A compendium of Technologies, Practices, Services and Policies for Scaling Climate Smart Agriculture in Odisha (India)

Stakeholders engaged in agricultural research for development (AR4D) are increasingly tackling risks associated with climate change in smallholder systems. Accordingly, development and scaling of climate-smart agriculture (CSA) are one of the priorities for all the organizations, departments and ministries associated with the farm sector. Having a ‘one-stop-shop’ compiled in the format of a compendium for CSA technologies, practices and services would therefore serve a guide for all the stakeholders for scaling CSA in smallholder systems. Bringing out a Compendium on Climate-Smart Agriculture (CSA) for Odisha, India was therefore thought of during the workshop on ‘Scaling Climate-Smart Agriculture in Odisha’ organized at Bhubaneswar on 18-19 July 2018 by International Rice Research Institute (IRRI) in collaboration with Department of Agriculture (DoA) & Farmers’ Empowerment, Indian Council of Agricultural Research-National Rice Research Institute (ICAR-NRRI), Orissa University of Agriculture and Technology (OUAT) & International Maize and Wheat Improvement Center (CIMMYT) under the aegis of CGIAR Research program on Climate Change, Agriculture and Food Security (CCAFS). The main objectives to bring forth this compendium are: to argue the case for agriculture policies and practices that are climate-smart; to raise awareness of what can be done to make agriculture policies and practices climatesmart; and to provide practical guidance and recommendations that are well referenced and, wherever possible, based on lessons learned from practical action. CSA programmes are unlikely to be effective unless their implementation is supported by sound policies and institutions. It is therefore important to enhance institutional capacities in order to implement and replicate CSA strategies. Institutions are vital to agricultural development as well as the realisation of resilient livelihoods.They are not only a tool for farmers and decision-makers, but are also the main conduit through which CSA practices can be scaled up and sustained. The focus in this compendium is on CSA and it’s relevant aspects, i.e., (i) technologies and practices, (ii) services, (iii) technology targeting, (iv) business models, (v) capacity building, and (vi) policies. The approaches and tools available in the compendium span from face-to-face technicianfarmer dialogues to more structured exchanges of online and offline e-learning. In every scenario it is clear that tailoring to local expectations and needs is key. In particular, the voice of farmers is essential to be captured as they are the key actors to promote sustainable agriculture, and their issues need to be prioritized. CSA practices are expected to sustainably increase productivity and resilience (adaptation), reduce Greenhouse Gases (mitigation), and enhance achievement of national food security along with sustainable development goals. CSA is widely expected to contribute towards achieving these objectives and enhance climate change adaptation. CSA practices have to be included in State’s Climate Policy as a priority intervention as the state steps up efforts to tackle climate change. Furthermore, emphasis shoud be laid on CSA training for a sustainable mode to enhance CSA adoption in the state hence the relevance of developing this document. The adaption of climate related knowledge, technologies and practices to local conditions, promoting joint learning by farmers, researchers, rural advisor and widely disseminating CSA practices, is critical. This compendium brings together a collection of experiences from different stakeholders with background of agricultural extension and rural advisory services in supporting CSA. The contributions are not intended to be state-of-the art academic articles but thought and discussion pieces of work in progress. The compendium itself is a ‘living‘ document which is intended to be revised periodically

Improving water productivity, reducing poverty and enhancing equity in mixed crop-livestock systems in the Indo-Gangetic Basin: CPWF project report 68

Farming systems / Mixed farming / Water productivity / Feed production / Livestock / Energy consumption / Gender / Poverty / River basins / Case studies / India / Indo-Gangetic Basin / West Bengal / Haryana / Uttar Pradesh

Agroforestry Opportunities for Enhancing Resilience to Climate Change in Rainfed Areas,

Not AvailableAgroforestry provides a unique opportunity to achieve the objectives of enhancing the productivity and improving the soil quality. Tree systems can also play an important role towards adapting to the climate variability and important carbon sinks which helps to decrease the pressure on natural forests. Realizing the importance of the agroforestry in meeting the twin objectives of mitigation and adaptation to climate change as well as making rainfed agriculture more climate resilient, the ICAR-CRIDA has taken up the challenge in pursuance of National Agroforestry Policy 2014, in preparing a book on Agroforestry Opportunities for Enhancing Resilience to Climate Change in Rainfed Areas at ICAR-CRIDA to sharpen the skills of all stakeholders at national, state and district level in rainfed areas to increase agricultural productivity in response to climate changeNot Availabl

Annual Report 2017-18

Not AvailableI am extremely happy and privileged to present the annual report of ICAR-CRIDA for the year 2017- 18. During the reporting year, ICAR-CRIDA has made eloquent progress in technology development and dissemination associated with climate change in rainfed agriculture and dealing contingencies in agriculture and allied sector. The institute has received copyright for “Unreaped yield potentials in major rainfed crops and scope for bridging yield gaps - A decision support system”. ICAR-CRIDA along with SAUs and KVKs prepared contingency plans at district level for all the 126 agro-climatic zones of the country (623 districts) to deal with weather related aberrations. An IFS module with cotton, vegetables, fodder and small ruminants with farm pond using portable raingun at Chenchu tribal farmer field implemented in Petrallachenu village of Nagarkurnool district showed positive impact on socio economic condition of the farmer with total net income of Rs. 96,605/- over the traditional system of growing only rainfed cotton, which gave negative returns of Rs. (-) 3600. A small scale solar powered micro-irrigation system was designed and installed for small farmers having one acre or less land under farm pond system for growing vegetables. The assessment based on daily rainfall dataset, annual average effective rainfall and runoff percentages helped in developing the expected runoff in various rainfall zones, which could be used to estimate the runoff in meso-scale watersheds. Seven inbreds of maize (DTL2, SNJ2011- 03, SNJ2011-37, SNJ2011-26, Z101-15, Z32-12 and HKI7660) were found to be promising for use in crop improvement programme under rainfed conditions. 4:4 strip intercropping system of sorghum and pigeonpea with relay horse gram performed better compared to traditional 2:1 intercropping system. In a study on resource conserving technologies, conventional tillage recorded 15% lower maize yields as compared to conservation agriculture practices. Intensive system of rearing livestock not only improved the profitability but also significantly reduced methane emissions as compared to semi-intensive and extensive systems. Heat Load Index (HLI) and Temperature Humidity Index (THI) was found to be better choice for comparing heat stress in extensively and intensively reared sheep, respectively. A rotary implement for weeding operation was developed to effectively utilize low horse power tractor for field applications. A raised bed planter cum herbicide applicator was developed and the design was transferred to Avanthi Bufa Industries Ltd., Jahirabad. Farmers’ first project, envisaged to transfer rainfed technologies with objective of doubling farmers income is being implemented in 4 villages of Pudur mandal of Vikarabad district. Among 12 pigeonpea genotypes AKT-8811, PUSA-33, GRG-276-1 and RVK-274 were the high yielders in both unstressed and rainfed conditions. An econometric analysis of impact of climate change on crop yields showed that the impacts would be more severe and widespread towards the end of the century. Under changing climatic scenarios, runoff is not expected to vary much in Vijayapura district under low or medium emission scenarios, but the high runoff potential available under the present scenario itself shows substantial scope for rainwater harvesting and its utilization for supplemental irrigation. Decreased grub duration with increased predation capacity of M. sexmaculatus on A. craccivora with elevated CO2 indicated increased predation in future climate change scenarios. For assessing the real time climate change impacts on crop water requirements, SCADA Preface based rainfall simulator and precision lysimeter was designed and developed by using state of art process automation instrumentation in climate change research complex at Hayathnagar. Rotavator, cultivator and disc plough + harrow recorded higher GHG emissions and global warming potential, whereas animal drawn implements recorded lower emissions. Evaluation of the performance of different crops under organic, inorganic and integrated production systems showed that yield of sunflower was 14 and 7% higher under integrated management (1374 kg/ha) than that of under inorganic and organic management, respectively. Supplementation of chromium propionate @ 200 ppb can help in mitigation of heat stress in grazing lambs. An experiment to evaluate 36 elite clones of short rotation and high biomass yielding multipurpose tree species (M. dhubia, Casuarina, B. balcoa, D. sisoo and Eucalyptus) was established at Hayathnagar Research Farm. The KVK under technology assessment and refinement has assessed 17 technologies through 115 trials on crop varieties, integrated crop management, horticulture and livestock management. 269 Frontline demonstrations on 19 technologies were conducted in different disciplines. It also organized 115 need based and skill oriented training programmes on various aspects of improved technologies to 3005 clientele farmers and filed level extension workers. Two special skill development programmes allotted by Department of Horticulture, Government of Telangana in the disciplines of “ farm pond construction and lining” were organized for 520 rural youths. Exemplary performance of its scientists were visible as two scientists attended trainings/exposure visit outside the country and 52 graduate and post graduate students carried out research work at ICAR-CRIDA. Sustained performance of its scientists were exhibited in terms of 20 scientists of Institute receiving several awards, fellowships, copyright and recognition from national academies, professional societies and other institutions. The scientists of the institute published a total of 116 research articles in international and national journals, 29 books/bulletins including 2 in Hindi and 112 book chapters. The contributions of scientists also appeared in the form of a number of policy papers, bulletins, popular articles, presentations in conferences, e-publications and radio and television programmes. The collaborations with several Ministries and Departments, SAUs, NGOs and Private Industries reflect its commitment to work hand-to-hand with grow together and finding the technological solutions to the problems of farmers in rainfed regions of India. I would like to place on record my sincere gratitude to Indian Council of Agricultural Research for its continued guidance and support. I appreciate all the committee members of annual report for their timely compilation and shaping this report in time.Not Availabl

Second-generation Biofuel Potential in India: Sustainability and Cost Considerations

This study is part of a larger research project on "Promoting Low-Carbon Transport in India", a major initiative of the United Nations Environment Programme (UNEP), hereafter referred to as the Low Carbon Transport (LCT) project in this document. The overall context in which the LCT project has been undertaken is the critical role of the transport sector in reducing greenhouse gas (GHG) emissions. India is currently the fourth largest GHG emitter in the world, although its per capita emissions are less than half the world's average. Furthermore, India's transport sector accounts for 13 percent of the country's energy related CO2 emissions. It is evident that opportunities exist to make India's transport growth more sustainable by aligning development and climate change agendas. At present, India is pursuing a comprehensive set of policies to move the country to a low-carbon growth path. In 2009, India announced that it would reduce the emissions intensity of its gross domestic product (GDP) by 20 percent to 25 percent over the 2005 levels by the year 2020. Specific measures to attain these goals are also being developed through the national missions identified in the National Action Plan on Climate Change (NAPCC) of 2008. The NAPCC recognises that GHG emissions from transport can be reduced by adopting a sustainability approach through a combination of measures such as increased use of public transport, higher penetration of bio-fuels, and enhanced energy efficiency of transport vehicles