Abstract
Saline soils constitute 15% of global landmass and have direct influence on the production functions of the existing land uses. In India, 6.75 Mha area is salt-affected, out of which 2.92 Mha are saline soils. The menace, increasing with each passing year to the irrigated areas, has become a major concern. Agroforestry plays a pivotal role in biological amelioration and check in further expansion of such landmasses. It is always useful to have agroforestry models/systems for saline landmasses by involving multipurpose nitrogen-fixing tree species, fruit trees, halophytes, and arable crops of economic importance. The potential flora suitable to saline soils has been identified based on tolerance level and climatic adaptability. The successful planting methods, viz., ridge-trench, furrow, and subsurface planting with furrow irrigation, have also been assessed and recommended for saline soils. Plant adaptations to saline conditions involve complex physiological traits, metabolic pathways, and molecular gene networks. These adaptive mechanisms to such ecologies are basically governed by one of the three processes like exclusion, excretion, and accumulation among trees and/or crops. In true sense, reclamation processes also help to keep the salt away and/or within tolerable limits for growing flora in the rhizosphere. Productive service functions of plants can be obtained from saline soils by combining reclamation and management options in pragmatic way. Sequential, agrisilviculture, agrihorticulture, silvopastoral, multipurpose wood lots, saline aquaforestry, homestead gardens, and energy plantations are the biological and economical viable recommended farm agroforestry practices in saline soils. Prosopis cineraria (Khejri) for hot dryland, Eucalyptus tereticornis (Safeda), Melia composita (Dek), Aegle marmelos (Bael), Emblica officinalis (Aonla), and Carissa carandas (Karonda) for saline-irrigated area and Casuarina equisetifolia (Casuarina), Eucalyptus camaldulensis (Safeda), and Acacia nilotica (Babul) for coastal regions as agroforestry trees in system mode are successful in reclaiming the saline soils with economic gains for sustenance. The benefits of agroforestry can be grouped into biomass, soil/environment, and socioeconomic outputs. This chapter highlights the issues in the quantification of the systems’ output in terms of existing procedural protocols. The agroforestry has passed and transcends into variable phases with the advancement as subject. Therefore, plausible future of the agroforestry is presented by taking the cognizance of present needs and future challenges in general and particular about saline soils. The holistic approaches of agroforestry undoubtedly rehabilitate saline soils and certainly will give income in perpetuity, employment generation, food and nutritional security and environmental safety for inhabiting masses in arid and semiarid regions.
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References
Abrol IP,Yadav JSP, Massoud FI (1988) Salt affected soils and their management. FAO Soils Bulletin 39. FAO Soil Resource Management and Conservation Service FAO Land and Water Development Division, Food and Agriculture Organization of the United Nations, Rome
Allan GL, Fielder DS, Fitzsimmons KM, Raizada S (2009) Inland saline aquaculture. New Technologies in Aquaculture: Improving Production Efficiency. Quality and Environmental Management, pp 1119–1147
Banyal R (2013) Short rotation culture with Willows in hill farming systems. In book of proceedings national seminar on ‘Indian agriculture: present situation, challenges, remedies and road map’ Rachna publications, Pushpanjali Complex, Rajpur, Palampur, HP, pp 82–85
Banyal R, Yadav RK, Sheoran P, Parveen K, Bhardwaj AK, Rahul T (2017) Agroforestry approaches for rehabilitation of saline ecologies. In National Conference on Alternate Farming Systems to Enhance Farmers’ Income, 19–21 Sept 2017
CSSRI (1995) Annual Report. ICAR-Central Soil Salinity Research Institute, Karnal, Haryana-132 001, India
CSSRI (2010) Biosafor-Biosaline (agro) forestry: remediation of saline wastelands through production of renewable energy, biomaterials and fodder. Central Soil Salinity Research Institute, Karnal, India. Tech Bull 4, p 26
CSSRI (2013) Annual report. ICAR-Central Soil Salinity Research Institute, Karnal, Haryana-132 001, India
CSSRI (2014) Annual report. ICAR-Central Soil Salinity Research Institute, Karnal, Haryana-132 001, India
CSSRI (2016) Annual report. ICAR-Central Soil Salinity Research Institute, Karnal, Haryana-132 001, India
Dagar JC (2014) Greening salty and waterlogged lands through agroforestry systems for livelihood security and better environment. In: Dagar JC, Singh AK, Arunachalam A (eds) Agroforestry systems in India: livelihood security & ecosystem services. Advances in agroforestry 10, Springer, Dordrecht, pp 273–332
Dagar JC, Tewari JC (2016) Agroforestry research developments: anecdotal to modern science. In: Agroforestry research developments. Nova Publishers, New York, pp 1–45
Dagar JC, Yadav RK (2017) Climate resilient approaches for enhancing productivity of saline agriculture. J Soil Salinity Water Qual 9(1):9–21
Dagar JC, Singh G, Singh NT (2001) Evaluation of Forest and Fruit Trees Used for Rehabilitation of Semiarid Alkali-Sodic Soils in India. Arid Land Res Manag 15(2):115–133
Dagar JC, Tomar OS, Minhas PS, Singh Gurbachan, Ram Jeet (2008) Dryland biosaline agriculture-Hisar experience. Technical bulletin No. 6/2008, Central Soil Salinity Research Institute, Karnal, India, pp 28
Dagar JC, Pandey CB, Chaturvedi CS (2014) Agroforestry: a way forward for sustaining fragile coastal and island ecosystems. In: Dagar JC, Singh AK, Arunachalam A (eds) Agroforestry systems in India: livelihood security & ecosystem services. Advances in Agroforestry, vol 10. Springer, Dordrecht, pp 185–232
Dagar JC, Khajanchi L, Jeet R, Mukesh K, Chaudhary SK, Yadav RK, Sharif A, Gurbachan S, Amarinder K (2016a) Eucalyptus geometry in agroforestry on waterlogged saline soils influences plant and soil traits in North-West India. Agric Ecosyst Environ 233:33–42
Dagar JC, Yadav RK, Tomar OS, Minhas PS, Gajender LK (2016b) Fruit-based agroforestry systems for saline water-irrigated semi-arid hyperthermic camborthids soils of north-west India. Agrofor Syst 90(6):1123–1132
FAO (1997) Production yearbook. Food and Agricultural Organization, Rome, v 48
FAO (2000) Crops and drops: making the best use of water for agriculture. Food and agriculture Organization of the United Nations, Rome
FAO (2009) High level expert forum—how to feed the World in 2050. Economic and Social Development, Food and Agricultural Organization of the United Nations, Rome
Flowers TJ, Galal HK, Bromham L (2010) Evaluation of halophytes: multiple origins of salt tolerance in land plants. Functional. Plant Biol 37:604–612
Gajender, Jat HS, Raju R, Rai AK, Yadav RK, Sharma DK, Chaudhari SK, Singh Gurbachan (2016) Multi-enterprise agriculture for sustaining livelihood security of small farmers in Indo-Gangetic plains. Extended summaries vol 2: 4th international agronomy congress, Nov. 22–26, 2016, New Delhi, India, pp 1159–1160
Gupta SK (2015) Reclamation and management of water-logged saline soils. Agribiol Res 52(2):104–115
Gururaja Rao G, Chinchmalatpure Anil R., Arora Sanjay, Khandelwal MK, Sharma DK (2013) Coastal saline soils of Gujarat: problems and their management. Technical Bulletin: CSSRI/Karnal/2013/1, Central Soil Salinity Research Institute, Regional Research Station, Bharuch 392012, Gujarat, India, p 59
Howlett DS, Mosquera Losada MR, Nair PKR, Nair VD, Riguciro-Rodriguez (2011) Soil carbon storage in silvopastoral systems and a tree less pasture in northwestern Spain. J Environ Qual 40:825–832
James RA, Blake C, Byrt CS, Munns R (2011) Major genes for Na+ exclusion, Nax1 and Nax2 (wheat HKT1;4 and HKT1;5), decrease Na+ accumulation in bread wheat leaves under saline and waterlogged conditions. J Exp Bot 62(8):2939–2947
Kawasaki SH, Hiroyuki H, Shin-Ichi A, Koichi Y (2010) Growth of trees planted for rehabilitation of saline areas of wheat belt in western Australia. J Agr Res Qual 44(1):47–33
Kumar A, Lata C, Kumar P, Devi R, Singh K, Kulshrestha N, Yadav RK (2016) Salinity and drought induced changes in gas exchange attributes and chlorophyll fluorescence characteristics of crops. Indian. J Agric Sci 86(6):718–724
Lopez-Diaz ML, Rolo V, Moreno G (2011) Trees’ role in nitrogen leaching after organic mineral fertilization: A greenhouse experiment. J Environ Quality 40:853–859
Mandal AK, Sharma RC, Singh G, Dagar JC (2010) Computerized data base on salt affected soils in India. Central Soil Salinity Research Institute, Karnal, p 28
Mattsson E, Ostwald M, Nissanka SP, Holmer B, Palma M (2009) Recovery and Protection of Coastal Ecosystems after Tsunami Event and Potential for Participatory Forestry CDM—Examples from Sri Lanka. Ocean Coast Manage 52:1–9
Munns R (2005) Genes and salt tolerance: bringing them together. New Phytol 167(3):645–663
Munns R, Tester M (2008) Mechanisms of salinity tolerance. Annu Rev Plant Biol 59:651–681
NAAS (2015) Bio-drainage: an eco-friendly tool for combating waterlogging. Policy Paper 74, p 27
Nair PKR (2011) Agroforestry systems and environmental quality: introduction. J Environ Qual 40:784–790
Nair PKR, Dagar JC (1991) An approach to developing methodologies for evaluating agroforestry systems in India. Agrofor Syst 16:55–81
Olderman LR, Hakkeling RTA, Sombroek WG (1991) World map of the status of Human induced soil degradation-an explanatory note-Global assessment of soil degradation, GLASOD Wageningen. International Soil Reference and Information Centre, United National Environmental Program, Nairobi
Purushothaman CS, Sudhir R, Sharma KL, Ranjeet KR (2014) Production of tiger shrimp (Penaeus monodon) in potassium supplemented inland saline sub-surface water. J Appl Aquac 26:84–93
Qadir M, Qureshi RH, Ahmad N (2002) Amelioration of calcareous saline sodic soils through phytoremediation and chemical strategies. Soil Use Mange 18(4):381–385
Rahnama A, James RA, Poustini K, Munns R (2010) Stomatal conductance as a screen for osmotic stress tolerance in durum wheat growing in saline soil. Funct Plant Biol 37(3):255–263
Ram J, Dagar JC, Khajanchi L, Singh G, Toky OP, Tanwar V, Dar SR, Chauhan MK (2011) Bio-drainage to combat waterlogging increase farm productivity and sequester carbon in canal command areas of North West India. Curr Sci 100(11):1673–1680
Ramoliya PJ, Patel HM, Pandey AN (2004) Effect of salinization of soil on growth and macro- and micro-nutrient accumulation in seedlings of Salvadora persica (Salvadoraceae). For Ecol Manag 202:181–193
Rao DLN, Gill HS (1990) Nitrogen fixation and biomass production by annual and perennial legumes. Annual Res., CSSRI, Karnal
Ravender S, Kundu DK, Verma HN (2004) Alternate landuses of salt affected lands in the eastern region. In: Mittal SP (ed) Alternate use for sustainable production. Oriental publishers, Dehradun, pp 419–434
Reddy MP, Sanish S, Iyengar ERR (1992) Photosynthetic studies and compartmentation of ions in different tissues of Salicornia brachiata Roxb. under saline conditions. Photosynthetica 26:173–179
Reddy MP, Shah MT, Patolia JS (2008) Salvadora persica, a potential species for industrial oil production in semiarid saline and alkali soils. Ind Crop Prod 28:273–278
Sairam RK, Tyagi A (2004) Physiology and molecular biology of salinity stress tolerance in plants. Curr Sci 86(3):407–421
Shah M (2014) Forest, fish and fruit: An innovative agroforestry practice in coastal Bangladesh to reduce vulnerability due to climate change. The Guardian, 24 July 2014
Sharma RC (1998) Nature, extent and classification of salt affected soils. In: Tyagi NK, Minhas PS (eds) Agricultural salinity management in India. Central Soil Salinity Research Institute, Karnal, pp 21–40
Sharma DK, Chaudhri SK (2012) Agronomic research in salt affected soils of India: an overview. Indian J Agron 57:175–185
Sharma DK, Chaudhari SK, Anshuman S (2014) In salt affected soils agroforestry is a promising option. Indian Farming 63:19–22
Sharma DK, Thimmppa K, Chinchmalatpure Anil R, Mandal AK, Yadav RK, Chaudhari SK, Kumar Satyendra, Sikka AK (2015) Assessment of production and monetary losses from salt affected soils in India, Technical bulletin: ICAR-CSSRI/Karnal/2015/05
Sharma DK, Yadav Gajender, Yadav R.K, Mishra VK, Burman D, Singh Gurbachan, Sharma PC. (2016) Diversified farming systems for sustainable livelihood security of small farmers in salt-affected areas of Indo-Gangetic plains. Lead Papers vol 4 : 4th International Agronomy Congress, Nov. 22–26, 2016, New Delhi, India, pp 110–112
Singh G (2009a) Comparative productivity of P. cineraria and Tecomella undulata based agroforestry systems in degraded lands of Indian desert. J For Res 20(2):144–150
Singh G (2009b) Salinity-related desertification and management strategies: indian experience. Land Degrad Dev 20:476–486
Singh G, Dagar JC (2005) Greening sodic soils: Bichhian model. tech bulletin 2/2005. Central Soil Salinity Researc Institute, Karnal, 51p
Tanji KK (1995) Foreword. In: The salinization of land and water resources: human causes, extent, management and case studies. Centre for Resources and Environment Studies. The Australian National University, Pub. Cab International, Wallingford, Oxon
Tomar OS, Gupta RK, Dagar JC (1998) Afforestation techniques and evaluation of different tree species for waterlogged saline soils in semiarid tropics. Arid Soil Res Rehab 12(4):301–316
Tomar OS, Minhas PS, Sharma VK, Singh YP, Gupta RK (2003) Performance of 31 tree species and soil condition in a plantation established with saline irrigation. For Ecol Manag 177:333–346
Tonucci RG, Nair PKR, Nair VD, Garcia R, Bernardino FS (2011) Soil carbon storage in silvopasture and related land use systems in the Brazilian Cerrado. J Environ Qual 40:833–841
Wicke B, Smeets Edward MW, Razzaque A, Leon S, Ranjay SK, Abdul AR, Khalid M, Faaij Andre PC (2013) Biomass production in agroforestry and forestry systems on salt affected soils in South Asia: exploration of the GHG balance and economic performance of three case studies. J Environ Manag 127:324–334
Yadav RK, Dagar JC (2016) Innovations in utilization of poor-quality water for sustainable agricultural production. In: Dagar JC, Sharma PC, Sharma DK, Singh AK (eds) Innovative saline agriculture. Springer, India, pp 219–263
Yadav RK, Singh SP, Lal D, Kumar A (2007) Fodder production and soil health with conjunctive use of saline and good quality water in Ustipsamments of a semi-arid region. Land Degrad Dev 18(2):153–161
Zhang JL, Shi H (2013) Physiological and molecular mechanisms of plant salt tolerance. Photosynth Res 115:1–22
Zhu JK (2003) Regulation of ion homeostasis under salt stress. Curr Opin Plant Biol 6(5):441–445
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Banyal, R., Rajkumar, Kumar, M., Yadav, R.K., Dagar, J.C. (2017). Agroforestry for Rehabilitation and Sustenance of Saline Ecologies. In: Dagar, J., Tewari, V. (eds) Agroforestry. Springer, Singapore. https://doi.org/10.1007/978-981-10-7650-3_16
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