT contributes to Pakistan’s efforts to intensify maize- and wheat-based cropping in ways that improve food security, raise farmers’ income, and reduce environmental impacts. This has helped Pakistani farmers to figure among South Asia’s leaders in adopting improved maize and wheat varieties, zero tillage for sowing wheat, precision land leveling, and other innovations.
With funding from USAID, since 2013 CIMMYT has coordinated the work of a broad network of partners, both public and private, to boost the productivity and climate resilience of agri-food systems for wheat, maize, and rice, as well as livestock, vegetable, and fruit production.
Download the fact sheet:
CIMMYT and Pakistan: 60 years of collaboration
Cover photo: A wheat field in Pakistan, ready for harvest. (Photo: Kashif Syed/CIMMYT)
World’s leading food security think-tank and research centres have recommended Bangladesh to ensure transportation of food from rural to urban areas and the flow of crucial inputs to farmers through market systems so that risk to food system during Covid-19 pandemic can be averted.
Read more here: https://www.dhakatribune.com/business/2020/04/22/ifpri-irri-cimmyt-worldfish-make-joint-call-for-measures-to-avert-risk-to-food-system
Wheat blast (Magnaporthe oryzae pathotype Triticum, or MoT) was first discovered in Brazil in 1985. Since then, it has spread across central and southern Brazil, parts of Bolivia, Paraguay, and Argentina. Grain sterility caused by the disease can significantly reduce wheat yield, with reductions as high as 32% in some parts of Brazil, even with up to two fungicide applications.
The disease appeared in Bangladesh unexpectedly in 2016 and re-emerged in 2017. Wheat area consequently dropped from 62,763 hectares in 2016 to just 14,238 hectares a year later. Suitable climatic conditions in South Asia warn that wheat blast will be a long-term problem.
Some 300 million people in South Asia consume over 100 million tons of wheat annually. Wheat blast therefore presents a significant threat to food security. Compounding these problems, climate change and the evolution of wheat blast – increasing virulence, fungicide resistance and sexual recombination – present further threats.
This project responds to these problems by working to mitigate the effect of wheat blast in South Asia and South America and limit the risk of further spread of this threat, with an emphasis on training, surveillance and monitoring to mitigate the threat of wheat blast disease in Bangladesh and beyond.
Objectives