World Agriculture Vol 6 issue 2 2016

editors

World Agriculture Editorial Board Patrons Professor Yang Bangjie Member of the Standing Committee of the National People’s Congress of China. (China) Lord Cameron of Dillington Chair of the UK All Party Parliamentary Group for Agriculture and Food for Development. (UK) Maxwell D. Epstein Dean Emeritus, International Students and Scholars, University of California, Los Angeles. (USA) Sir Crispin Tickell GCMG, KCVO, formerly, British Ambassador to the United Nations and the UK’s Permanent Representative on the UN Security Council (UK) Managing Editor and Deputy Chairman Dr David Frape BSc, PhD, PG Dip Agric, CBiol, FRSB, FRCPath, RNutr Mammalian physiologist Regional Editors in Chief Robert Cook BSc, CBiol, FSB. (UK) Plant pathologist and agronomist Professor Zhu Ming BS, PhD (China) President of CSAE & President of CAAE Scientist & MOA Consultant for Processing of Agricultural Products & Agricultural Engineering, Chinese Academy of Agricultural Engineering Deputy Editors Dr Ben Aldiss BSc, PhD, CBiol, MSB, FRES. (UK) Ecologist, entomologist and educationalist Dr Sara Boettiger B.A. ,M.A.,Ph.D (USA) Agricultural economist Professor Neil C. Turner FTSE, FAIAST, FNAAS (India), BSc, PhD, DSc, (Australia) Crop physiologist Professor Xiuju Wei BS, MS, PhD (China) Executive Associate Editor in Chief of TCSAE, Soil, irrigation & land rehabilitation engineer

Published by Script Media, 47 Church Street, Barnsley, South Yorkshire S70 2AS, UK

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Members of the Editorial Board Professor Gehan Amaratunga BSc, PhD, FREng, FRSA, FIET, CEng. (UK & Sri Lanka) Electronic engineer & nanotechnologist Professor Pramod Kumar Aggarwal B.Sc, M.Sc, Ph.D. (India), Ph.D. (Netherlands), FNAAS (India), FNASc (India) Crop ecologist Dr Andrew G. D. Bean BSc, PhD, PG Dip. Immunol. (Australia) Veterinary pathologist and immunologist Professor Tim Benton BA, PhD, FRSB, FLS Food systems, food security, agriculture-environment interactions Professor Phil Brookes BSc, PhD, DSc. (UK) Soil microbial ecologist Professor Andrew Challinor BSc, PhD. (UK) Agricultural meteorologist Dr Pete Falloon BSc, MSc, PhD (UK) Climate impacts scientist Professor Peter Gregory BSc, PhD, CBiol, FSB, FRASE. (UK)

Soil scientist Professor J. Perry Gustafson BSc, MS, PhD (USA) Plant geneticist Herb Hammond (Canada) Ecologist, forester and educator Professor Sir Brian Heap CBE, BSc, MA, PhD, ScD, FSB, FRSC, FRAgS, FRS (UK) Animal physiologist Professor Fengmin Li BSc, MSc, PhD, (China) Agroecologist Professor Glen M. MacDonald BA, MSc, PhD (USA) Geographer Professor Sir John Marsh CBE, MA, PG Dip Ag Econ, CBiol, FSB, FRASE, FRAgS (UK) Agricultural economist Professor Ian McConnell BVMS, MRVS, MA, PhD, FRCPath, FRSE. (UK) Animal immunologist Hamad Abdulla Mohammed Al Mehyas B.Sc., M.Sc. (UAE) Forensic Geneticist Professor Denis J Murphy BA, DPhil. (UK) Crop biotechnologist Dr Christie Peacock CBE, BSc, PhD, FRSA, FRAgS, Hon. DSc, FSB (UK & Kenya) Tropical Agriculturalist Professor R.H. Richards C.B.E., M.A., Vet. M.B., Ph.D., C.Biol., F.S.B., F.R.S.M., M.R.C.V.S., F.R.Ag.S. (UK) Aquaculturalist Professor Jacqueline Rowarth PhD, CNZM, CRSNZ, FNZIAHS (New Zealand) Agricultural Economist Professor John Snape BSc PhD (UK) Crop geneticist Professor Om Parkash Toky MSc, PhD, FNAAS, (India) Forest Ecologist, Agroforester and Silviculturist Professor Mei Xurong BS, PhD Director of Scientific Department, CAAS (China) Meteorological scientist Professor Changrong Yan BS, PhD (China) Ecological scientist Advisor to the board Dr John Bingham CBE, FRS, FRASE, ScD (UK) Crop geneticist Editorial Assistants Dr. Zhao Aiqin PhD (China) Soil scientist Ms Sofie Aldiss BSc (UK) Rob Coleman BSc MSc (UK) Michael J.C. Crouch BSc, MSc (Res) (UK) Kath Halsall BSc (UK) Dr Wang Liu BS, PhD (China) Horiculuturalist Dr Philip Taylor BSc, MSc, PhD (UK)

In this issue ...

Second issue contents

notice:

n World Agriculture welcomes your comments, criticisms and discussions

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editorials: Number 5 n Indian agroforestry and food production David Frape Number 6 n India: Potential based on tradition Robert Cook and Professor O.P. Toky

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Number 7 n Innovative agroforestry for 7-16 livelihood security in India Dr A.K. Handa, Professor O.P. Toky, Dr S.K. Dhyani and S.B. Chavan If you wish to submit an article for consideration by the Editorial Board for inclusion in a section of World Agriculture: a) Scientific b) Economic & Social c) Opinion & Comment or d) a Letter to the Editor please follow the Instructions to Contributors printed in this issue and submit by email to the Editor editor@world-agriculture.net Published by Script Media, 47 Church Street, Barnsley, South Yorkshire S70 2AS, UK

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editorials

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World Agriculture welcomes your comments, criticisms and discussions

ur journal is to open a new section entitled “Readers’ Comments, Criticisms, Opinions and Letters”. The objectives of this section of the Journal is for unedited views to be expressed and discussed amongst our readers. Your comment emailed to the Editor (editor@world-agriculture. net) could be published within a week

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n the current Issue of WA we publish a fascinating and informative account of agroforestry in India by Handa, Toky et al. In this paper are listed various treebased products: gums, resins, floss, fibres, fodder, brooms, fruits and many others for the use of the subsistence farmer. Hence, these various agroforestry systems are considered to be the backbone of marginal farming for a selfreliant and sustainable agriculture, which also forms a strong feasible option to counter climate change. The achievement of food security, environmental security and social benefit is a prime objective of these subsistence farming systems. For Indian commercial production woodland is a source of apiculture (honey bees), sericulture (silk worms), lac cultivation (commercial products e.g. shellac), gum, resin, and medicinal, aromatic and flavouring plants (e.g. the spices, cardamon, black pepper, coffee, mustard and chilli). The wood, itself is sold for paper pulp, building structures and furniture and in India one must not forget the cricket bat industry. There is an urgent need to have appropriate marketing interventions and capacitybuilding programmes for post-harvest technology, with value addition in these areas, to provide better economic returns and to check the migration of rural youth to urban areas. Trees can be used as wind breaks and to raise the organic matter content of the upper soil horizons, so benefiting agricultural crops, and the appropriate

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or two, so that our readers are able to participate in any current international debate concerning agricultural production in the environment, or to comment on any article we have published. Owing to space limitation it may be necessary to abridge some longer comments; but so long as the statement does not break any law it could be

selected for publication- similarly to Letters to the Editor of a newspaper. As is the practice with other Publications please send your comment together with your full name, postal address and telephone number to the Editor (editor@world-agriculture.net). If it is your wish your name and the country of your address, only will be published. Editor, April, 2016.

tree species, which are listed, known as phreatophytes (deep rooted plants which obtain water from a permanent ground supply of the water table, often found in arid environments) draw water from well below the agricultural layer. Handa et al. provide evidence from the Khejri (a phreatophyte)-based agroforestry systems in Rajasthan that the availability of soil N, P and K is increased in all of their reported systems (remember that the there is a finite supply of soil P in the world(1)). This Khejri agroforestry also increases: 1) free-living nitrogen fixers (Azotobacter spp.), 2) organic C, microbial biomass, soil myccorrhyzal spore count, hyphal density and fungal biomass (all measures of similar soil activity) and 3) soil moisture content in both the rainy and rainless seasons. The increase in soil fertility from the Khejri system has led to increases in agricultural productivity of crops ranging from cow peas, cluster and mung beans to pearl millet, taramira and mustard. It is surprising to me that this list includes nitrogen-fixing crops; but it excludes wheat, for which shade from the trees presumably reduces yield even on this relatively poor soil, deficient in moisture. In their final table they show that the benefit/cost ratio is well over one in all 21 areas in which agroforestry is practiced. This is very largely on land unsuitable for agricultural crops, but also on land for which its fertility for those crops would benefit in the longer term. We shall in the next Issue publish a paper in which

the Chinese Government has recently recognized the value of woodland as an extended “fallow” period for land, the fertility of which has become exhausted. Likewise India launched a much-needed National Agroforestry Policy in 2014 – the first of its kind in the world. This new policy is a path-breaker in making it an instrument for transforming lives of the rural farming population, protecting the ecosystem and ensuring food security through sustainable means. It has established an Institutional organization at the national level to promote agroforestry under a mandate of the Ministry of Agriculture with a simplification of regulations related to harvesting, felling and transportation of trees grown on farmland; ensuring security of land tenure and creating a sound base of land records and data for developing a Market Information System (MIS) for agroforestry; investing in research, extension and capacity building and related services; improving access to quality planting material; provision of institutional credit and insurance cover to agroforestry practitioners; increasing participation of industries dealing with agroforestry produce and strengthening the marketing information system for tree products. Initially twenty important multipurpose tree species have been identified nationally to be exempted from all restrictions related to harvesting, transportation, marketing and of course grown under agroforestry systems. Agroforestry produces edible foodstuffs for Man and animals. Nevertheless, on good quality land,

Indian agroforestry and food production

where proven methods of crop production are used, it is the case that agricultural crops produce more digestible energy and protein per unit area that does agroforestry. One hopes that the Indian population does not exceed the ability of their existing farmland to produce adequate digestible energy and protein to give their population an adequate diet. If the population does grow disproportionately, then there will be pressure to encroach on or replace forests

by energy-yielding crops. That would disrupt a carefully tuned balance and lead to an inevitable and eventual decline in both productivity of crops and in biodiversity. This is the general case for the adoption of currently developed and proven methods of plant breeding which lead to greater and more assured production from a given area of crops(2). Moreover, it is my view that individual trees and forests have characters and

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characteristics for which there are no substitutes and forests are the home of a wide range of wildlife!

References

1. Cornish, P.S. (2011) World Agriculture, 2, No.2, 21-27. Peak phosphorus: implications for agriculture. (2) Murphy, D.J. and Virgin, I (2016) World Agriculture, 6, Issue 1, 8-15. Has agricultural biotechnology finally turned a corner? Report of FAO Symposium on genetic manipulation as used in agriculture, Rome, February, 2016.

David Frape

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India: Potential based on tradition

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nyone who has visited India two or three times in the last decade cannot fail to be impressed by the huge economic progress made in recent years. Dual carriageways and regular flights now link most major cities and traffic becomes more frenetic by the day, as new cars, motor cycles and lorries crowd onto the congested roads. This is a reflection not just of economic activity, but of increasing affluence, especially amongst an expanding middle class, whose spending power provides benefits throughout the country. India is now a major global power. Although the population continues to increase there is evidence that the rate is decreasing with the latest census showing a drop in the number of under 20s in all communities (3). Such an effect would be expected if the trends observed in other countries are followed, where increased economic activity and education are associated with reduced overall birth rates. In India, the trend is also encouraged by government policy. There are of course great challenges. India still has a large number of cultural, linguistic and ancestral communities whose interests need to be recognized and supported in a changing country, where their needs may not always be met by vigorous pursuit of a market economy. As pointed out by Frape (this issue) 40% of India’s land area is devoted to arable production for food to meet the nutritional requirements of the growing population. About 24% of the land area is forest (2) and 9% is managed as national park or wildlife sanctuary. These areas are a vital buffer to preserve India’s wildlife and preserve iconic species such as the threatened tiger and the Asian lion. The population of the latter is increasing in the Gir Forest in Gujarat, thanks to the skilful management of the Gujarat Forest Service in cooperation with the National Parks Service and local communities. Likewise, Siriska wildlife sanctuary in Rajasthan, a semiarid state, has been repopulated with Bengal tigers. This is a success story of tiger conservation in an area where large scale human interference had eliminated them. Open wildlife sanctuaries also play an important role in conservation.

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Robert Cook and Professor O.P. Toky

For example, the Bisnoi community in north India protect wildlife in their agricultural fields and conserve many species including black buck (a rare antelope). Sanctuaries of this type are an important component of protection for flora and fauna. As in all countries, the challenge is to maintain food production from a decreasing land area whilst preserving territory for biodiversity when an increasing middle class requires greater attention be given to wilderness preservation and wildlife sanctuaries. Returning European visitors to India’s wildlife sanctuaries and national parks will have noticed how, in recent years, numbers of Indian visitors have overtaken those from other countries; a sign of increasing concern for conservation as well as increasing affluence in India itself. These changes are all likely to be influenced by the challenges of climate change. Unseasonal variation in the usually predictable climate of northern India seems to be especially serious this year. After two years of low monsoon rainfall, a warm and dry winter has reduced plantings of the essential winter crops of rice and oilseeds by over 4%, and by 7% for wheat alone (3). These figures represent a significant shortfall in production. Temperature rises, rainfall changes and sea level rises have already affected India to a significant extent since the 1950s, compounding an already variable climate. The 5th IPCC report (4) indicates that these trends will continue so there will be increased risk of flooding with more variable rainfall and increased temperatures which will reduce yields of rice and wheat in particular. This puts India at the forefront of global challenges for adaptation to climate change and the need to adopt new agricultural technology to increase yield per unit area and thus production efficiency. Cotton is an excellent example of this, where adoption of GM cultivars in recent years has increased productivity by 55% since 2000 and increased farmer profits by 50% (6). Murphy (1) identifies other crops which have the potential to effect similar yield improvements. Adequate field testing of these will be essential if their potential is to be realised, according to a leading crop scientist, M S Swaminathan (7).

The environmental lobby however, considers GM crops to be unsafe for the human and animal consumption (despite much evidence to the contrary), and not sustainable in the long term. They claim the quality of GM foods is inferior to so called natural foods. They also claim repeated application of the same herbicide reduces biodiversity and stability of the ecosystem. Small scale farmers, especially in marginal areas contribute significantly to Indian agriculture. With changing climate and increased risk of crops failures, these farmers are less likely to afford the high seed cost of new crops and rely on farm saved seed. They frequently have one or two buffaloes, cows or goats which provide resilience in times of crop failures. This small scale agriculture, so important in India, relies on diversity of foods from a small area of land and may well be more resilient in times of unpredictable weather. The Indian civilization has survived for thousands of years and developed on the basis of a rich cultural tradition to become a global powerhouse. The nation demonstrates the challenges facing the globe, as societies increase in affluence they become more conscious of their heritage. Historically, such resilience has helped India survive prolonged famines and human invasions; the rich heritage and diversity of plants and animals helped man to survive. Articles in recent issues of World Agriculture and planned for our next issue highlight how India can meet these challenges with confidence.

References

1. Murphy, D (2016). Title to be decided. World Agriculture 6.3 2. Anon (2016). National Parks, Wildlife Sanctuaries and Biosphere Reserves in India http://ces.iisc.ernet.in/envis/sdev/parks.htm Retrieved 3 April 2016 3. Miscellaneous reports in The Times of India, January 2016 4. Anon (2014) http://cdkn.org/wp-content/ uploads/2014/04/CDKN-IPCC-Whats-in-it-for-SouthAsia-AR5.pdf Retrieved 3 April 2016 5. Anon (2016) http://www.cotcorp.gov.in/nationalcotton.aspx#indiancotton Retrieved 4 April 2016 6. Vaidyanathan, G (2012) Genetically modified cotton gets high marks in India: Engineered plants increased yields and profits relative to conventional varieties. http://www.nature.com/news/genetically-modifiedcotton-gets-high-marks-in-india-1.10927 Retrieved 4 April 2016 7. Vishwa, M (2016) Test GM crops at University farms for fair verdict. Times of India, January 13 2016

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Innovative agroforestry for livelihood security in India

Dr A.K. Handa1, Professor O.P. Toky2, Dr S.K. Dhyani3 and S.B. Chavan4 Principal Scientist (Forestry)1 & Scientist (Forestry)4 ICAR-Central Agroforestry Research Institute, Jhansi, India 2Ex-ICAR Emeritus Scientist, CSS Haryana Agricultural University, Hisar, India 3Principal Scientist (Agroforestry), Natural Resource Management Division, ICAR, New Delhi, India Dr. O. P.Toky ICAR Emeritus Scientist, Ex Dean, Postgraduate Studies CCS Haryana Agricultural University, Hisar-125004 (India) Mobile: ++91 9896173626 E-mail: optoky@gmail.com Summary

Planting trees in agricultural landscapes not only generates income in the form of timber and non-timber produce, but also performs valuable ecosystem services. Agroforestry has an important role in reducing vulnerability, increasing resilience of farming systems and buffering households against climate related risks. It can also maintain or increase the supply of ecosystem services – water, soil health and biodiversity, especially under a changing climate, that will continue to support social, industrial and ecosystem services needs. There are many options which can be integrated with agroforestry to ensure livelihood security in rural areas, such as apiculture, sericulture, lac cultivation, gum and resin, medicinal and aromatic plants. There is an urgent need to have appropriate marketing interventions and capacity-building programmes for post-harvest technology with value addition in these areas to provide better economic returns and to check the migration of rural youth towards urban areas. The present paper aims at potential and role of agroforestry in providing livelihood and environmental securities in India. Key words: Agroforestry systems, livelihood security, employment opportunity, bio-fuel, climate change. Abbreviations: AICRP-AF: All India Co-ordinated research Programme on Agroforestry; ICAR: India Council of Agricultural Research; MTP: Multi-purpose trees; BNF: biological nitrogen fixation; VAM: Vesicular Arbuscular mycorrhiza; ITC: India Tobacco Company; WIMCO: Western Indian Match Company; IFFCO: Indian farmers Fertilizer Cooperative Limited Glossary: Agroforestry is the deliberate growing of woody perennials on the same unit of land as agricultural crops and/or animals, either in some form of spatial mixture or sequence Lac is resinous secretion of Lac insects in the encrustations on trees and which produces commercial product e.g. shellac Sericulture, silk farming, the rearing of silkworms for the production of silk. Cardamon (Cardamum) is a spice made from the seeds of several species in the genera µElettaria§ and µAmomum§ in the family Zingiberaceae. Phreatophyte is a deep rooted plant which obtains water from a permanent ground supply of water table, often found in arid environments. Lopping is the practice of cutting down leafy canopy of trees for the purpose of fodder and fuelwood. Discounting is the interest rate paid by the market or bank on invested capital. NPV: Net present value is determined by discounting all revenue and costs to the present; B/C ratio: benefit/cost ratio is calculated by dividing the sum of discounted revenues by the sum of discounted costs; FIRR: Financial internal rate of return is a discount rate at which an investment’s NPV equals zero; LEV: Land expectation value is interpreted as the maximum amount of money a landowner can pay for the land and still earn the minimum acceptable rate of return of an agroforestry investment.

Introduction

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groforestry is practised by millions of farmers worldwide, and has been a feature of agricul­ture for millennia. It encompasses a wide range of trees that are grown on farms and in rural

landscapes, and includes the generation of science-based tree enter­prise opportunities that can be important in the future (1). As per the World Bank 2004 report an estimated 1.2 billion rural people cur­rently practise agroforestry on their farms and

in their communities and depend upon its products. Almost 10% of the world’s agricultural area is under agroforestry (2), whereas Nair et al. (3) estimated the total area under agroforestry was 2.35 billion ha. At present agroforestry meets almost

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half of the demand of fuel wood, two thirds of that for small timber, 70-80% wood for plywood, 60% raw material for paper pulp and 9-11% of the green fodder requirement of livestock, besides meeting the subsistence needs of households for food, fruit, fibre, medicine etc. However, at present the biomass productivity per unit area is less than 2 t ha-1yr-1. Agroforestry practices have demonstrated that this could be safely increased to10 t ha-1yr-1 by carefully selecting tree-crop combinations. The area under forest is degrading due to demographic pressure and infrastructure growth needs while the agricultural area is almost stable. In India, nearly 120.72 million ha land or 37% of the total geographical area is under one or other forms of soil degradation (e.g. water erosion: 93 million ha (Mha), wind erosion: 11 Mha, salt affected soils: 6.74 Mha and 16.53 Mha of open forest area) (4). Up to March 2007, 56.54 Mha has been treated under various watershed development programmes, however, a sizeable area is yet to be treated. Agroforestry can play a vital role in such endeavours by meeting the diverse needs of people resorting to them as inter-dependent benefits of the three components, viz. trees, crops and livestock in addition to the 6Fs, i.e. food, fruit, fodder, fuel, fertiliser and fiber (5) from limited land resources. Trees are integral to our traditional farming systems, for the innumerable benefits that they provide. However, over time, with shrinking land holdings, annual crops have replaced trees for various reasons. Trees complement farming in terms of manure, fodder and fuel needs of the farmer. They form the backbone for practicing integrated farming systems which is necessary for self reliant and sustainable agriculture. Owing to diverse options and products, agroforestry systems provide opportunities for employment generation in rural areas. Increased supply of wood in the market has triggered a substantial increase in the number of small-scale industries dealing with wood and wood based products in the recent past.

Diversity of agroforestry systems

The Diagnosis and Design (D&D) survey of the existing agroforestry system was conducted to identify suitable species and traditional agroforestry practices. The various improved agroforestry practices and systems, such as home gardens, block plantation, energy

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scientific the “State� forests (12). The prominent agroforestry system from different region of the country are enumerated and presented in Table 1.

Potential and area under agroforestry

Table 1. Prominent agroforestry systems in different regions of India. Irri: irrigated; RF: rainfed; TBOs: tree borne oil seed (Source: Dhyani et al., 6) plantation, shelterbelts and improvement or alternative to shifting cultivation, are some of the specialised agroforestry systems developed. Dhyani et al. (6) have reported the common twenty agroforestry systems being practised in different agroecological regions of India and these are, 1. Agri-silviculture; 2. Boundary plantation; 3. Block plantation; 4. Energy plantation (trees + crops during initial years); 5. Alley cropping (hedges + crops); 6. Agri-horticulture (fruit trees + crops); 7. Agri-silvi-horticulture (trees + fruit trees + crops); 8. Agri-silvi-pasture (trees + crops + pasture or animals); 9. Silvi-olericulture (tree + vegetables); 10. Horti-pasture (fruit trees + pasture or animals); 11. Hortiolericulture (fruit tree + vegetables); 12. Silvi-pasture (trees + pasture/ animals); 13. Forage forestry (forage trees + pasture); 14. Shelter-belts (trees + crops); 15. Wind-breaks (trees + crops); 16. Live fence (shrubs and under- trees on boundary); 17. Silvi or Horti-sericulture (trees or fruit trees + sericulture); 18. Horti-apiculture (fruit trees + honeybee); 19. Aqua-forestry (trees + fishes); and 20. Homestead (multiple combinations of trees, fruit trees, vegetable etc). Agronomic practices for raising the promising multipurpose tree species (MPTS) in association with annual crops

have been developed and standardised. The All India Co-ordinated research Programme on Agroforestry (AICRP-AF) and ICAR-Central Agroforestry Research Institute Jhansi recommends Morus and Grewia-based system for the western Himalayas, alder-based for the North Eastern Hill (NEH) region, poplar-based for the Indo-Gangetic region, aonla and Khejri-based for the semi-arid and arid regions, teak-based for the tropical region and Gmelina and Acacia-based system for humid and sub humid regions. Homegardens in Kerala and other coastal states promote food security and diversity and provide basic needs of food, fuel-wood (7, 8) fodder, plantderived medicines, and cash income from their small holdings (9). In addition, agroforestry practices have been intertwined with the various programmes/ schemes like watershed development, rehabilitation of problem soils, treatments of degraded and other wastelands etc. (10). Deliberate growing of trees on field bunds (risers) and in agricultural fields as scattered trees, and the practice to utilise the open interspaces in the newly-planted orchards and forests for cultivating field crops are also widespread in the sub-continent (11). It is estimated that currently agroforestry (outside the forest) has a greater number of trees than

The increasing human and cattle population has increased demand of food and fodder in India to an alarming extent, as there is little scope to increase food production by increasing the area under cultivation. Food production can only be increased from the land already under cultivation or from land not conventionally considered arable. A management system needs to be devised that is capable of producing food from marginal agricultural land and that is also capable of maintaining and improving the quality of the environment. Agroforestry has both productive and protective potential so can play an important role in enhancing the productivity of our land to meet the demands of the human and livestock populations. The area under agroforestry in India as well as in the rest of the world is a debatable issue. The number of trees vary from one (arid region of Rajasthan) to 200 per ha (Home gardens of Kerala) and there is no standard procedure to estimate them. Chavan et al. (5) have documented the current approximate area under agroforestry as approximately 25.32 m ha, or 8.2%of the total geographical area of the country according to Dhyani et al. (1). Based on data from CAFRI, Jhansi and Bhuvan LISS III, the area under agroforestry is 13.75 m ha (13). However, the Forest Survey of India (14) estimated the same as 11.54 m ha, which is 3.39% of the geographical area of the country. Figure 1 shows the area under agroforestry as estimated by two different agencies in India. Various literature surveys were undertaken to present the area under different traditional and commercial agroforestry systems in India (Table 2)

Agroforestry for food and nutritional security

The country’s food production has increased five-fold since independence but recent improvements in food supply have been insufficient to fulfil the nutritional needs of the average person owing to the increasing population. As per estimates of economic survey in 2015 the wheat and rice yield was 90.76 and 102.54 million

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Table 2. Area expansion of traditional and commercial agroforestry Source: Chavan et al. (5) systems (AFS) in India. tonne respectively, which have the greatest increase in yields, while production of coarse grains (40.22 m t) and pulses (17.38 mt) has changed only marginally. Increasing the production and consumption

of protein-dense foods, pulses in particular, will be necessary if the country is to meet its protein needs. Agroforestry with appropriate treecrop/legume combination is one option. The different agroforestry

Figure 1. Agroforestry area (m ha) in India. (Chavan et al. 5). (J & K, Jammu and Kashmir)

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systems provide the desired diversification to increase the food security of the country and act as a shield against poor production during drought and other stress conditions. Agroforestry also provides nutritional security because of diverse production systems which include fruit, vegetables, oilseed crops, medicinal and aromatic plants in addition to normal food crops grown by the farmers. Vegetable crops yield a higher return on an average than the common field crops. Crops like peas and cowpeas can be grown successfully during winter and summer months respectively under trees and these crops can also fix the atmospheric nitrogen and improve the fertility status of the soil along with providing additional income from the production of vegetable crops. Agroforestry has the immense potential to increase and sustain the food production per unit area in systems like the Prosopis cineraiabased agroforestry system of the arid region of India (22). The case study on Prosopis cineraria will provide light on the role of agroforestry in the arid region. Case study 1. Prosopis cinerariabased agroforestry in the arid regions of Gujarat and Rajasthan, India Khejri (Prosopis cineraria) is an indigenous tree growing in the tropical dry and thorn forests of North-western parts of India. The tree is also called the King Tree of the Great Indian Desert due its multiple benefits in conserving the fragile desert ecosystem. Since time immemorial, Khejri has been the friend of arid dwellers, providing all types of ecosystem services (food, fodder, shade, shelter, fuel, aesthetic value, improving soil fertility etc.). Khejri is a nitrogen-fixing leguminous tree having characteristics of a phreatophyte root system which enables it to obtain water from the zone of saturation or capillary fringe and makes moisture available to the agricultural crops in the upper strata of soil. Thus, there is no competition between trees and crops/grasses for soil moisture. It is also reported that vegetative growth is high under trees, as it is known to increase the fertility status of the soil. Moreover, in agroforestry nutrient cycling takes place by three main treemediated process. 1) Increased input of nitrogen through biological nitrogen fixation (BNF) by trees. 2)

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Table 3. Soil property status under Khejri based agroforestry systems in Rajasthan. (Source: Verma et al. (23); Tarafdar and Sharma (24)). cluster bean, pearl millet, mustard, Enhanced availability of nutrients through production and decomposition Taramira, wheat and mung bean mainly due to its deep root system and of substantial quantities of tree having little competition with crops for biomass. 3) Greater uptake and nutrients and moisture. Moreover this utilization of nutrients from deeper tree has nitrogen fixing ability (Table layers of soil by trees. Apart from 4). this, root tissues are continuously Though the tree is present in a sloughed off and replaced. These scattered form in arid environments, sloughed off tissues, along with it is beneficial to maintain a tree senescent and dead roots, contribute density of 100-200 trees per hectare a significant addition of organic matter that can increase crop yield by 15 to to the soil ecosystem. The soil fertility 20% compared to sole crops. The tree enhancement status has been given in is lopped for fodder and fuelwood. Table 3. Lopping practices in winter helps Agroforestry is playing an important for winter crops. Prosopis cineraria role in optimising nutrient cycling, trees are lopped annually to gain organic matter production and maximum fodder yield, however, trees reducing a need for the external input of more than 75 cm diameter can be of fertilisers; however the information lopped for maximum returns (28). on the inputs and outputs of the This agroforestry is considered as the nutrient system is lacking. In the light most sustainable basis and is helping of the present-day situation, it can to increase food production in arid be said that the Khejri tree serves as regions of India. an ‘island of fertility’ in an ecosystem Agroforestry systems have been where resources are very much developed for different agro-ecological limited. regions of the country. In addition to Thus, more attention should be providing higher returns, these also focused on saving this ‘Lifeline tree of improve livelihood security as a cover the desert ecosystem’ for evergreen agriculture productivity and livelihood against crop failure due to climatic security. aberrations, particularly in arid and Khejri is known to improve yields of semi-arid regions (Fig 3). associated crops such as cow pea, Some of the important activities which

Table 4. Crop yields under Khejri agroforestry in Rajasthan.

can be integrated with agroforestry for livelihood security include lac cultivation. Conventional tree hosts of lac like ber (Zizyphus mauritiana) and Palas (Butea monosperma) can easily be integrated in bunds of cropped fields. Other quick-growing hosts like Flemingia semialata hold potential for integration in farming system models for lac production. Another option is to integrate sericulture as of the four hosts of the silk worm viz., Mulberry (Bombyx mori), Tasar (Antheraea myllitte), Eri (Phelosamia ricini) and Muga (Antheraea assamensis) are cultivated in India. The silk worm insect can feed on leaves of different agroforestry tree species such as Terminalia tomentosa (asan), T. arjuna (arjun) and Shorea robusta (sal) for the Tasar insect; the commonly used Morus alba, M. indica, M. serrata and M. latifolia for the mulberry insect can be included in the agroforestry models. As per study of Sridhar et al. (29) the lac cultivation on Butea monospermabased agroforestry is quite helpful for livelihood security in droughtprone regions of Central India and a single tree of Butea monosperma can produce 1.5-2.5 kg and gives an annual income of Rs 700/- to Rs 800/- (10-12 US$). An apiculturebased agroforestry system is another option which will not only provide additional income to the farmers, but will also result in other benefits to the agricultural production due to the role of honeybees as pollinators. A number of agroforestry tree species have been identified which can act as host species for honey bees and there is ample scope for including such trees in different agroforestry models to sustain round-the-year honey production. Gums and resins form another important group of non-wood forest products. India is traditionally the largest producer of guar gum and karaya gum. Gumyielding trees species such as Acacia senegal (gum Arabic), Acacia nilotica, Butea monosperma (Bengal kino gum) and Boswellia serrata (yielding salai guggul) are potential species for agroforestry models and need to be promoted on a large scale to provide sustained income and livelihood security to resource poor rural masses (Fig 5). Venkatesh et al. (30) reported that a single tribal family can collect up to 65 kg of Butea gum and earn a maximum amount of Rs 2628 (40-42 US$).

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Figure 2. Prosopis cineraria-based agroforestry system of the arid zone of India Agroforestry for livelihood security. Figure 3 a) Lac host Butea monosperma scattered agroforestry in Central India; b) Brood inoculation of trees; c) lac incrustation by insect Laciferr lacca.

Figure 4. Multi-storeyed agroforestry systems for livelihood and nutritional security. wood and wood based products. Such industries promote agroforestry and contribute to an increasing area of farm forestry. Recognizing agroforestry as a viable venture, many business corporations, limited companies such as ITC, WIMCO, West Coast Paper Mills Ltd, Hindustan paper Mills Ltd., and financial institutes, such as IFFCO, have entered into the business on a large scale and have initiated agroforestry activities in collaboration with farmers. Figure 5. Gum based agroforestry One of the major contributions of systems a) Acacia nilotica gum b) agroforestry for the economy is the Butea monosperma gum. livelihood impact, both in terms of income

Agroforestry for employment opportunities

The role of agroforestry products and environmental services to meet the subsistence needs of low income households and providing a platform for greater and sustained livelihood of the society have been highlighted (31). Increased supply of wood has triggered a substantial increase in the number of small-scale industries dealing with

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and employment generation. Besides the existing agroforestry practices, there is a potential to increase employment by up to 943 million person days annually from the 25.4 Mha of agroforestry. In the Indian Himalaya alone there is an estimated potential increase of 5.763 million person days each year (10). The Alnus nepalensis-based agroforestry system of Sikkim state is an excellent example of the dependency of people on agroforestry for employment which is distributed on 34,000 ha in north-east India (32). Case study 2: Alder-large cardamom based agri-silviculture system of North-east India The first inhabitants of Sikkim, the Lepchas, collected capsules of large cardamom from natural forests. New plantations and large patches of large cardamom based agroforestry systems have been converted in to monocultures of N2 fixing actinorrhizal Alnus nepalensis as a shade tree. Other common trees are Schima wallichii, Engelhardtia acerfolia, Eurya acuminate, Leucosceptrumc anum, Maesachisia, Symplocos theifolia, Ficus nemoralis, F. hookeri, Nyssa sessiliflora, Osbeckia paniculata,Viburnum cordifolium, Litsaea polyantha, Macaranga postulata,etc. Thus, it is conducive to the conservation of tree biodiversity in the north eastern region. Large-scale land use transition in maximizing the benefits to meet the rising demands for food and other ecosystem services for the well being of society has been the main problem confronting sustainable development in mountain areas. Agroforestry is one of the favoured land management systems in the mountains. This case study analyses the role of a traditional large cardamom (Amomum subulatum) agroforestry system on enhancing the ecosystem services in the Eastern Himalayas. A total of 16,949 cardamom holdings have been recorded in Sikkim State, most of which are smaller than 1 ha

Figure 6. Poplar based agroforestry system and wood based industries in Indo-Gangetic region of India.

scientific (Fig 7). The large cardamom-based agroforestry system is observed to accelerate nutrient cycling, increases soil fertility and productivity, reduces soil erosion, conserves biodiversity, conserves water and soil. It serves as a carbon sink, improves the living standards of the communities by increasing the farm incomes and provides aesthetic values for the mountain societies. Cardamom agroforestry stores 3.5 times more carbon than rainfed agriculture, showing potential mitigation possibilities of the agroforestry by sequestration of the atmospheric carbon. Agroforestry is an efficient management system where the ratio of output to input is more than 13 compared to rainfed agriculture. Cost benefit analysis shows that cardamom agroforestry is profiting the farmers by 5.7 times that of rainfed agriculture. This agroforestry system is a unique example of the ecological sustenance and economic viability for the mountain peoples while providing goods and services to downstream users. In the large-scale land use change the role of cardamom agroforestry is quite promising for ecological and economic sustainability. Large cardamom agroforestry is almost a closed system that does not depend on the external input. The system requires about 800 to 1000 kg/ha of raw fuel-wood for curing the capsules that can be managed from the shade trees within the agroforestry. The annual production of woody biomass in cardamom based agroforestry ranges between 4.5 to 5.5 t/ha which is more than five times the fuel wood requirement for curing. The share of gross income from large cardamom (Rs. 20.7 million or 4.1

Figure 8. Acacia lecophloea and Acacia nilotica lopped for fodder in a Ravinous tract of Datiya (Madhya Pradesh), India.

million US $) was next to cereals over Sikkim state income from all crops for the year 1995-96. The benefit –cost ratio is more than 6 from the fourth year onwards (Sharma et al. 32)

Agroforestry for fodder production

Trees and shrubs often contribute substantial amounts of leaf fodder in arid and semi-arid and hill regions during the lean period, through lopping/pruning of trees, popularly known as top feed. The leaf fodder yield depends on species, initial age, lopping intensity and interval, as well as agro-climatic conditions. Fodder from trees is provided by leaf twigs and pods. This forage is usually rich in proteins, vitamins and minerals like calcium. They are however in general low in phosphorus and crude fibre. Top feed plays an important role in human food security through the function as an animal feed resource. The importance of top feeds increases with the severity of drought and progression of the drought season. Other uses such as for live fencing, are complementary, as they encourage cultivation of the species and increase the availability of feed. The top feeds are

Figure 7. Alder (Alnus nepalensis) agroforestry system of the eastern Himalaya.

considered very important in vegetation stabilisation and sustained productivity of rangelands. They also play an important role as windbreaks and by providing shade for grazing animals. The most important top feed species are Prosopis cineraria, Albizzia lebbeck. Acacia spp, Leucaena leucocephala, Dalbergia sissoo, Ailanthus excelsa, Azadiracta indica, Acacia leucophoela for the arid and semi –arid regions and Grewia optiva, Morus alba, Celtis australis for the hilly regions. Tree fodder provides enough nutrients and can serve very well as a green fodder supplement. In addition, leaves are also conserved in the form of hay and silage to supplement feed during shortages.

Agroforestry for bio-fuel production

A large part of India’s population, mostly in rural areas, does not have access to conventional source of energy. Biofuels are gaining worldwide acceptance as a solution for problems of environmental degradation, energy security, restriction of imports, rural employment and improving the agricultural economy. Trees with potential as biofuel include Jatropha curcas, Pongamia pinnata, Simarouba, Azadiracta indica, Madhuca spp., etc. In agroforestry these can be intercropped with annual crops such as cowpea, sesame, sunflower, French bean, black gram, green gram and groundnut. The promotion of oil crops also provides a poverty alleviation option in rural areas, as vacant waste and marginal land can be used for these trees, providing annual produce and income. The increased green cover will also benefit the environment. These oils are also CO2 neutral, mitigating the Green House Effect. The major source of biofuels in India is non-edible oil seeds i.e. tree borne oilseeds (TBOs). The requirement for TBOs in the country as per the National Oilseeds and Vegetable Oils Development Board, Gurgaon (India)

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exceeds 5 million tons. However, only 0.8-1.0 million tons are being collected from various species, such as Neem (Azadirachta indica), Karanj (Pongamia pinnata), Mahua (Madhuca longifolia), Jatropha (Jatropha curcas), Kusum (Schleichera oleosa), Pilu (Salvadora oleoides), Bhikal (Prinsepia utilis), Undi (Calophyllum inophyllum), Simarouba glauca, Sal (Shorea robusta) and Jojoba (Symondsia chinensis). Some of the TBO species can be grown in wasteland under relatively unfavourable environmental conditions and such species should be promoted. They meet the dual objectives of rehabilitating wasteland and providing an energy substitute (33). However, there is still a need for research on genetic improvement for increasing seed and oil yield.

Agroforestry for bio-energy

In rural areas 70-80% energy comes through biomass from trees and shrubs. Due to the agroforestry initiatives, large amounts of wood are now being produced from outside the conventional forestlands. Small landholdings and marginal farmers, through short rotation forestry and agroforestry practices are now providing the bulk of country’s domestically produced wood products. Prosopis juliflora is the major source of fuel for the power generation plants in Andhra Pradesh. The fuel wood potential of indigenous (Acacia nilotica, Azadirachta indica, Casuarina equisetifolia, Dalbergia sissoo, Prosopis cineraria and Ziziphus mauritiana) and exotic (Acacia auriculiformis, A. tortilis, Eucalyptus camaldulensis and E. tereticornis) trees with calorific values from 18.7 to 20.8 MJ DM kg-1for indigenous tree species and 17.3 to19.3 MJ DM kg-1 for exotics. Species such as C. equisetifolia, Prosopis juliflora, Leuceana leucocephala and Calliandra calothyrsus have become prominent due to their potential for providing wood energy of the highest efficiency, a shorter rotation and of high adaptability to diverse habitats and climates. Agroforestry plantations on community land and live fences on farm boundaries have immense potential in this regard. There is also an option for biomass-based power plants, where electricity generation can use crop/plant residue as another option. Chouhan et al. (34) conducted an extensive study on the socioeconomic status of fuelwood utilization in the Bendelkhand region of India and concluded that plantations of locally available multipurpose tree species can be promoted in the region in wasteland, community and private land (Fig 9).

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Figure 9. Fuelwood dependecy on trees in Bundelkhand region of central India.

Moreover, the use of biomass as one of the sources of energy (through agroforestry, for example) in the semi arid Bundelkhand region, not only improved livelihood, but will also bring better ecological health to this area. In continuation of this, Chavan et al. (35) carried out fuelwood analysis of farmer preferred tree species and recommended Acacia catechu, Acacia senegal, Anogeissus pendula and Prosopis juliflora as a best fuel-wood tree species for agroforestry plantation in the Bundelkhand region.

Economics of agroforestry systems in India

There are studies from different parts of the country suggesting that agroforestry is more profitable to farmers than agriculture or forestry for a particular area of land. Ram Newaj and Rai (36) analyzed 13 years of an aonla-based agroforestry system in marginal lands under rainfed conditions and found a B:C ratio of 3.28 (on a discounted rate, 2.61) which indicated its profitability. Similarly, there are studies indicating profitability of the system. A comprehensive analysis indicates (Table 5) their economic viability, with an IRR ranging from 25 to 68 and a B:C ratio of 1.01 to 4.17 for 24 agroforestry systems in various agro-climatic regions of the country (37). Agroforestry models adopted by farmers in the upper Gangetic region and especially in Haryana, Punjab and Western Uttar Pradesh are highly lucrative, therefore, being very attractive to farmers. In these areas poplar planted on agricultural fields and on field boundaries are harvested after a 6 to 8 year rotation, and the average economic return of poplar based agroforestry systems is very high compared to that of a sole agriculture crop. A kinnow-based horti-agricultural system is highly remunerative. In general, an average gross income of Rs.50,000

to Rs.1,00,000/acre (Rs.125000-250000/ ha) is obtained from a Kinnow plantation after 6-7 years depending upon tree density and management. The net return from the agricultural crops after 4 years of plantation is considerably less because of reduced yields. The economic feasibility of Eucalyptus hybrid both with and without agriculture under varying spacing viz. 2.5×2.5 m, 3×1.5 m, 4×2 m and 6×1 m in Haryana state was estimated by Dhillon and Bangarwa (38). This study indicates that cultivation of eucalyptus at wider spacing (6×1 m) with rotation of 8 years in combination with agricultural crops on farm lands gives a maximum NPV and B/C ratio of 2.28. The influence of eucalyptus trees grown as a single row on one side of the field in East-West direction on the growth and yield of wheat was studied in Haryana state. Poplar-based agroforestry has been very successful in Northern States, but we do not have a similar agroforestry model for other parts of the country, except for Eucalyptus and Casuarina. It was because of the success of these trees in Agroforestry, credit support was provided by banking institutions. Hence, there is tremendous scope for promoting viable agroforestry models for different agro-ecological regions of the country through quadripartite arrangement of industries, banks, research institutes and farmers. Research Institutes under the Indian Council of Forestry Research and Education and Indian Council for Agricultural Research have developed a number of agroforestry models, but these are mostly restricted to research farms. These models need to be used commercially for the improvement of the farmer’s livelihood. A Task Force sub-committee has identified technically feasible and financially viable agroforestry models for different agro-ecological regions of the country in order to solicit bank finance for tree farming (Table 5) (39).

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Table 5. Financial Analysis of prominent agroforestry systems in various agro-climatic zones of India.

National Agroforestry Policy of India

India launched the much-needed National Agroforestry Policy, 2014 –the first of its kind in the world. The New Agroforestry Policy is a path-breaker in making agroforestry an instrument for transforming lives of the rural farming population, protecting the ecosystem and ensuring food security through sustainable means. The major highlights of the Policy are: 1) establishment of Institutional setup at National level to promote Agroforestry under the mandate of Ministry of Agriculture; 2) simplification of regulations related to harvesting, felling and transportation of trees grown on farmlands; 3) ensuring security of land tenure and creating a sound base of land records and data for developing a Market Information System (MIS) for agroforestry; 4) investing in research, extension and capacity building and related services; 5) access to quality planting material; institutional credit and insurance cover to agroforestry practitioners; 6) increased participation of industries dealing with agroforestry produce;

7) strengthening marketing information system for tree products. Initially twenty important multipurpose tree species have been identified at the national level to be exempted from all restrictions related to harvesting, transportation and marketing grown under agroforestry systems (5).

Conclusions

The nurturing trees in fields or homestead gardens are historically a way of life in Indian culture. They are integral to our traditional farming systems, for the innumerable direct and indirect benefits that they provide. So these agroforestry systems act as a source of different tree based products, such as gums, resins, floss, fibers, fodder, brooms, fruits etc, for the subsistence of farmers. Therefore, agroforestry is considered to be the backbone of marginal farming for a self-reliant and sustainable agriculture. Achieving food security and environmental security is a prime benefit of agroforestry systems. The varied agroforestry systems in India form a strong feasible option to counter climate change. However, all of these approaches are an

attempt to reduce the ecological footprint focused at the farm scale, and not at the larger landscape level.

References

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