funder_partner: Chaudhary Charan Singh Haryana Agricultural University (CCS HAU)

Building technical capacity for emerging agri-research science and big data management

Written by Nima Chodon on August 14, 2023. Posted in News.

CSISA collaborates with Chaudhury Charan Singh Haryana Agriculture University to provide students with opportunities to engage in the latest agri-research and big data management. (Photo: CIMMYT)

Working alongside smallholder farmers, the Cereal Systems Initiative for South Asia (CSISA) project, has forged partnerships at the state and center levels to bridge the gap between innovation and the adoption of sustainable agricultural systems. In its current phase (2022-2025) in India, CSISA is helping mainstream innovation processes into the programing of national and state institutes through joint extension and research activities, including capacity building initiatives. Chaudhury Charan Singh Haryana Agriculture University (CCSHAU) is one of Asia’s biggest agricultural universities, located at Hisar in state of Haryana, India. Initially a campus of Punjab Agricultural University, Ludhiana, it became an autonomous institution in 1970 and contributed significantly to both the Green and White Revolutions in India.

Together with CCSHAU, CSISA recently initiated a landscape diagnostic survey (LDS) under the university’s rural agricultural work experience (RAWE) program for students graduating with an honors Bachelor of Science in agriculture. The twin objectives of this initiative were to gain an understanding of the existing challenges and opportunities for different cropping systems in Haryana through a bottom-up approach and to prepare students for careers in agriculture by building their practical skills in digital agriculture and big data management. This, explained CCSHAU Vice Chancellor B.R. Kamboj, who led the collaboration with CSISA, would provide recent graduates with the opportunity to “design a survey schedule, collect data in digital format, understand how farmers are adopting new technologies, and the learnings and challenges associated with each cropping system.”

Developing solutions for tomorrow’s problems

The predominant cropping systems practiced within the three ecologies of Haryana state are: the rice-wheat cropping system (RWCS); the cotton-wheat cropping system (CWCS); and the pearl millet-mustard cropping system (PMCS). The landscape diagnostic survey was carried out in parts of Sirsa and Hisar districts (for CWCS), Rewari and Mahendergarh districts (for PMCS) and Panipat, Yamunanagar, and Kurukshetra districts (for RWCS). The entire survey design was based on farmers’ participatory engagement and the cropping system framework.

A thorough process of survey design, including the training of master trainers, followed by orientation for students, was undertaken by the university’s RAWE faculty with support from CSISA’s technical team and participating KVKs. Students collected data from farming households using questionnaires and analyzed them using different analytical tools and techniques. Based on farmers’ responses, important data points about the region’s three crucial cropping systems were recorded and a book entitled Cropping Systems of Haryana – Challenges and Opportunities was published earlier this year, documenting the research process, data generated, results, and conclusions.

This has been a unique experience for both students and faculty that culminated in a research program with hands-on training. In the long run, this approach to capacity building for students is expected to support fieldwork and studies that help develop solutions to tomorrow’s problems in agricultural development. “The commitment of CCSHAU to implement a strong RAWE program under the technical guidance of CSISA, with support from the district KVKs, and student participation made this publication a strong endorsement and reference for similar RAWE programs across states and central universities,” acknowledged Peter Craufurd, CSISA project lead for India.

Lessons from the field

The survey helped build students’ capacity to design and understand data collection methods, analysis, and management with actual field exposure. Additionally, the qualitative data-gathering experience allowed them to develop their understanding of farmers’ perspectives in adopting or rejecting a particular technology or recommendation. Sharing her experience of the field sessions, RAWE student Muskan– group leader for the rice-wheat cropping system survey, said, “This process of data gathering, and field exposure is very motivating. I have a better understanding of our farmers’ practices and challenges.”

Another participating RAWE student and group leader for the cotton-wheat cropping system survey, Nilanchal Nishan said, “this exposure has helped me understand how policies and technology advancements affect farmers and their interaction with these changes over the years”.

“The entire process, from training to data management and curation, was fascinating for us,” said Aman Kumar, who led the pearl millet-mustard cropping system (PMCS) survey. He added that such field exposure will make students more aware of the trends and prevalent practices in the agricultural sector and help them choose their future field of research and study in a way that is in sync with real-time developments. These sentiments were echoed by RC Aggarwal, deputy director general for education at the Indian Council of Agricultural Research (ICAR), who called for more collaborations and capacity development exercises of this nature to be initiated in other state agriculture universities.

Read the full publication: Cropping Systems of Haryana – Challenges and Opportunities

A shortage of farm workers is driving the serious consideration by farmers and policymakers to replace traditional, labor-intensive puddled rice cropping (shown here), which leads to sizable methane emissions and profligate use of irrigation water, with the practice of growing rice in non-flooded soils, using conservation agriculture and drip irrigation practices. (Photo: P. Wall/CIMMYT)

A climate-smart remodeling of South Asia’s rice-wheat cropping is urgent

Written by Mike Listman on June 3, 2022. Posted in Publications.

A climate change hotspot region that features both small-scale and intensive farming, South Asia epitomizes the crushing pressure on land and water resources from global agriculture to feed a populous, warming world. Continuous irrigated rice and wheat cropping across northern India, for example, is depleting and degrading soils, draining a major aquifer, and producing a steady draft of greenhouse gases.

Through decades-long Asian and global partnerships, the International Maize and Wheat Improvement Center (CIMMYT) has helped to study and promote resource-conserving, climate-smart solutions for South Asian agriculture. Innovations include more precise and efficient use of water and fertilizer, as well as conservation agriculture, which blends reduced or zero-tillage, use of crop residues or mulches as soil covers, and more diverse intercrops and rotations. Partners are recently exploring regenerative agriculture approaches — a suite of integrated farming and grazing practices to rebuild the organic matter and biodiversity of soils.

Along with their environmental benefits, these practices can significantly reduce farm expenses and maintain or boost crop yields. Their widespread adoption depends in part on enlightened policies and dedicated promotion and testing that directly involves farmers. We highlight below promising findings and policy directions from a collection of recent scientific studies by CIMMYT and partners.

Getting down in the dirt

A recent scientific review examines the potential of a suite of improved practices — reduced or zero-tillage with residue management, use of organic manure, the balanced and integrated application of plant nutrients, land levelling, and precise water and pest control — to capture and hold carbon in soils on smallholder farms in South Asia. Results show a potential 36% increase in organic carbon in upper soil layers, amounting to some 18 tons of carbon per hectare of land and, across crops and environments, potentially cutting methane emissions by 12%. Policies and programs are needed to encourage farmers to adopt such practices.

Another study on soil quality in India’s extensive breadbasket region found that conservation agriculture practices raised per-hectare wheat yields by nearly half a ton and soil quality indexes nearly a third, over those for conventional practices, as well as reducing greenhouse gas emissions by more than 60%.

Ten years of research in the Indo-Gangetic Plains involving rice-wheat-mungbean or maize-wheat-mungbean rotations with flooded versus subsoil drip irrigation showed an absence of earthworms — major contributors to soil health — in soils under farmers’ typical practices. However, large earthworm populations were present and active under climate-smart practices, leading to improved soil carbon sequestration, soil quality, and the availability of nutrients for plants.

The field of farmer Ram Shubagh Chaudhary, Pokhar Binda village, Maharajganj district, Uttar Pradesh, India, who has been testing zero tillage to sow wheat directly into the unplowed paddies and leaving crop residues, after rice harvest. Chaudhary is one of many farmer-partners in the Cereal Systems Initiative for South Asia (CSISA), led by CIMMYT. (Photo: P. Kosina/CIMMYT)

Rebooting marginal farms by design

Using the FarmDESIGN model to assess the realities of small-scale, marginal farmers in northwestern India (about 67% of the population) and redesign their current practices to boost farm profits, soil organic matter, and nutritional yields while reducing pesticide use, an international team of agricultural scientists demonstrated that integrating innovative cropping systems could help to improve farm performance and household livelihoods.

More than 19 gigatons of groundwater is extracted each year in northern India, much of this to flood the region’s puddled, transplanted rice crops. A recent experiment calibrated and validated the HYDRUS-2D model to simulate water dynamics for puddled rice and for rice sown in non-flooded soil using zero-tillage and watered with sub-surface drip irrigation. It was found that the yield of rice grown using the conservation agriculture practices and sub-surface drip irrigation was comparable to that of puddled, transplanted rice but required only half the irrigation water. Sub-surface drip irrigation also curtailed water losses from evapotranspiration and deep drainage, meaning this innovation coupled with conservation agriculture offers an ecologically viable alternative for sustainable rice production.

Given that yield gains through use of conservation agriculture in northern India are widespread but generally low, a nine-year study of rice-wheat cropping in the eastern Indo-Gangetic Plains applying the Environmental Policy Climate (EPIC) model, in this case combining data from long-term experiments with regionally gridded crop modeling, documented the need to tailor conservation agriculture flexibly to local circumstances, while building farmers’ capacity to test and adapt suitable conservation agriculture practices. The study found that rice-wheat productivity could increase as much as 38% under conservation agriculture, with optimal management.

Key partner organizations in this research include the following: Indian Council of Agricultural Research (ICAR); Central Soil Salinity Research Institute (CSSRI), Indian Agricultural Research Institute (IARI), Indian Institute of Farming Systems Research (IIFSR), Agriculture University, Kota; CCS Haryana Agricultural University, Hisar; Punjab Agricultural University, Ludhiana; Sri Karan Narendra Agriculture University, Jobner, Rajasthan; the Borlaug Institute for South Asia (BISA); the Trust for Advancement of Agricultural Sciences, Cornell University; Damanhour University, Damanhour, Egypt; UM6P, Ben Guerir, Morocco; the University of Aberdeen; the University of California, Davis; Wageningen University & Research; and IFDC.

Generous funding for the work cited comes from the Bill & Melinda Gates Foundation, The CGIAR Research Programs on Wheat Agri-Food Systems (WHEAT) and Climate Change, Agriculture and Food Security (CCAFS), supported by CGIAR Fund Donors and through bilateral funding agreements), The Indian Council of Agricultural Research (ICAR), and USAID.

Cover photo: A shortage of farm workers is driving the serious consideration by farmers and policymakers to replace traditional, labor-intensive puddled rice cropping (shown here), which leads to sizable methane emissions and profligate use of irrigation water, with the practice of growing rice in non-flooded soils, using conservation agriculture and drip irrigation practices. (Photo: P. Wall/CIMMYT)

Digital nutrient management tool reduces emissions, improves crop yields and boosts farmers’ profits

Written by Alison Doody on January 15, 2021. Posted in News.

A farmer in the Ara district, in India's Bihar state, applies NPK fertilizer, composed primarily of nitrogen, phosphorus and potassium. (Photo: Dakshinamurthy Vedachalam/CIMMYT) — A farmer in the Ara district, in India’s Bihar state, applies NPK fertilizer, composed primarily of nitrogen, phosphorus and potassium. (Photo: Dakshinamurthy Vedachalam/CIMMYT)

An international team of scientists, led by the International Maize and Wheat Improvement Center (CIMMYT), has demonstrated how better nutrient management using digital tools, such as the Nutrient Expert decision support tool, can boost rice and wheat productivity and increase farmers’ income while reducing chemical fertilizer use and greenhouse gas emissions.

Reported today in Nature Scientific Reports, the results show how the farmer-friendly digital nutrient management tool can play a key role in fighting climate change while closing the yield gap and boosting farmers’ profits.

The researchers tested the Nutrient Expert decision tool against typical farmer fertilization practices extensively using approximately 1600 side-by side comparison trials in rice and wheat fields across the Indo-Gangetic Plains of India.

The study found that Nutrient Expert-based recommendations lowered global warming potential by 12-20% in wheat and by around 2.5% in rice, compared to conventional farmers’ fertilization practices. Over 80% of farmers were also able to increase their crop yields and incomes using the tool.

Agriculture is the second largest contributor of greenhouse gas emissions in India. To tackle these emissions, crop scientists have been working on new ways to make farming more nutrient- and energy-efficient. Of the many technologies available, improving nutrient-use-efficiency through balanced fertilizer application — which in turn reduces excess fertilizer application — is key to ensuring food security while at the same time contributing to the UN’s Sustainable Development Goals on climate change.

The work was carried out by CIMMYT in collaboration with farmers, and funded by the CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS), the CGIAR Research Program on Wheat (WHEAT), and the Indian Council of Agricultural Research (ICAR). Scientists from the Borlaug Institute for South Asia (BISA), the International Rice Research Institute (IRRI), the Alliance of Bioversity International and CIAT, and the former International Plant Nutrition Institute (IPNI) also contributed to this study.

Researchers tested the Nutrient Expert decision tool against typical farmer fertilization practices extensively using approximately 1600 side-by side comparison trials in rice and wheat fields across the Indo-Gangetic Plains of India (Graphic: CIMMYT).

Precise recommendations

Nutrient Expert, which was launched back in 2013, works by analysing growing conditions, natural nutrients in the soil, and even leftover nutrients from previous crops to provide tailored fertilizer recommendations directly to farmers phones. The tool also complements the Government of India’s Soil Health Cards for balanced and precise nutrient recommendations in smallholder farmers’ fields.

Each farmer’s field is different, which is why blanket fertilizer recommendations aren’t always effective in producing better yields. By using nutrient management tools such as Nutrient Expert, farmers can obtain fertilizer recommendations specific to the conditions of their field as well as their economic resources and thus avoid under-fertilizing or over-fertilizing their fields.

“While efficient nutrient management in croplands is widely recognized as one of the solutions to addressing the global challenge of supporting food security in a growing global population while safeguarding planetary health, Nutrient Expert could be an important tool to implement such efficient nutrient management digitally under smallholder production systems,” said Tek Sapkota, CIMMYT climate scientist and first author of the study.

Sapkota also argues that adoption of the Nutrient Expert tool in rice-wheat systems of India alone could provide almost 14 million tonnes (Mt) of extra grain with 1.4 Mt less nitrogen fertilizer use, and a reduction of 5.3 Mt of carbon (CO2) emissions per year over current practices.

However, technological innovation alone will not achieve these positive outcomes.

“Given the magnitude of potential implications in terms of increasing yield, reducing fertilizer consumption and greenhouse gas emissions, governments need to scale-out Nutrient Expert-based fertilizer management through proper policy and institutional arrangements, especially for making efficient use of the nearly 200 million Soil Health Cards that were issued to farmers as part of the Soil Health mission of the Government of India,” said ML Jat, CIMMYT principal scientist and co-author of the study.

Read the study:
Crop nutrient management using Nutrient Expert improves yield, increases farmers’ income and reduces greenhouse gas emissions.