Refine your search
Collections
Co-Authors
Journals
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z All
Mandal, Uday
- Conceptualization of Community-Based Integrated Farming System Model Design with Multi-Objective Optimization Management
Abstract Views :269 |
PDF Views:112
Authors
Affiliations
1 Hydrology and Engineering Division, ICAR-Indian Institute of Soil and Water Conservation, 218-Kaulagarh Road, Dehradun 248 195, IN
2 ICAR-Indian Institute of Water Management, Bhubaneswar 751 023, IN
1 Hydrology and Engineering Division, ICAR-Indian Institute of Soil and Water Conservation, 218-Kaulagarh Road, Dehradun 248 195, IN
2 ICAR-Indian Institute of Water Management, Bhubaneswar 751 023, IN
Source
Current Science, Vol 112, No 11 (2017), Pagination: 2234-2242Abstract
Effective utilization of land and water resources is attempted in the present study through an integrated farming system and multi-objective optimization management framework model using goal programming algorithm in a coastal waterlogged paddy area in Odisha, India. A methodology is developed to identify the water harvesting structure locations in the study area using spatial science tool. Due to the uncertainty of parameters and control variables, development of management framework was considered with 85% and 75% probability of rainfall occurrence and runoff generation. To incorporate the uncertainties, a multi-objective linear goal programming optimization model is developed considering the objective of maximizing the net annual return and production subject to optimal allocation of land. While evaluating the model for different water resources scenarios, the net annual return is found to be Rs 4,343,474 and maximum production is 10,424 q from scenario I, whereas maximum production of 10,980 q is obtained in scenario II. Tomato and rice cultivation area increased from 11.47 to 21.43 ha and 8.82 to 10.48 ha respectively in scenario II. The developed methodology shows the potential applicability in similar farming situations in other areas.Keywords
Integrated Farming System, Land and Water Resources Management, Linear Goal Programming, Multiobjective Optimization.References
- Kumar, S. and Jain, D. K., Are linkages between crops and livestock important for the sustainability of the farming system? Asian Econ. Rev., 2005, 47(1), 90–101.
- http://www.indiaonlinepages.com/population/india-current-population.html
- FAO, World agriculture: towards 2030/2050 – Interim report, Food and Agricultural Organization of United Nations, Rome, Italy, 2006.
- http://www.thehindu.com/opinion/columns/sainath/over-2000-fewer-farmersevery-day/article4674190.ece
- SAC, Reports on coastal zones of India, Space Application Centre, Ahmedabad, 2012.
- Keating, B. A. and Mccown, R. L., Advances in farming systems analysis and intervention. Agric. Syst., 2001, 70, 555–579.
- Thornton, P. K. and Herrero, M., Integrated crop – livestock simulation models for scenario analysis and impact assessment. Agric. Syst., 2001, 70(2), 581–602.
- Behera, U. K., Yates, C. M., Kebreab, E. and France, J., Farming systems methodology for efficient resource management at the farm level: a review from an Indian perspective. J. Agric. Sci., 2008, 146(5), 493–505.
- Gill, M. S., Singh, J. P. and Gangwar, K. S., Integrated farming system and agriculture sustainability. Indian J. Agron., 2009, 54(2), 128–139.
- AICRP on IFS, Annual Report 2010–2011. Project Directorate Systems Research (ICAR), Modipuram, Meerut, India, 2011, p. 198.
- Kumar, S., Singh, S. S., Shivani and Dey, A., Integrated farming systems for Eastern India. Indian J. Agron., 2011, 56(4), 297–304.
- Nayak, R. C. and Panda, R. K., Integrated management of a canal command in a river delta using multi-objective techniques. Water Resour. Manage., 2002, 15(6), 383–401.
- Xevi, E. and Khan, S., A multi-objective optimization approach to water management. Environ. Manage., 2005, 77(4), 269–277.
- Amini Fasakhodi, A., Nouri, S. H. and Amini, M., Water resources sustainability and optimal cropping pattern in farming systems; a multi-objective fractional goal programming approach. Water Resour. Manage., 2010, 24(15), 4639–4657.
- Sethi, L. N., Panda, S. N. and Nayak, M. K., Optimal crop planning and water resources allocation in a coastal groundwater basin, Orissa, India. Agric. Water Manage., 2006, 83, 209–220.
- Panigrahi, D., Mohanty, P. K., Acharya, M. and Senapati, P. C., Optimal utilisation of natural resources for agricultural sustainability in rainfed hill plateaus of Orissa. Agric. Water Manage., 2010, 97(7), 1006–1016.
- Mandal, U., Dhar, A. and Panda, S. N., Integrated land and water resources management framework for Hirakud canal subcommand (India) using gray systems analysis, J. Water Resour. Plann. Manage., 2013, 139(6), 733–740.
- Sekar, I., Mcgarigal, K., Finn, J. T., Ryan, R. and Randhir, T. O., Dynamic simulation modelling to evaluate best management practices in integrated farming systems. Indian J. Soil Conserv., 2001, 40(2), 166–172.
- USDA (Soil Conservation Service), SCS National Engineering Hand Book. Section 4, Hydrology, USDA, Washington, DC, 1972.
- http://power.larc.nasa.gov/cgi-bin/cgiwrap/solar/agro.cgi?email=agroclim@larc.nasa.gov
- Charnes, A. and Cooper, W. W., Management Models and Industrial Applications of Linear Programming, Vol. I and Vol. II, John Wiley, New York, USA, 1961.
- Rao, K. V. R., Runoff estimation from daily total rainfall using curve number with varying site moisture. J. Irrig. Drain. Div., ASCE, 1995, 105, 439–441.
- FAO, 1986; http://www.fao.org/docrep/S2022E/S2022E00.htm
- Hargreaves, G. H. and Samani, Z. A., Reference crop evapotranspiration from temperature. Appl. Eng. Agric., 1985, 1, 96–99.
- Allen, R. G., Pereira, L. S., Raes, D. and Smith, M., Guideline for computing crop water requirement. Irrigation and Drainage Paper No. 56, FAO, Rome, Italy, 1998.
- Sharda, V. N., Sena, D. R., Shrimali, S. S. and Khola, O. P. S., Effects of an intercrop-based conservation bench terrace system on resource conservation and crop yields in a sub-humid climate in India. Trans. ASABE, 2013, 56(4) 1411–1425.
- Chang, Y. L., WinQSB: Dicision Support Software for MS/OM, John Wiley, New York, USA, 1998.
- Role of arbuscular mycorrhizal fungi in soil and water conservation: a potentially unexplored domain
Abstract Views :184 |
PDF Views:80
Authors
Affiliations
1 ICAR-Indian Institute of Soil and Water Conservation, Dehradun 248 195, IN
1 ICAR-Indian Institute of Soil and Water Conservation, Dehradun 248 195, IN
Source
Current Science, Vol 120, No 10 (2021), Pagination: 1573-1577Abstract
There is a general consensus that nature-based biological measures can be used as a valuable tool to improve land quality. Microbial technology, e.g. use of mycorrhizal fungi, has been considered a beneficial option in the rehabilitation of disturbed and degraded lands. Mycorrhizal fungi are extremely important to improve soil aggregation and in turn the porosity, erodibility and even soil fertility. This article provides an insight into how mycorrhizal fungi might play a role in reclamation and revegetation of degraded lands with special focus on soil and water conservation. External hyphae of arbuscular mycorrhizal fungi (AMF) can bind the small soil particles into micro aggregates by producing a glycoprotein (glomalin) which alone can account for 30–60% of carbon in undisturbed soils. Glomalin is derived specifically from the hyphae of AMF and has not been reported in any other fungal species. Besides agriculture, the presence of AMF in the grassland and forest ecosystems is also of great significance as it helps in establishment of native plant species, soil improvement and carbon storage. The increasing interest of soil conservationists in this glycoprotein is also highlighted in this article.Keywords
Arbuscular mycorrhizal fungi, carbon storage, degraded lands, glycoprotein, soil and water conservation.References
- Mandal, D. and Sharda, V. N., Assessment of permissible soil loss in India employing a quantitative bio-physical model. Curr. Sci., 2011, 100(3), 383–390.
- Mandal, D. and Tripathi, K. P., Soil erosion limits for Lakshadweep Archipelago. Curr. Sci., 2009, 96(2), 276–280.
- Mozafar, A., Anken, T., Ruh, R. and Frossard, E., Tillage intensity, mycorrhizal and nonmycorrhizal fungi, and nutrient concentrations in maize, wheat, and canola. Agron. J., 2000, 92, 1117–1124.
- Oehl, F., Sieverding, E., Ineichen, K., Mäder, P., Boller, T. and Wiemken, A., Impact of land use intensity on the species diversity of arbuscular mycorrhizal fungi in agroecosystems of central Europe. Appl. Environ. Microbiol., 2003, 69, 2816–2824.
- Lenka, N. K., Mandal, D. and Sudhishri, S., Permissible soil loss limits for different physiographic regions of West Bengal. Curr. Sci., 2014, 107(4), 665–670.
- Quoreshi, A. M., The use of mycorrhizal biotechnology in restoration of disturbed ecosystem. In Mycorrhizae: Sustainable Agriculture and Forestry (eds Siddiqui, Z. A. et al.), Springer Science + Business Media B.V., 2008, pp. 303–320.
- Hooker, J. E., Black, K. E., Perry, R. L. and Atkinson, D., Arbuscular mycorrhizal fungi induced alteration to ischolar_main longevity of poplar. Plant Soil, 1995, 172(2), 327–329.
- Yakop, F., Taha, H. and Shivanand, P., Isolation of fungi from various habitats and their possible bioremediation. Curr. Sci., 2019, 116(5), 733–740.
- Marschner, H. and Dell, B., Nutrient uptake in mycorrhizal symbiosis. Plant Soil, 1994, 159(1), 89–102.
- Piotrowski, J. S., Annis, S. L. and Longcore, J. E., Physiology of Batrachochytrium dendrobatidis, a chytrid pathogen of amphibians. Mycologia, 2004, 96(1), 9–15.
- Mandal, D. et al., 137Cs – a potential environmental marker for assessing erosion-induced soil organic carbon loss in India. Curr. Sci., 2019, 117(5), 865–871.
- Rillig, M. C., Sara, F. W. and Valerie, T. E., The role of arbuscular mycorrhizal fungi and glomalin in soil aggregation: comparing effects of five plant species. Plant Soil, 2002, 238, 325–333.
- Miller, R. M. and Jastrow, J. D., The role of mycorrhizal fungi in soil conservation. Mycorrhizae Sustain. Agric., 1992, 54, 29– 44.
- Costa, O. Y. A., Raaijmakers, J. M. and Kuramae, E. E., Microbial extracellular polymeric substances. Ecological function and impact on soil aggregates. Front. Microbiol., 2018, 9, 1636; doi:10.3389/fmicb.2018.01636.
- Graham, J. H. and Abott, L. K., Wheat responses to aggressive and non-aggressive arbuscular mycorrhizal fungi. Plant Soil, 2000, 220, 207–218.
- Xie, H., Li, J., Zhang, B., Wang, L., Wang, J., He, H. and Zhang, X., Long-term manure amendments reduced soil aggregate stability via redistribution of the glomalin-related soil protein in macroaggregates. Sci. Rep., 2015, 5, 14687.
- Mader, P., Fliessbach, A., Dubois, D., Gunst, L., Fried, P. and Niggli, U., Soil fertility and biodiversity in organic farming. Science, 2002, 296, 1694–1697; doi:10.1126/science.1071148.
- Wilson, G. W., Rice, C. W., Rillig, M. C., Springer, A. and Hartnett, D. C., Soil aggregation and carbon sequestration are tightly correlated with the abundance of arbuscular mycorrhizal fungi: results from long-term field experiments. Ecol. Lett., 2009, 12(5), 452–461.
- Domisch, T., Finér, L., Lehto, T. and Smolander, A., Effect of soil temperature on nutrient allocation and mycorrhizas in Scots pine seedlings. Plant Soil, 2002, 239(2), 173–185.
- Gavito, M. E., Olsson, P. A., Rouhier, H., Medina-Peñafiel, A., Jakobsen, I., Bago, A. and Azcón-Aguilar, C., Temperature constraints on the growth and functioning of ischolar_main organ cultures with arbuscular mycorrhizal fungi. New Phytol., 2005, 168(1), 179– 188.
- Wang, B., Funakoshi, D. M., Dalpe, Y. and Hamel, C., Phosphorus-32 absorption and translocation to host plants by arbuscular mycorrhizal fungi at low ischolar_main-zone temperature. Mycorrhiza, 2002, 12, 93–96.
- https://www.lebanonturf.com/education-center/biological-planttreatments/mycorrhizalfungi-and-ph-of-soil-or-water (accessed on 4 January 2020).
- Shukla, A., Kumar, A., Jha, A., Salunkhe, O. and Vyas, D., Soil moisture levels affect mycorrhization during early stages of development of agroforestry plants. Biol. Fert. Soils, 2013, 49(5), 545– 554.
- Auge, R. M., Water relations, drought and vesicular–arbuscular mycorrhizal symbiosis. Mycorrhiza, 2001, 11, 3–42.
- Mendoza, R., Escudero, V. and Garcia, I., Plant growth, nutrient acquisition and mycorrhizal symbioses of a waterlogging tolerant legume (Lotus glaber Mill.) in a saline–sodic soil. Plant Soil, 2005, 275, 305–315.
- Karasawa, T., Arihara, J. and Kasahara, Y., Effects of previous crops on arbuscular mycorrhizal formation and growth of maize under various soil moisture conditions. Soil Sci. Plant Nutr., 2000, 46, 53–60.
- Tahat, M. M. and Sijam, K., Mycorrhizal fungi and abiotic environmental conditions relationship. Res. J. Environ. Sci., 2012, 6(4), 125–188.
- Melin, E., Physiology of mycorrhizal relations in plants. Annu. Rev. Plant Physiol., 1953, 4, 325–346.
- Melin, E., Die Bedeutung der Mycorrhiza fur die Versorgung der Pflanze mit Mineralstoffen. In Handbuch der Pjlanzenphysiologie (ed. Ruhland, W.), Springer, Berlin, Germany, 1958, p. 1210.
- Paavilainen, E., On the effect of drainage on ischolar_main systems of Scots pine on peat soils. Commun. Inst. For. Fenn., 1966, 66(1), 1–100.
- Abbott, L. K. and Robson, A. D., The effect of soil pH on the formation of VA mycorrhizas by two species of Glomus. Soil Res., 1985, 23(2), 253–261.
- Wang, G. M., Stribley, D. P., Tinker, P. B. and Walker, C., Effects of pH on arbuscular mycorrhiza I. Field observations on the longterm liming experiments at Rothamsted and Woburn. New Phytol., 1993, 124(3), 465–472.
- Ouzounidou, G., Skiada, V., Papadopoulou, K. K., Stamatis, N., Kavvadias, V., Eleftheriadis, E. and Gaitis, F., Effects of soil pH and arbuscular mycorrhiza (AM) inoculation on growth and chemical composition of chia (Salvia hispanica L.) leaves. Braz. J. Bot., 2015, 38(3), 487–495.
- Richards, B. N., Soil pH and mycorrhiza development in Pinus. Nature, 1961, 190(4770), 105.
- Bakhshandeh, S., Corneo, P. E., Mariotte, P., Kertesz, M. A. and Dijkstra, F. A., Effect of crop rotation on mycorrhizal colonization and wheat yield under different fertilizer treatments. Agric. Ecosyst. Environ., 2017, 247, 130–136.
- Harinikumar, K. M. and Bagyaraj, D. J., Effect of crop rotation on native vesicular arbuscular mycorrhizal propagules in soil. Plant Soil, 1988, 110(1), 77–80.
- Haider, K. R., The effect of cropping rotation and management on arbuscular mycorrhizal fungi in a sustainable dairy cropping system, 2014; https://etda.libraries.psu.edu/catalog/22664 (accessed on 5 January 2020).
- Wu, F., Dong, M., Liu, Y., Ma, X., An, L., Young, J. P. W. and Feng, H., Effects of long-term fertilization on AM fungal community structure and Glomalin-related soil protein in the Loess Plateau of China. Plant Soil, 2011, 342(1–2), 233–247.
- Wright, S. F., Franke-Snyder, M., Morton, J. B. and Upadhyaya, A., Time-course study and partial characterization of a protein on hyphae of arbuscular mycorrhizal fungi during active colonization of ischolar_mains. Plant Soil, 1996, 181(2), 193–203.
- Wright, S. F., Rillig, M. C. and Nichols, K. A., Glomalin: a soil protein important in carbon sequestration. In Proceedings of the American Chemical Society Annual Meeting Symposium, 2000, pp. 721–725.
- Six, J., Bossuyt, H., Degryze, S. and Denef, K., A history of research on the link between (micro) aggregates, soil biota, and soil organic matter dynamics. Soil Till. Res., 2004, 79(1), 7–31.
- Morel, J. L., Habib, L., Plantureux, S. and Guckert, A., Influence of maize ischolar_main mucilage on soil aggregate stability. Plant Soil, 1991, 136(1), 111–119.
- Mardhiah, U., Caruso, T., Gurnell, A. and Rillig, M. C., Arbuscular mycorrhizal fungal hyphae reduce soil erosion by surface water flow in a greenhouse experiment. Appl. Soil Ecol., 2016, 99, 137–140; https://doi.org/10.1016/j.apsoil.2015.11.027
- Kimura, A. C. and Scotti, M. R., Soil aggregation and arbuscular mycorrhizal fungi as indicators of slope rehabilitation in the São Francisco River basin (Brazil). Soil Water Res., 2016, 11(2), 114–123.
- Celik, I., Ortas, I. and Kilic, S., Effects of compost, mycorrhiza, manure and fertilizer on some physical properties of a chromoxerert soil. Soil Till. Res., 2004, 78, 59–67.
- Bearden, B. N. and Petersen, L., Influence of arbuscular mycorrhizal fungi on soil structure and aggregate stability of a Vertisol. Plant Soil, 2000, 218, 173–183.
- Treseder, K. K. and Allen, M. F., Mycorrhizal fungi have a potential role in soil carbon storage under elevated CO2 and nitrogen deposition. New Phytol., 2000, 147, 189–200.
- Wright, S. F. and Anderson, R. L., Aggregate stability and glomalin in alternative crop rotations for the central Great Plains. Biol. Fert. Soil, 2000, 31(3–4), 249–253.
- Wang, W., Zhong, Z., Wang, Q., Wang, H., Fu, Y. and He, X., Glomalin contributed more to carbon, nutrients in deeper soils, and differently associated with climates and soil properties in vertical profiles. Sci. Rep., 2017, 7(1), 13003.
- Xu, M., Li, X., Cai, X., Li, X., Christie, P. and Zhang, J., Land use alters arbuscular mycorrhizal fungal communities and their potential role in carbon sequestration on the Tibetan Plateau. Sci. Rep.,
- , 7(1), 3067.
- Mandal, D., Giri, N. and Srivastava, P., The magnitude of erosioninduced carbon (C) flux and C-sequestration potential of eroded lands in India. Eur. J. Soil Sci., 2020, 71(2), 151–168.