Preface Agriculture is the lifeline of India as being central to food security, nutritional security, poverty alleviation, socio-economic stability and sustainable development. Though contribution to nation’s GDP is 18% yet agriculture is the major profession providing employment to more than 58% households in rural India. Indian agriculture is vibrant, responding and gigantic enterprise with annual production of 285 million tons of food grains, 181 million tons of vegetables, 115 million tons of fruits, 25.3 million tons of pulses, 174 million tons of fresh milk, 74 billion of poultry eggs and 11.5 million tons of fish. Inspite of this, nutritional security to many and food security to 115 millions, targets of higher livestock and crop productivity, consumers’demand for innovative agri-products and export orientation are yet to be achieved. This advocates factorial analysis of agriculture and renovations and reforms in earlier and present recommendations. Major factors impacting Indian agriculture comprise weather parameters, monsoon, irrigation patterns, crop and livestock nutrition, government policy (federal as well as state), commodity prices (global, national as well as local) and consumers’ preferences. The predictability as well as modeling of risks on abovementioned factors, is a herculean task. In fact, the number of factors impacting the viability of agriculture sector, as well as the volatility in the magnitude of these factors is increasing and thus, the sector requires integrated transformation for sustainable development and stable food security. The Indian agriculture sector is witnessing a massive transformation because of technological interventions and governmental initiatives. In the past three consecutive budgets, the agriculture sector has received special attention but this time the focus of the Indian Union Budget is on agribusiness and “agri-value” addition. In the Indian Union Budget 2018-19, the government has allocated Rs. 14.5 lakh crores ($222.4 billion) for the rural development and agriculture sector. Indian government has set a target to double farmers’ income by 2022. Indian finance minister has announced a number of initiatives, keeping the recommendations of the Doubling Farmers’ Income committee in mind, for example the decision to keep MSP (Minimum Support Price) for crops at least at one and- half times of their production cost. For those farmers who are not in a position to directly transact at APMCs (Agriculture Produce Market Committees) and other wholesale markets, the government has decided to develop and upgrade existing 22,000 rural haats into Gramin Agricultural Markets (GrAMs). These GrAMs will be electronically linked to e-NAM (Electronic National Agricultural Market, an online platform) to provide farmers with a facility to sell their produce directly to consumers. The government has launched with allocation Rs. 2600 crore ($360.8m.) Pradhan Mantri Krishi Sinchai Yojana, a national mission to improve farm productivity and ensure better utilization of the resources in the country, in 96 irrigation- deprived districts. In words of Indian Finance Minister “We consider agriculture to be an enterprise and want to help farmers produce more from the same land parcel at less cost, and simultaneously to realize higher prices for their produce”. To address the challenge of price volatility of perishable agricultural commodities, the finance minister has proposed launching a scheme called “Operation Greens.” This scheme will help bring farmers closer to the marketplace through better logistics, processing facilities and professional management. A sum of Rs. 500 crore ($75.2 million) is allocated for this purpose. Hence, a shift from agriculture to agripreneurship and agribusiness is the focus to revitalize Indian agriculture so that it becomes more receptive and remunerative venture for youths that has the potential to contribute to a range of social and economic developments such as employment generation, women empowerment, income generation, poverty reduction and improvements in nutrition, health and overall food security in the national economy. Nearly 40 crore women out of the total of 60 crore female population depend upon crop and animal husbandry, fisheries, forestry, agro-processing and agri-business for their livelihood. Moreover, agripreneurship ventures are seen to have a potential to promote job-led economic growth in rural areas by harnessing technologies for environmentally sustainable and socially equitable development which can provide a decent livelihood to women as well. Considering the existing scenario that two-thirds of the Indian population is employed in agriculture sector, agripreneurship and agribusiness stand out as imperatives for sustainable development and employment generation in the country. With this contention in mind, an attempt has been made through this volume entitled “Integrated Transformation of Agriculture with Special reference to India” to narrow down on the challenges related to agricultural transformation in India. Technological amalgamations required to upgrade agriculture to commercial form. Strategical deployment of innovations to transform agriculture into an attractive and profitable venture. In all, there are 23 chapters first one describes the bottlenecks and gaps in the form of challenges that one needs to know while thinking of futuristic plans. Chapter 2nd elaborates technologies that brought green revolution while third one focuses on technologies that deserve priority if transformation in agriculture is desired. In view of small holdings, contract farming is important which is enumerated in chapter 4. Due emphasis is placed on livestock farming through zoonotic diseases control, strategic parasite management and dairying at chapters 5, 8 and 15. Innovative approaches like ICTs interventions, climate smart agriculture, seed priming, biochar, organic agriculture and integrated farming system are appropriately dealt in chapter no 6, 7, 10, 13, 14 and 17. Horticulture and marketing aspects are covered in chapter no 11, 12 and 9 and hi-tech agronomy in chapter no 22. Weather forecasting, remote sensing and agro-advisory relevance is discussed in chapter no 16 and 18. Last chapter but not the least, is on organic agriculture as an entrepreneurship for women empowerment and socio-economic transformation which discusses the compatibility and suitability of organic agriculture to women entrepreneurs. I am thankful to the scientists, teachers and my professional colleagues who took pain to contribute to this volume and solicit their cooperation in future, too. From the core of my heart, I acknowledge the various internet sites, international and national institutes, Govt. organizations, social sites, scholars and farmers whose information has been used to develop this volume. The sole purpose of this task has been academic, social and reference book for policy makers. I don’t claim the exclusiveness of the information but surely way and form of the compilation and presentation is maiden. This will be useful to scientists, teachers and scholars as a reference book on Indian Agriculture while it will act as a source book for field functionaries for plethora of new technologies fit for project development and field implementation. I am obliged to the Executive Body of SIDAVES (Society for Integrated Development of Agriculture, Veterinary and Ecological Sciences, J&K, India), Dr Vikas Sharma, Dr Narinder Panotra, Dr AP Singh and Dr Neelesh Sharma for entrusting me the responsibility of editing this volume. I owe thanks to my wife Mrs Kusam Lata for her support and inspire me to take this kind of venture. A word of appreciation is must for my son Vishaw Vikas, daughter Sabhyata Sharma and daughter-in-law Aarushi Singh Sharma who have been always amicable, cooperative and supportive to me during long busy hours with this assignment. Special thanks and gratitude my gurus Sh OP Pushap, Jammu, Prof HS Chawla, Pantnagar, Prof SC Mani, Pantnagar, Prof BB Mukerjee, Bose Institute, Kolkatta who motivated and instilled in me the sentiments for service to the social and academic societies.

Abstract India today has 1.30 billion people and would be the world’s most populous country by 2025. The challenge is how to feed India’s growing population with rising income, but limited land and water resources. Whereas area under crop cultivation has come down from 142 million ha to 138 million ha, asking for protecting the arable lands from mass urbanization and more productivity per unit area. The agricultural production systems are still operating at low productivity and high uncertainty in the country. There is little or no alignment between production, the growth of agricultural commodities in the market and the supply of these commodities. All this leading to considerable farm produce wastage, mounting tremendous pressure on natural resources and would pose a challenge to the country in providing food, water, health, shelter, sanitation and jobs to all. While industry and services have grown, agricultural sector has lagged behind. Information technology sector is growing consistently at 30 per cent every year but agriculture has not even achieved 4 per cent growth. The contribution of agricultural sector to national Gross Domestic Product (GDP) has continued to decline over the years; has shrunk from 55 per cent in 1951-52 to 14.6 per cent in 2015-16. Land fragmentation, reducing holding size, obscure marketing prospects, low water and inputs use efficiencies, modest level of mechanization, unorganization, unreliable returns from rainfed areas, inadequate storage infrastructure, weak processing sector and meagre investments continue to leave visible impressions on Indian agriculture. Nonetheless, agriculture remains a major source of employment, absorbing about 52 per cent of the total national workforce. Higher levels of investments in agriculture, both by the public and private sector can yield much better results if the reforms are undertaken to streamline not only the incentive structures for the farmers, but also the institutional framework to address the issues of integration, export orientation, infrastructure development, and information technology and management to achieve the objective of a innovative agricultural sector capable of providing food security to all. Farmer insecurity about crop failure also prevents them from adopting changes. A balance between risk and reward is considered to be an important economic factor for enhancing relationships. Trust among channel partners, power share and interdependence are other important factors for enhancing relationships in the supply chain system.

Abstract Indian agriculture witnessed a transformation in early seventies with green revolution in cereals. The Green Revolution resulted in a record grain output of 131 million tons in 1978-79. Yield per unit of farmland improved by more than 30 per cent between 1947 and 1979. This was because of introduction of high yielding varieties and use of agro-chemicals, particularly synthetic fertilizers. Farmers realized 3-4 times increment in their profit when high yielding varieties and chemical fertilizers were used in integration. Agriculture is the primary source of livelihood for about 58 per cent of India’s population. Gross Value Added by agriculture, forestry and fishing is estimated at Rs 17.67 trillion (US$ 274.23 billion) in FY18. The Indian food industry is poised for huge growth, increasing its contribution to world food trade every year due to its immense potential for value addition, particularly within the food processing industry. Food & Grocery retail market in India was worth US$ 380 billion in 2017, is the world’s sixth largest, with retail contributing 70 per cent of the sales. The Indian food processing industry accounts for 32 per cent of the country’s total food market, one of the largest industries in India and is ranked fifth in terms of production, consumption, export and expected growth. It contributes around 8.80 and 8.39 per cent of Gross Value Added (GVA) in Manufacturing and Agriculture respectively, 13 per cent of India’s exports and six per cent of total industrial investment. During 2017-18, food grain production is estimated at 279.51 million tons, with rice and wheat production in the country at 111.52 MT and 98.61 MT, respectively in the same period. Milk production stands at 165.4 million tons during FY17, while meat production is 7.4 million tons. India is the second largest fruit producer in the world. Production of horticulture crops is estimated at record 307.16 million tons (mt) in 2017-18 as per second advance estimates. Total agricultural exports from India grew at a CAGR of 16.45 per cent over FY10-18 to reach US$ 38.21 billion in FY18. In April-May 2018 agriculture exports were US$ 6.43 billion. India is the largest producer, consumer and exporter of spices and spice products. Spice exports from India reached US$ 3.1 billion in 2017-18. Tea exports from India reached a 36 year high of 240.68 million kgs in CY 2017 while coffee exports reached record 395,000 tons in 2017-18.

Abstract With its core intention to raise economic status of farmers, Govt of India vows for transformation in agriculture and sets goal to double farmers’ income by 2022. Nonetheless, net income increase at the farm is amalgamation of technologies, tactics and government policies. Farmers realized 3-4 times increment in their profit during era of green revolution when high yielding varieties and chemical fertilizers were introduced in early seventies. Subsequently income enhancement of the farmers continued through raising of farm productivity per unit area and entrepreneurship. Thus Indian agriculture experienced transformation through chemical fertilizers, high yielding varieties, synthetic pesticides, off-season cultivation, high yielding breeds, export orientation and entrepreneurship development in food processing, mushroom production, dairying and poultry. With the result, India emerged as top producer of milk, millets, pomegranate, banana, mango, jute, pulses, okra, safflower etc and second top producer of wheat, rice, tea, tomato, potato, onion etc and third in egg production and fourth in poultry meat. Consequence was evolution of commercial farming from subsistence farming. In era of globalization and increased purchase power of consumers, profitability at the farm has become subject of competitiveness, quality and consumer preference. Price shoot-up and market crashing of commodities in the country has made agriculture, a profession of risk, uncertainties and unpredictability. It has thus, lost creditability of socioeconomic security. To make it remunerative and attractive, a combo plan of transformational technologies that has the competence to break production and productivity barriers and can also address market needs as well as consumer preferences is highly wanted. There is urgent need to infuse characteristic of market orientation in agriculture through marketing information system and promoting demand driven production system with focus on zonalization of crops taking advantage of niche area or geographical indications. Commodity supply must remain high through promotion of climate resilient varieties or breeds, mechanization, adoption of hi-tech crop and livestock management practices. All this has to be made sustainable by way of produce and product diversification through integrated farming system, organic agriculture and secondary agriculture. Considering future vision, research initiatives must continue on noble areas like vertical farming and in vitro farming. Information and communication technologies will open avenue for assured marketing by linking production to consumption system via proper marketing and distribution leading to increased farm profitability. This as a whole will make transformation in agriculture a reality.

Abstract Indian agriculture is undergoing rapid transformation and agricultural-based food industry in India requires timely and adequate supply of good quality raw material for processing, value addition and export. The recent growth and diversification of consumer demand and the expansion of organized agricultural processing and marketing ventures in India has the potential to boost the market opportunities, productivity, and incomes of farmers, including that of marginal and small holders. However, achieving these goals will likely require creation of new institutions and innovations to develop supply chains and facilitate linkages between farmers, wholesalers, processors, and retailers. Among these institutions and innovations are various models of contract farming, including those led by cooperatives, by farmer groups, and by various types of private sector resource intermediation that develop backward linkages to growers. Contract farming is a system where agricultural production is carried out according to an agreement between a buyer and farmers, which establishes conditions for the production and marketing of a farm product or products. In other words Contract Farming is a system of production and supply of agricultural/horticultural produce under forward contracts between producers/ suppliers and buyers. The essence of such an arrangement is the commitment of the producer to provide an agricultural commodity of a certain type, at a time and a price, and in a quantity required by a known and committed buyer. Well-managed contract farming is an effective approach to help solve many of the market linkage and access problems of small and marginal farmers which constitute 86% of the farming households in India. This chapter examines growth and status including the performance of different models of contract farming based on empirical studies. It concludes that by entering into the contractual arrangement, the income level of the farmer and employment level in the rural economy has increased despite certain problems faced by the farmers like delayed payment, delay in procurement and low supply of agricultural inputs to them.

Abstract The global economic burden due to zoonotic diseases is very high. According to a recent World Bank estimate, the economic burden due to six of the zoonotic diseases that have occurred in specific countries between 1997 and 2009 is estimated to be US$80 billion. In a worst-case scenario, potential losses from a pandemic influenza outbreak could be US$3 trillion, which is equivalent to 5% of the global GDP. Zoonotic diseases continue to represent an important health hazard in most parts of the world. More than 200 zoonotic diseases have been described, caused by bacteria, parasites, viruses, fungi and unconventional agents (e.g. prions). About 75 percent of the new diseases that have affected humans over the past ten years are caused by pathogens originating from animals or from products of animal origin. Many of these diseases have the potential to spread by various means over long distances and to become global problems. India contributes to substantial portion of the global burden of endemic zoonoses and is one of the several ‘EID hotspots’. The quality and safety of food supplies are put at risk by demands for more, cheaper food, driven by growing population and increasing urbanization, combined with a lack of resources to deal with issues related to food safety and lower or less rigorously enforced regulatory standards add to spread of zoonotic diseases. Human and financial resources that are dedicated by national authorities to the support of regulatory and non-regulatory food safety programs generally fall well short of needs. Commonly, many of the resources available are used for quality control of food for export, rather than products for domestic consumption, leaving the domestic market more vulnerable to unacceptable levels of food safety hazards, thus adding to the problem. In many developing countries, there is a substantial informal market that generally escapes any food safety controls. The successful control of zoonoses is possible if acceptable standards of life and social welfare are observed in developing country like India. Close cooperation and interaction between veterinarians, health physicians and public health operators, agriculturists and ecologists is thus necessary via one health approach strategy facilitating interdisciplinary collaborations and communications in all aspects of health care for humans, animals and the environment.

Abstract ICT is contributing in every sphere of human society and agriculture cannot be an exception. It can bring revolutionary changes in farmers’ life by improving accessibility to information and knowledge. Farmers certainly feel empowered and with confidence can opt for innovative approaches in business farming. Nearly 70 percent of the bottom fifth of the population in developing countries own a mobile phone. The number of internet users has more than tripled in a decade, from 1 billion in 2005 to an estimated 3.2 billion at the end of 2015. Thus, ICTs provide faster and newer ways of delivering and accessing information to many and are potential tools for poverty alleviation, health, education, judiciary, agricultural marketing and sustainable development. As per an ICAR report 80 per cent of the technologies generated by the researchers in agricultural sector are either not transferred to the ultimate users or they do not find applicability in the farmer’s field. Out of the remaining 20 per cent of the technologies, around 50 per cent do not impress the farmers due to mainly its ineffective technology transfer that range from language to effective demonstration using the available tools. Information and communication technology revolution is the latest milestone in Indian agriculture that can usher an era of knowledge flow from institution to farmers field in much systematic and organized way and eliminate hurdles in technology transfer and adoption. From the perspective of agricultural knowledge and information systems (AKIS), ICTs can be seen as useful in improving linkages between the research, extension and the market sub systems. Real-time information and customized knowledge provided by ‘eChoupal’ enhance the ability of farmers to take decisions and align their farm output with market demand and secure quality and productivity. The eKrishi project, Market driven Agricultural Initiative through IT enabled Agri-business Centres in Kerala, addresses the existing gap in agriculture information flow and transaction management. The touch screen kiosk with information on cattle health was tried and tested under a United Kingdom Department of International Development (DFID) – Animal Health Program (AHP) supported project on dissemination of animal health knowledge for development of landless dairy cattle owners in the peri-urban regions of Pondicherry. Being a global resource, and with billions of users, the Internet requires some degree of international cooperation on technical matters as well as on standards and norms that can ensure that it remains a global public good, facilitating information flows and contributing towards sustainable development.

Abstract Climate change is well acknowledged fact globally and in India has been witnessed with more frequent cloud bursts, highly variable frequency and distribution of rainfall, high seasonal thermal variations, receding glaciers and unstable agricultural production. Likely impact of climate change is expected to reduce agricultural productivity, production stability and incomes in some areas that already have high levels of food insecurity. However, Agriculture has the potential to retard the pace of climate change by capturing a significant part of the excess atmospheric carbon in the soil and plants in the form of organic matter and also competent to reduce emissions of nitrous oxide and methane if practiced in smart ways so developing climate-smart agriculture is thus crucial in achieving future food security and climate change goals. Transformations are needed in both commercial and subsistence agricultural systems, but with significant differences in priorities and capacity. Several climate smart agriculture practices such as cropping system improvement (e. g. crop rotation, diversification, improved varieties and integration of legumes), integrated nutrient management (e.g. green manure, compost and site specific nutrient management), resource conservation (e.g. minimum/zero tillage, keeping the land consistently covered with crop residues), precision water management (e.g. planting crops in bed, laser land leveling, mulching with crop residues) and agro-forestry have been proposed for adaptation to climate change and variability. However, their adoption decisions by the farmers are largely dependent on economic benefits associated with the interventions. It should be clearly understood that climate smart agriculture does not make use of different practices but certainly it uses them differently.

Abstract Parasitic diseases are of great economic importance in livestock farming and are major obstacle in the health and productivity of animals. These may be due to endo-parasites that live inside the body or ecto-parasites such as ticks, mites, flies, fleas, midges, etc., which attack the body surface. Among ecto-parasites, ticks and mites are very important and harmful blood sucking external parasites of mammals. Blood sucking by large numbers of ticks causes reduction in body weight and anemia among domestic animals, while their bites also reduce the quality of hides. More than 250 species of mites can cause problems for humans and domestic animals because of their being vector for zoonotic diseases. Their attack may lead to problems of temporary irritation of the skin due to bites, persistent dermatitis due to mites invading skin or hair follicles, mite-induced allergies, transmission of pathogenic microbial agents, intermediate host of tapeworms, invading respiratory passages, ear canals and internal organs, fear of mites called acarophobia The economic or medical importance of the Acari increases with their ability to be vector for viruses, rickettsiae, spirochaetes, phytoplasmas, mycoplasmas and protozoa, or to harbor and transport nematodes, bacteria and fungi pathogens that affect plants, domestic and wild animals and humans. Ectoparasites were not considered serious problem till the introduction of exotic animals or exotic semen in India as the indigenous breeds were considered resistant to parasites and the damages occurred by them were totally ignored. Much awareness was not there about the diseases caused by ectoparasites like anaplasmosis therefore dairy producers had to bear losses both, in milk production and proper animal growth. Ectoparasites may be causing death of animals in certain cases. Losses in dairy, poultry, goatry and other livestock farming can be considerably reduced through strategic management of parasites. This needs timely detection, identification and development of effective control measures. 10-30% production losses are estimated by parasitic infestation. If profitability is the goal in livestock entrepreneurship then target has to be the animal health, productivity and quality produce through strategic management and awareness campaign on economic importance of parasites.

Abstract Doubling the farmers’ income”, implies a 100 per cent growth of the current level of income of the farmers within a specific time frame, through multifaceted efforts of technological advancements in agriculture, policy formulation/ implementation, and efficient market system. The idea of doubling the farmers’ income during seven year period has by many experts been deemed impractical owing to the fact that a consistent annual growth rate of 14.86 per cent would be required in agricultural sector to double its GDP which has never had any history in the Indian agriculture. Some experts point out the possibility of success through appropriate technological intervention and viable government policies specific for each of the agro ecological zones of the nation. Increase in the farmer’s income doesn’t imply increase in nominal income through excessive production, but increase in real income, taking inflation into account. Production technologies, their use and impact are important factors to focus on doubling the farmers’ income. These technologies are already available across all the regions of the country but their adoption remains a problem to discuss always and partial adoption of the technological package can never be expected to get the desired results on ground. The results are suggestive of the pent up need to focus on the extension support on end-to-end approach from production to marketing with appropriate facilitation for inputs, insurance, credit, storage, marketing facilities etc. However, it would need involvement of all the stakeholders to come up on board to pursue this goal.

Abstract Seed priming is the innovative way of ensuring optimum germination and plant stand under moisture deficit situations. It enables the seed to tide over initial stress from biotic and abiotic factors. Higher yield with better quality seed are reported. The seeds of agronomic and horticultural crops are significantly affected by ageing and deterioration. Reversal or rejuvenation of aged seeds is therefore of primary interest. Experiments related to reversal of seed deterioration effects due to ageing relying heavily on accelerated ageing (AA) of seeds and their priming using various priming agents especially osmotic substances. Repair during germination is a hypothetical event supported by some investigators and questioned by others. Repair includes the spontaneous reorganization of plasma membrane phospholipids, which occurs during seed hydration. Alternatively or additionally, metabolic repair might occur. Experimental evidence for repair in imbibed seeds has been elusive. Priming reduced electrolyte leakage as well as lipid peroxidation in seeds implying the activation of membrane repair processes. Priming was also associated with increased levels of antioxidants like ascorbic acid and tocopherols particularly the latter and the activities of enzymes SOD, CAT POX involved in the mitigation of oxidative damage. In comparison with the priming of unaged seeds, the aged seeds experienced a diminution of response in terms of changes in the levels of antioxidants and scavenging enzymes. Thus, seed priming technique under climate extremities seems the best and economical means to sustain higher crop yields. The technique needs to be popularized among the farmers practicing agriculture and horticulture under rainfed situation so as to sustain production under climatic adversaries and enhance livelihood security and more profitability at the farm.

Abstract Worldwide trend in fruit crops has shifted to high density or meadow orcharding to manage tree size for desired architecture to allow better light interception and easy in operations such as pruning, pest control and harvesting. The meadow orcharding facilitates increase production as well as quality of fruits. High density planting (HDP) is one of the recent and novel concepts of increasing the productivity without affecting the quality of fruits. The HDP has been successfully demonstrated in fruit crops such as apple, mango, citrus, banana, pineapple and guava. However, for more location specific benefit research must continue on appropriate plant canopy, integrated nutrient management suitable varieties, ageing of orchard and tree replacement. HDP accommodates more number of trees per unit area ranging from 500-10,000 plants/ha depending on the type of fruit crop and the level of density such as medium high density 500-1500 plants/ha, optimum high density 1,500-10,000 plants/ha ultra-high density 10,000-1,00,000 plants/ha. High density orcharding is a highly technical entrepreneurship where nutrient management, irrigation and canopy management practices widely vary from traditional orchards hence growers must have full execution knowledge of this technology in present as well as future perspective. Post harvest, storage and marketing are closely associated with the success of HDP technology. Fruit yield increases 2 to 4 times vertically enhancing income of fruit growers.

Abstract The J&K state, like other Himalayan states, is endowed with varied climates and agro-climatic situations and has the potential for improvement in a horticulture sector. Focus on selective issues based on the niches of the areas , strengthening the on-going programs of different developmental departments, site specific issues, backed up with latest technologies need to be identified which can have tangible and immediate impact on the farm economy. The horticulture section is doing well in Jammu and Kashmir state when compared with others food crops, since it fetches good price because of its nature of seasonality. The estimation of the potential profits can be drawn by the fact that a farmer producing wheat of 1 kg gets 10 times higher prices for the same produce in horticulture section. Considering this high potential, the concept of doubling farmer’s income can work magically with horticultural crops. There is a need of shift from traditional crops and cropping patterns. Technological interventions are required to strengthen the conditions of cold storage, adoption of farming system approach, instead of cropping system approach, incorporating element of diversification, promotion of cultivation of high value crops, efficient post-harvest management, value addition etc. popularization of technologies and schemes to achieve targeted growth in horticulture. Strengthening water resources through rainwater harvesting, soil moisture conservation and efficient utilization of stored/conserved rain water (micro-irrigation, fertigation). Promotion of niche commodities based on agro-ecological situations will benefit promotional efforts in horticulture development with increased benefit cost ratio.

Abstract Biochar is the product of thermal degradation of organic materials in the absence of air (pyrolysis), and is distinguished from charcoal by its use as a soil amendment. Biochar is generally alkaline in pH and may increase soil pH with greater increase observed in sandy and loamy soils than in clayey soils. Biochar addition can increase cation exchange capacity, base saturation, exchangeable bases and organic carbon content as well as decreases in Al saturation in acid soils. Biochar enhances soil productivity by improving the physical, chemical and biological soil conditions. Improvement in soil structure increase soil water retention. A comparative study of soil fertility and leaching losses of nutrients between an Anthrosol and an adjacent unamended Ferralsols revealed that the Anthrasol had significantly higher P, Ca, Mn and Zn availability than the Ferralsol, and an increased biomass of both cowpea and rice by 38–45% without fertilization. More experimentation is needed to substantiate multiple benefits of biochar application in relevant soil-environment-climate-management factors and minimize any possible drawbacks in Indian perspective. Efficient use of biochar in agricultural system is one viable option that can enhance natural rates of carbon sequestration in the soil, reduce farm waste, enhance crop yield with concomitant improvement in soil quality.

Abstract Organic farming has proved to be effective technology for socio-economic empowerment of Indian farmers as it imposes positive changes in social factors in the local communities. There is tremendous scope of export, entrepreneurship and employment opportunities in organic farming in India. Local, regional, national and global markets are developing sinks for organic products. Organic crop production is sustainable and has positive impact on the ecology and socio-economic status of the peoples. Various socio-economic factors influence the farmers’ choice to adopt organic cultivation. Several threats and weaknesses exist. Hence, there is a need to address the weaknesses of the organic system by integrating it with innovative tools of marketing and ICTs so that there is alignment in demand- production-supply so concerted efforts are needed to establish production-consumption linkages through PPP mode. It will offset threats of organic farming thereby making it more remunerative and promising. The existing evidences suggest greater research efforts in this area are required. There is need to identify the gaps between the adoption of techniques of organic farming and remove them by strengthening production-consumption and marketing linkages. Moreover, it is important to assess and analyze the status of organic farming and feasibility to different sustainable practices in different production systems and farming situations across the country for promotion of this value added entrepreneurship. Keywords: organic farming, status, constraints, entrepreneurship and socio-economic dynamics

Abstract Over the years, India has emerged as one of the world’s biggest producers of milk, with the total milk production rising from 122 Million Metric Tons in 2010 to 171 Million Metric Tons in 2017 with dairy market in India touching a value of INR 7,916 Billion. An average livestock contributes about 12 % of farmer’s income and the same for small and marginal farmers and landless laborers’ is 36 %. While farmer’s income in agriculture is growing at 3.5 % annually, income from livestock is growing at about 14.5 %. Despite this, the majority of the dairy industry in India is still highly unorganized and dominated by small and marginal dairy farmers. Of all the major rural enterprises, dairy is an important profession of economic and social transformation to supplement the income and employment to the rural sector in general and rural women in particular. The process of dairy development would be incomplete and lop sided, unless farm women are fully involved in it. Indian dairy industry also offers good opportunities to both domestic and foreign investors for entry and expansion. Low yielding breeds, costly animal feeds, inadequate market linkage and predominance of handling dairy through indigenous technologies mar the Indian dairy industry. It is imperative to develop proper production, processing and marketing infrastructure if India has to emerge as an exporting country which is capable of meeting international quality requirements. It is anticipated that milk production in India will further grow at a CAGR of around 15% between 2018 and 2023. A comprehensive plan for producing quality and safe dairy products should be formulated with suitable legal backup. Dairy products’ consumption has been growing exponentially in the country owing to their rich nutritional qualities. Thus, it has enormous scope for women empowerment and socio-economic transformation of rural India and must rank top in our developmental agenda.

ABSTRACT Losses and benefits in agricultural production are associated with various weather parameters. So prediction of weather systems in different spatial and temporal scale over the Indian region therefore assumes considerable socio-economic importance. Meteorological information also plays an important role in the following operations in agriculture. The meteorological services can help the farmers & the planners exploit the potential of good weather and minimize the impact of bad weather as there exist tremendous opportunities for applications of meteorology in both day to day and long term planning in agriculture and such applications could contribute substantially to promote sustainable agriculture and poverty alleviation and the management of agrometeorological data is the key to these applications. Therefore, the area and input intensive agriculture is leading us into an era of unsustainable agricultural growth as the crucial components of sustainable agricultural production and distribution system such as integration of natural biological cycles and controls; protection and renewal of soil fertility and the natural resource base; optimization of the use of nonrenewable resources and of on-farm & off- farm inputs; ensuring dependable farm income. Hence, the meteorological information may help the farmer make the most efficient use of natural resources, with the aim of improving agricultural production both in quantity and quality. It becomes more and more important to supply meteorological information blended with weather sensitive management operations before the start of cropping season in order to adapt the agricultural system to increased weather variability. Subsequent to this, weather forecast based Agro-meteorological advisories become vital to stabilize their yields through management of agro-climatic resources as well as other inputs such as irrigation, fertilizer and pesticides. The main emphasis of the existing AAS system is to collect and organize climate/weather, soil and crop information, and to amalgamate them with weather forecast to assist farmers in taking management decisions. This has helped to develop and apply operational tools to manage weather related uncertainties through agro-meteorological applications for efficient agriculture in rapidly changing environments. Hence, weather information and advisories have assumed greater significance under the increased variability in the changing climate. Thus, Weather forecasting and advisory has become an indispensable aid for sustainable agro-transformation

Abstract Agriculture is at a cross-road in J&K wherein the small holdings, profitability, livelihood security and sustainability issues are the factors adding to the existing agrarian crisis in the state in particular and the country in general. This requires a decisive direction shift at the policy level towards adoption of integrated farming system. There is a need of fundamental change from the unilateral, top-down, prescriptive “knowledge generation and transmission” models of agriculture development adopted in the country so far, which have in fact resulted in an ecological, economic and social crisis in the farming sector of the state during 40 years of adoption and that climate change is one more imperative for drastic change to address the situation. Climate change is already a reality for farming community and that conventional models of agricultural research and extension have failed to address the need of the hour unless some fundamental recasting in the form of diversified farming system is adopted. The immediate need for interventional action precludes traditional models of research and support systems and requires alternative but urgent programmatic interventions, led by farmers’ institutions and their local resources, knowledge and innovations. Existing mainstream models of farming are GHG-inducing and are not conducive to adoption either given their high external-input dependency-models which increases the risk of vulnerable farmers. Integrated farming system a key to sustainable agriculture, on the other hand, holds immense mitigation and adaptation potential, specifically in the context of climate change even as it improves rural livelihoods and addresses the ecological crisis in farming of today under various climatic regions of Jammu in particular and state in general. Jammu region of the J&K state is bestowed with varying climate zones i.e. subtropical, intermediate and temperate zones, which is best suited for diversified farming,as the promotion of single enterprise is neither beneficial from economy point of view nor is sustainable under the given climate change crisis. The integration of Crops, Horticulture, Animal ,Fish cum Poultry, Mushroom, Vermicompost, Apairy, Biogas and Boundary plantation enterprises in Jammu region under integrating farming system is having the potential to improve the farm income to three folds besides will address the sustainability issues in the long run.

Abstract Remote sensing has wider applications in agriculture right from landscape mapping, soil moisture, planting dates, cropping systems to climate change effects. Growing uncertainties of weather and climate change pose a major threat to food security of the country and thus warrant for farmers empowerment of informed decision in agricultural risk management. The technology is competent to monitor crop growth, predict crop yield in terms of quantity and quality, assists in estimating crop acreage, its condition, disease and pest status. Over the last two decades, the development of space technology has led to a substantial increase in satellite earth observation systems. Simultaneously, the Information and Communication Technology (ICT) revolution has rendered increasingly effective the processing of data for specific uses and their instantaneous distribution on the World Wide Web (WWW). Satellite data provide better coverage in time and in area extent than any other alternative. It is important to make maximum use of this information to monitor our environment. Access to these Satellite data and products is only the beginning. In addition, the ability to interpret, combine, and make maximum use of this information is an integral part of weather and climate management at the national level. Production estimates, post harvest and quantity available for market enable the farmers and policy makers to chalk out sustainable strategy to match supply with market demand.

Abstract A Krishi Vigyan Kendra (KVK) is synonymous to farm science center with responsibilities of on- farm technological assessment, front line demonstrations, capacity building, advisory services and mulit-sector support to various private and public initiatives. The KVKs work under the ambit of ICAR, New Delhi with administrative support from local institutions or State Agricultural Universities. There were about 695 KVKs operational in India till October 2018. All KVKs fall under the jurisdiction of one of the 11 Agricultural Technology Application Research Institutes (ATARIs) spread throughout India. 21 KVKs are functioning in Jammu and Kashmir with seven of them in Jammu province namely KVK Jammu, Samba, Kathua, Reasi, Rajouri, Doda and Poonchh. The major thrust areas of hilly district Jammu and Kashmir are as integrated nutrient/pest/weed management in different crops, water management, promoting organic farming, protected cultivation of high value and low volume crops, promotion of aromatic and medicinal plants, increase in the productivity of livestock, drudgery reduction for farm women, promotion of loose flower cultivation, promotion of new single cross hybrids in maize, value addition of agricultural products and promotion of farming system approach. KVK Reasi has been able to motivate farmers of the district to adopt and practice organic farming, floriculture, backyard poultry farming and mushroom production at the commercial level.

Abstract India with population of 1.30 billion in which 47 per cent is engaged in agriculture earnestly needs efficiently use of biotechnology and genetic engineering for transforming agriculture sector. Biotechnological tools offer great opportunities for increasing agricultural production and can play an important role towards the attainment of production sustainability of crops. Biotechnological tools have the potential to release burgeoning pressure on agriculture and allied sectors; ecology and environment; plant, animal and microbial biodiversity; and allied resources such as land and water with improved and sustainable agricultural productivity which enhances food security. Agricultural biotechnology, including tissue culture, DNA-marker-assisted breeding and genetic engineering (GE) technology have potential to increase stress tolerant, selection efficiency, crop adaptation, crop productivity and food security in more efficiently manner through the development of improved varieties with increased yields, nutritional content and storage characteristics. Genetic engineering tools should continue to build capacity in this technology, giving priority to traits and crops that are of economic importance such as drought tolerance in maize, rice, beans; cold tolerance in rice; increased nutritional value and improved shelf life in fruits and vegetables. Crop varieties and livestock with improved characteristics have been developed using tools such as marker-assisted breeding and genetic engineering. Molecular pharming is one of the applications of genetically modified crops and livestock for the production of pharmaceutical proteins. Reproductive technologies are alternative ways for genetic improvement of livestock. The development of molecular diagnostics and vaccine technology as a tool improved the ability to detect and treat several diseases of livestock. The advancements in biotechnological tools such as protein engineering and metabolic engineering play a significant role in production of a large number of valuable and high quality industrial products.

Abstract Climate models predict a global average increase of air temperatures in the range of 14°C by 2100 (IPCC 2014) - a pace exceeding that of past climatic modifications. Change in temperature is expected to influence species occurrence and distribution with up to 37% of all extant species “committed to extinction” due to climate change. These predictions, however, do not include species interactions and evolutionary change which will significantly alter the fate of species. It is therefore important to improve our understanding of host-parasite interactions and subsequent evolution in response to environmental changes in general and temperature changes in particular. Globally livestock production systems are estimated to account for around 18% of emissions. The need of hour is to draw on recent advances in climatology and epidemiology of various parasitic diseases to consider how environmental changes linked with urbanization and climate change can alter the biology of hosts, pathogens and vectors. Climate change is leading to unusual flare-up of diseases, outbreak recurrences, range expansions, or invasion into novel territories and ecosystems, concomitantly with vector or host range shifts. Higher temperatures increase the invertebrate metabolic rate, egg production amount, and feeding frequency, reducing the duration of the development periods and impacting on the number of generations per year and population abundance effecting livestock and human health and socio-economic transformation

Abstract The future food grain demand in India is projected to increase beyond 300 million tons by 2025. There are only two ways to meet the increasing food and other agricultural demands of the country’s rising population either expanding the net area under cultivation or intensifying cropping over the existing area. The net sown area of the country has risen by about 20 per cent since independence and has reached a point where it is not possible to make any appreciable increase. The option left is go for high cropping intensity for ahead of present of 137%. A major share of this increase is likely to come from increasing the number of crops produced per year on a given land using improved crop cultivars. Research indicates that maximum intensity of 400-500% is possible provided situation fulfills the requisite factors such as irrigation facilities, short duration varieties, mechanization and agrochemicals are available. The objective of increasing the cropping intensity will be achieved only by the inclusion of short duration varieties of cereals, identification of pulses and oilseed crops that can fit well in the cropping systems of different agro-ecologies that will ultimately improve crop productivity per unit of land making the efficient utilization of resources and will meet the objectives of crop diversification leading to food and economic security of the nation.

Abstract Women empowerment is a buzz word of every platform starting from household issues to national politics. The best way to empower women is to make them economically self-reliant through entrepreneurial activities. In India agriculture is mainstay of the country and 70 percent women are farmers, so the best measure to empower them is through entrepreneurship in agriculture and allied sectors particularly organic agriculture as India currently holds a prominent position among 172 countries that actively practice it. At present, the country is home to more than 8, 50,000 organic producers, 699 processors, 669 exporters, and 7, 20,000 hectares under cultivation. Merely with 0.4 per cent of total agricultural land area under organic cultivation, India has attained global standing which infers that this industry still has a long way to go in terms of growth and opportunities for socio-economic development. Organic Food industry has been experiencing steadfast growth in past few years in India in spite of several challenges at producer, processor and consumer levels. With its annual turnover of Rs 4000 crore and annual growth rate of 25%, the country’s budding organic food market is transforming into world’s fastest growing organic food market with expected turnover of 10,000 crore by 2020. There is drastic change in consumer behavior and spending patterns in the country which has opened avenues for organic food industry at the national level besides export. This highscale opportunity is driven by the fact that organic food consumption is not even 0.1 percent of India’s $300 billion annual food consumption. Likewise, India’s share in the $100 billion global organic food market is less than 0.2 percent. Further, the scope of the opportunity is also driven by the increasing variety of organic foods hitting the market and the emergence of e-commerce as a channel in which to sell the product. India today is on the threshold of organic revolution where women participation will act as booster but need to be supported by Govts and technical institutions. Barriers to improving women’s agency include widespread deficiencies in policy support to women, and in fact to the organic farming sector as a whole. It is necessary to increase women’s research presence in organic research institutions (including at the higher levels). To enable women to conduct research in the field, it is important to allow women to set research agendas, and to work with their research needs and priorities. Food security as a priority for organic agriculture involves women’s empowerment since they hold a central role in providing nutrition for the household.

Index A Accelerated aging 239 Acute clinical mastitis 336 AFLP 436 agri export zones 66 Agri-horti zonalization 65 Agriculture production 375 agro-climatic diversity 45 agro-ecological 465 Agro-Food Processing 47 Agro-infiltration 440 Agromet Products 396 Agrometeorological advisory 356, 358, 359 Agrometeorological Advisory Service 356 air temperatures 348