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Malik, R.

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Malik
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Malik, R.

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Now showing 1 - 6 of 6
  • Influence of conservation agriculture-based production systems on bacterial diversity and soil quality in rice-wheat-greengram cropping system in eastern Indo-Gangetic Plains of India
    (Frontiers Media S.A., 2023) Kumar, R.; Choudhary, J.S.; Naik, S.K.; Mondal, S.; Mishra, J.S.; Poonia, S. P.; Saurabh, K.; Hansraj Hans; Kumar, S.; Das, A.; Kumar, V.; Bhatt, B.P.; Chaudhari, S.K.; Malik, R.; Craufurd, P.; Mcdonald, A.; Sherpa, Sonam
    Publication
  • Understanding decision processes in becoming a fee-for-hire service provider: a case study on direct seeded rice in Bihar, India
    (Elsevier, 2021) Brown, B.; Samaddar, A.; Singh, K.; Leipzig, A.; Anurag Kumar; Kumar, Pankaj; Singh, D.K.; Malik, R.; Craufurd, P.; Kumar, V.; Mcdonald, A.
    Publication
  • Potential of conservation agriculture modules for energy conservation and sustainability of rice-based production systems of Indo-Gangetic Plain region
    (Springer, 2021) Nandan, R.; Poonia, S. P.; Sati Shankar Singh; Chaitanya Prasad Nath; Kumar, V.; Malik, R.; Mcdonald, A.; Hazra, K.K.
    Publication
  • The conservation agriculture roadmap for India: policy brief
    (ICAR, 2018) Jat, M.L.; Biswas, A.K.; Pathak, H.; Mcdonald, A.; Patra, A.K.; Acharya, C.B.; Sharma, P.C.; Chaudhari, S.K.; Singh, R.; Bhaskar, S.; Sharma, R.; Jat, H.S.; Agarwal, T.; Gathala, M.K.; Pal, S.; Sidhu, H.S.; Yadvinder-Singh; Chhokar, R.S.; Keil, A.; Saharawat, Y.S.; Jat, R.K.; Singh, B.; Malik, R.; Sharma, A.R.; Parihar, C.M.; Das, T.K.; Singh, V.K.; Jat, S.L.; Jha, B.K.; Pratibha, M.; Singh, P.; Singh, R.C.; Choudhary, O.P.; Sharma, S.; Satyanarayana, T.; Sidhu, B.S.; Gehlawat, S.K.; Sen, S.K.; Singh, A.K.; Sikka, A.K.
    Agriculture remains central to the Indian economy, providing livelihood to the majority of its population. Though Indian agriculture have made spectacular progress for food self-sufficiency, yet growing challenges of large management yield gaps, low water and nutrient efficiency, imbalance and inadequate use of external production inputs, diminishing farm profits, deterioration of soil health and environmental quality coupled with climate risks are major concerns. Feeding a growing population with increasing dietary preferences for resource-intensive food products is a major challenge. Moreover, with no scope for horizontal expansion of farming to produce needed food; improving agronomic productivity and achieving high and stable yields under changing and uncertain climate are important for feeding the growing population. Increasing climatic variability affects most of the biological, physical and chemical processes that drive productivity of agricultural systems. The productivity and stability of agricultural systems depends upon measurable factors and processes controlled by climate and non-climate drivers of production paradigm. It is therefore vitally important to develop strategies and practices to sustainably increase food production while increasing farm income, protecting natural resources and minimizing environmental footprints.
    Publication
  • Evaluation of long-term conservation agriculture and crop intensification in rice-wheat rotation of Indo-Gangetic Plains of South Asia: carbon dynamics and productivity
    (Elsevier, 2017) Samal, S. K.; Rao, K.K.; Poonia, S. P.; Kumar, R.; Mishra, J.S.; Prakash, V.; Mondal, S.; Dwivedi, S.K.; Bhatt, B. P.; Naik, S.K.; Choubey, A. K.; Kumar, V.; Malik, R.; Mcdonald, A.
    In the context of deteriorating soil health, stagnation of yield in rice-wheat cropping system (RWCS) across Indo- Gangetic plains (IGP) and environmental pollution, a long term field experiment was conducted during 2009–2016 taking four crop scenarios with conservation agriculture (CA), crop intensification and diversified cropping as intervening technology aiming to evaluate the sustainability of the systems. Scenario 1 (S1) represented conventional farmers’ practice of growing rice and wheat with summer fallow. In scenario 2 (S2) and scenario 3 (S3), legume crop was taken along with rice and wheat with partial CA and full CA, respectively. Conventional RWCS was replaced with rice-potato + maize- cowpea cropping system with partial CA in scenario 4 (S4). The S3 scenario registered highest total organic carbon (TOC) stock of 47.71 Mg C ha−1 and resulted in significant increase of 14.57% over S1 (Farmer’s practice) in 0–30 cm soil depth after 7 years of field trial. The S4 scenario having intensified cropping systems recorded lowest TOC of 39.33 Mg C ha−1 and resulted in significant depletion of 17.56% in C stock with respect to S3 in 0–30 cm soil depth. The TOC enrichment was higher in S2, S3 and S4 scenario in the surface soil (0–10 cm) compared to S1. At lower depth (20–30 cm), the TOC enrichment was significantly higher in S2 (12.82 Mg C ha−1) and S3 (13.10 Mg C ha−1 soil) over S1 scenario. The S2 and S3 scenario recorded highest increased allocation of TOC (3.55 and 6.13 Mg C ha−1) to passive pool over S1. The S2 (15.72 t ha−1), S3 (16.08 t ha−1) and S4 (16.39 t ha−1) scenarios recorded significantly higher system rice equivalent yield over S1 (10.30 t ha−1). Among the scenarios, S3 scenario had greater amount of total soil organic carbon, passive pool of carbon and higher system rice equivalent yield, thus, is considered the best cropping management practice to maintain soil health and food security in the middle IGP.
    Publication
  • Regional dialogue on conservation agriculture on South Asia: proceedings and recommendations
    (CIMMYT, 2011) Jat, M.L.; Malik, R.; Saharawat, Y.S.; Gupta, R.K.; Mal, B.; Paroda, R.S.
    South Asia accounts for less than 2% of the world’s total land area and 14 % of the global agricultural land. However, about 94% of the agriculturally suitable area is already under cultivation with almost no scope for further horizontal expansion of agriculture. There has been a tremendous shift in the production variables of modern farming over traditional farming. Even then, most of the agronomic works revolved around tillage and labour intensive farming. Declining soil organic carbon (SOC) status of soils has been the main shift in agriculture from ‘traditional animal based subsistence’ to ‘intensive chemical and tractor based’ agriculture that multiplied problems associated with sustainability of natural resources. The SOC concentration in most cultivated soils of South Asia is less than 5 g/kg compared with 15-20 g/kg in uncultivated virgin soils, attributed to intensive tillage, removal/burning of crop residue and mining of soil fertility. Large acreage of cultivated lands shows fertility fatigue and multiple nutrients deficiency in many intensively cropped areas. This adds to our challenge of making farming more profitable and sustainable. Hence, the current and future food security of South Asian countries has twin challenges of resource fatigue and decelerating productivity growth of food grain crops. These challenges are being further exacerbated with the sharp rise in the cost of food and energy, depleting water resources, vulnerability of soil to degradation, indiscriminate and imbalanced use of external production inputs and overarching effects of changing climate. This has and will further lead to lower farm profit, making farming unattractive and unsustainable. The efficiency and sustainability of a production system depends on system-based management optimization of crop yields, economic benefits, and environmental impacts. Therefore, vertical improvement through development and deployment of tools and techniques aiming at increasing agricultural production and arresting degradation of soil, water and environment and their rational use are essential to satisfy future food demand in the region and to meet the Millennium Development Goals (MDGs). To bring a paradigm shift in agriculture, National Agricultural Research Systems (NARS), the FAO of the United Nations and CGIAR Centers have accepted conservation agriculture (CA) as a vehicle for change. No-till agriculture together with other associated management practices such as direct seeding into loose crop residues to provide soil cover and to conserve soil moisture, judicious choice of crop rotations and agroforestry tree species constitutes conservation agriculture (CA). CA based crop management practices have proved to be effective to produce more at less costs, reduce environmental pollution, promote conjunctive use of organics (avoids residue burning), improve soil health and promote timeliness of planting and other farm operations to address issues relating to terminal heat stress in the region. Like any other tillage and crop establishment technology, it may not be a panacea for all present day ills, but has proven to bring out south American Agriculture out of its stagnant state almost 20 years ago, skyrocketing the cereals and oilseed production system. Same is the case for regional CA networks in different continents/sub-continents. CA is being widely accepted as an important component of the overall strategy for enhancing productivity, improving the environment and conserving natural resources for food security and alleviating poverty in such areas. Thus, for addressing the issues of resource fatigue and bridging management yield gaps, in South Asia, Conservation agriculture based management solutions can prove to be the cornerstone. In South Asia, no-till systems were introduced during mid 1990s by the International Maize and Wheat Improvement Center (CIMMYT) in close collaboration with regional NARES primarily to grow wheat in ricewheat system. The CA program was later facilitated by the strong presence of Rice-Wheat Consortium (RWC) for the Indo-Gangetic Plains led by the regional NARS and convened by CIMMYT. It led to a steady rise in the acreage of CA based resource conserving technologies in India, Pakistan, and Nepal and to some extent in Bangladesh. RWC reported a total coverage of nearly 3 m ha under CA based resource conserving technologies in South Asia by 2007 benefiting hundreds of thousand farmers directly to the extent of nearly US$ 150 million. This has been possible through regional learnings and information sharing for development of light weight, low cost multi-crop ferti-seed planters through building capacity of local manufacturers. However, in the past few years, there has been a slowdown in the adoption of zero-till systems in the region. This has been due to several reasons including blanket and commodity crop based recommendations, farmers’ access to location specific and timely information and policy mismatches in prioritization of investments but the most important one is the lack of common platform for regional learnings and information sharing. It is fairly well understand that dissemination or extension of new technologies in general and CA in particular is a complex issue. Very often than not the scientists, having developed and tested the technologies, are not able to transfer these to the farmers widely. Why farmer is not ready to adopt the new technologies is an issue that haunts the planners and scientists alike. Farmers today need value chain information (production, protection, inputs and services) on region-specific technologies. These region specific technologies and innovations are in advanced stages of experimentation in farmers’ fields. However, the lack of a regional common platform for sharing this information and capacity building are the major deterrent in accelerating the pace of adoption of CA in South Asia. Therefore, the agricultural science, extension and development leaders, key researchers of South Asian National Agricultural Research and Extension System (NARES), CGIAR Centers in the region, Food and Agriculture Organization of the United Nations (FAO), United States Agency for International Development (USAID), innovators, Non-Government Organizations (NGOs), and farmer associations met on 1-2 November, 2011 at New Delhi, India for a dialogue on ‘Conservation Agriculture in South Asia’. The dialogue focused on Conservation Agricultural Research for Development (CAR4D) through innovations for greater impacts on smallholder farmers in the region was organized jointly by Asia-Pacific Association of Agricultural Research Institutions (APAARI), International Maize and Wheat Improvement Center (CIMMYT) and Indian Council of Agricultural Research (ICAR). The dialogue was structured in four sessions: i) status of conservation agriculture in the region, ii) initiatives of CG Centers on CA in South Asia, iii) focused discussion through break-out groups on (a) out-scaling for impact, (b) partnerships for regional cooperation, (c) capacity building, and (iv) research and development needs on CA in South Asia. The status reports of different countries were presented by the respective RW coordinators of regional NARS and the progress of CA initiatives by the key CG Centers in the region (CIMMYT, IRRI, IFPRI, ILRI, ICRISAT) as well as other international programs in Central Asia were presented by the respective lead scientists of these organizations. All presentations were followed by in-depth discussions. This report provides the outcomes of deliberations and key recommendations for implementation by the scientific community and policy planners.
    Publication