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Srinivasarao, Ch.
- Performance of Concrete Containing Granulated Blast Furnace Slag as a Fine Aggregate
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Authors
Affiliations
1 KL University, Vaddeswaram - 522502, Andhra Pradesh, IN
2 Mallareddy College of Engineering, Hyderabad - 500043, Telangana, IN
1 KL University, Vaddeswaram - 522502, Andhra Pradesh, IN
2 Mallareddy College of Engineering, Hyderabad - 500043, Telangana, IN
Source
Indian Journal of Science and Technology, Vol 9, No 38 (2016), Pagination:Abstract
The present challenge in front of Civil Engineers is to find alternative materials for fine aggregates in concrete. Since, most of the State Govt. banned the dredging of river sand. The Granulated blast furnace slag is considered as a fine aggregate in concrete. At present, in India Steel Industry produces about 40 Million Tonnes by 2020 it is estimated to 60 million tonnes. The Author has investigated the effect of compressive strength of concrete, when Granulated blast furnace slag is used (GBFS) as a fine aggregate in concrete. The work includes the partially and fully replacement of river sand by granulated slag in M25 Grade of concrete with a constant 0.45 W/C ratio. Slag replacement of 50, 80, 100% are used. It has been observed that concrete made with 50% of river sand and 50% (GBFS) is nearer to Zero percent replacement. Objectives: To determine the optimum percentage slag replacement as a fine aggregate in concrete which helps in maintaining sustainability of concrete and balancing between the environmental problems due to construction industry as it is necessary to find out the alternative materials for use as fine aggregates because of restrictions by the local authorities. Methods: The experiments are planned to find out the optimum replacement percentage of GBFS against river sand as a fine aggregate in concrete. Mix design for M25 grade of concrete is made with OPC (Ordinary Portland Cement) and PPC (Port land Pozzolana Cement) is considered with a constant 0.45 W/C ratio and slag replacement of 50, 80, 100% are used. 30 Cubes for each cement category of 150 mm size are casted, cured by immersion and tested by CTM. Findings: In both the cement category, the compressive strength and slump of concrete is found reducing with the increase in the percentage of slag as a replacement to fine aggregate. In concrete made with OPC when compared with 50%, 80% and 100% replacement with GBFS reduction upto 96.50%, 87% and 77.5% in strength and 84.6%, 53.84% and 34.6% in slump respectively is observed. In concrete made with PPC when compared with 50%, 80% and 100% replacement with GBFS reduction upto 95.30%, 80% and 63% in strength and 82.7%, 51.7% and 34.0% in slump respectively is observed. Application/Improvements: This study using alternatives to fine aggregate in concrete will help in making concrete economical, reduction in environmental problems and saving the natural resources. The study may be extended to determine the concrete sustainability in saline conditions also.Keywords
Compressive Strength, Granulated Blast Furnace Slag, OPC, PPC, River Sand.- Alternative Sources of Soil Organic Amendments for Sustaining Soil Health and Crop Productivity in India – Impacts, Potential Availability, Constraints and Future Strategies
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Authors
A. K. Indoria
1,
K. L. Sharma
1,
K. Sammi Reddy
1,
Ch. Srinivasarao
1,
K. Srinivas
1,
S. S. Balloli
1,
M. Osman
1,
G. Pratibha
1,
N. S. Raju
1
Affiliations
1 ICAR-Central Research Institute for Dryland Agriculture, Hyderabad 500 059, IN
1 ICAR-Central Research Institute for Dryland Agriculture, Hyderabad 500 059, IN
Source
Current Science, Vol 115, No 11 (2018), Pagination: 2052-2062Abstract
Among the several causes, critical low soil organic matter status is predominant for decline in soil health and consequent fall in crop productivity. Over the years, availability of traditional source of soil organic amendment, viz. cattle manure drastically declined due to various reasons (domestic uses as fuel and plastering of the kachha houses). The present study highlights that there are many alternative sources of soil organic amendments available in the country which have tremendous potential to improve soil organic matter status and crop productivity, and rejuvenate and enhance the dying total factor productivity of Indian soils. Data from various sources reveal that about 300 million tonnes of alternative sources of soil organic amendments are available in the country. This study highlights that the application of alternative sources of organic amendments directly or indirectly improves soil health by influencing many soil properties (physical and chemical) and enzyme activities (biological) that regulate nutrient dynamics in the soil. Consequent upon improvement in soil environment, the application of alternative sources of soil organic amendments alone or along with recommended dose of fertilizers registered significantly higher yield in different crops across different agro-climatic conditions of the country. Composting and vermicomposting are the best strategies to convert the biomass of available alternative sources of organic amendments to plant nutrient-rich products.Keywords
Climate Change, Crop Productivity, Organic Amendments, Soil Health.References
- NAAS, Crop response to nutrient ratio. Policy Paper No. 42, National Academy of Agricultural Sciences, New Delhi, 2009, pp. 1–16.
- FAO, Fertilizer use by crop in India, Land and Plant Nutrition Management Service, Land and Water Development Division, Food and Agriculture Organization of the United Nations, Rome, 2005, pp. 1–45.
- Kassam, A., Sustainable soil management is more than what and how crops are grown. In Principles of Sustainable Soil Management in Agroecosystems (eds Lal, R. and Stewart, B. A.), CRC Press, Boca Raton, FL, USA, 2013, pp. 337–399.
- Acharya, C. L., Kapur, O. C. and Dixit, S. P., Moisture conservation for rainfed wheat production with alternative mulches and conservation tillage in the hills of north-west India. Soil Till. Res., 1998, 46, 153–163.
- Ghosh, S., Wilson, B., Ghoshal, S., Senapati, N. and Mandal, B., Organic amendments influence soil quality and carbon sequestration in the Indo-Gangetic plains of India. Agric. Ecosyst. Environ., 2012, 156, 134–141.
- Lal, R., Enhancing crop yield in the developing countries through restoration of the soil organic carbon pool in agricultural lands. Land Degrad. Dev., 2006, 17, 197–209.
- Chandra, R., Demand for food grains during 11th Plan and towards 2020. Policy Brief 28, National Centre for Agricultural Economics and Policy Research, New Delhi, 2009, pp. 1–4.
- FAI, Fertilizer Statistics 2009–2010, The Fertilizer Association of India, New Delhi, 2010 (also referred to various issues of Fertilizer Statistics).
- Jaga, P. K. and Patel, Y., An overview of fertilizers consumption in India: Determinants and outlook for 2020 – a review. Int. J. Sci. Eng. Technol., 2012, 1, 285–291.
- Tewatia, R. K., Developments in fertiliser consumption in India. Indian J. Agron. (3rd IAC: Special Issue), 2012, 57, 116–122.
- NAAS, Low and declining crop response to fertilizers. Policy Paper No. 35, National Academy of Agricultural Sciences, New Delhi, 2006, pp. 1–8.
- FAO, Current world fertilizer trends and outlook to 2015, Food and Agriculture Organization of the United Nations, Rome, 2011.
- Bhattacharyya, T. et al., Soils of India: historical perspective, classification and recent advances. Curr. Sci., 2013, 104, 1308– 1323.
- Bhattacharyya, T., Pal, D. K., Chandran, P., Ray, S. K., Mandal, C. and Telpande, B., Soil carbon storage capacity as a tool to prioritize areas for carbon sequestration. Curr. Sci., 2008, 95, 482–494.
- Rao, A. S., Soil health issues in rainfed agriculture. Indian J. Dryland Agric. Res. Dev., 2011, 26, 1–20.
- Sindhu, D. S. and Byerlee, D., Technical change and wheat productivity in the Indian Punjab in post-GR period. Working Paper 92-02, International Maize and Wheat Improvement Center, Mexico, 1992.
- Bhattacharyya, T. et al., Change in levels of carbon in soils over years of two important food production zones of India. Curr. Sci., 2007, 93, 1854–1863.
- NAAS, Management of crop residues in the context of conservation agriculture. Policy Paper No. 58, National Academy of Agricultural Sciences, New Delhi. 2012, pp. 1–12.
- Pappu, A., Saxena, M. and Asolekar, S. R., Solid wastes generation in India and their recycling potential in building materials. Build. Environ., 2007, 42, 2311–2320.
- Sengupta, J., Recycling of agro-industrial wastes for manufacturing of building materials and components in India. An overview. Civ. Eng. Constr. Rev., 2002, 15, 23–33.
- Chanakya, H. N., Ramachandra, T. V. and Vijayachamundeeswari, M., Anaerobic digestion and reuse of digested products of selected components of urban solid waste. In Technical Report of Centre for Ecological Sciences and Centre for Sustainable Technologies, Technical Report No. 114, Indian Institute of Science, Bengaluru, 2006, pp. 1–109.
- The Hindu News Paper, Benefits from poultry manure – no chicken feed. The Hindu, Chennai edn, 22 October 2009.
- Vijaya, D., Padmadevi, S. N., Vasandha, S., Meerabhai, R. S. and Chellapandi, P., Effect of vermicomposted coir pith on the growth of Andrographis paniculata. J. Org. Syst., 2008, 3, 51–56.
- Singh, R., Singh, R., Soni, S. K., Singh, S. P., Chauhan, U. K. and Kalra, A., Vermicomposting from biodegraded distillation waste improves soil properties and essential oil yield of Pogostemon cablin (patchouli) Benth. Appl. Soil Ecol., 2013, 70, 48–56.
- Gunathilagaraj, K. and Ravignanam, T., Vermicomposting of sericultural wastes. Madras Agric. J., 1996, 83, 455–457.
- Pathak, H., Bhatia, A., Jain, N. and Aggarwal, P. K., Greenhouse gas emission and mitigation in Indian agriculture – a review. In ING Bulletins on Regional Assessment of Reactive Nitrogen (ed. Singh, B.), Society for Conservation of Nature (SCON)-Indian Nitrogen Group (ING), New Delhi, 2010, Bulletin No. 19, p. 34.
- Sharma, K. L. et al., Effect of graded levels of surface crop residue application under minimum tillage on carbon pools and carbon lability index in sorghum (Sorghum bicolor (l.) Moench) – cowpea (Vigna unguiculata) system in rainfed Alfisols. Commun. Soil Sci. Plant Anal., 2017, 48, 2506–2513.
- Sharma, K. L. et al., Long-term effects of soil and nutrient management practices on soil properties and additive soil quality indices in SAT Alfisols. Indian J. Dryland Agric. Res. Dev., 2014, 29, 56–65.
- Singh, Y. B. S., Ladha, J. K., Khind, C. S., Khera, T. S. and Bueno, C. S., Effects of residue decomposition on productivity and soil fertility in rice–wheat rotation. Soil Sci. Soc. Am. J., 2004, 68, 854–864.
- Varsney, J. G., Sushilkumar and Mishra, J. S., Current status of aquatic weeds and their management in India. In Proceedings of TAAL 2007, 12th World Lake Conference, Jaipur, Rajasthan (eds Sengupta, M. and Dalwani, R.), 2008, pp. 1039–1045.
- Murugesan, A. G., Ruby, J., Paulraj, M. G. and Sukumaran, N., Impact of different densities and temperature regimes on the feeding behaviour of water hyacinth weevils, Necochetina bruchi and Neochetina eichhorniae on Eichhornia crassipes. Asian J. Microbiol. Biotechnol. Environ. Sci., 2005, 7, 73–76.
- Sharda, V. and Lakshmi, G., Water hyacinth as a green manure for organic farming. Int. J. Res. Appl. Nat. Soc. Sci., 2014, 2, 65–72.
- Gandhi, A. and Sundari, U. S., Effect of vermicompost prepared from aquatic weeds on growth and yield of eggplant (Solanum melongena L.). J. Biofertil. Biopestic., 2012, 3, 128.
- DWSR, Marching Ahead, Directorate of Weed Science Research, Jabalpur, 2014, pp. 1–52.
- Prihar, S. S. and Arora, V. K., Crop response to mulching with crops in Punjab. Research Bulletin, Department of Soils, PAU Ludhiana, 1979, pp. 1–35.
- Biradar, A. P. and Patil, M. B., Studies on utilization of prominent weeds for vermiculturing. Indian J. Weed Sci., 2001, 33, 229–230.
- Kumar, V. and Verma, S. K., Influence of use of organic manure in combination with inorganic fertilizers on sugarcane and soil fertility. Indian Sugar, 2002, 52, 177–181.
- Thiyageshwari, S., Gayathri, P., Krishnamoorthy, R., Anandham, R. and Paul, D., Exploration of rice husk compost as an alternate organic manure to enhance the productivity of blackgram in typic Haplustalf and typic Rhodustalf. Int. J. Environ. Res. Publ. Health, 2018, 15, 358; doi:10.3390/ijerph15020358.
- Rangaraj, T, Somasundaram, E. M., Amanullah, M., Thirumurugan, V., Ramesh, S. and Ravi, S., Effect of agroindustrial wastes on soil properties and yield of irrigated finger millet (Eleusine coracana L. Gaertn) in coastal soil. Res. J. Agric. Biol. Sci., 2007, 3, 153–156.
- Singhal, S. and Pandey, S., Solid waste management in India – status and future directions. Inf. Monitor Environ. Sci., 2001, 6, 1–4.
- Indoria, A. K., Mehta, S. C., Poonia, S. R., Sharma, M. K. and Panwar, B. S., Effect of sewage sludge and farmyard manure on the Ni sorption in a sandy loam soil. Ann. Agri. Bio Res., 2006, 11, 15–20.
- Indoria, A. K., Mehta, S. C., Poonia, S. R. and Kaushik, R. D., Effect of sewage sludge and farmyard manure on the adsorption of cadmium in a sandy loam soil of Haryana. Environ. Ecol., 2008, 26, 1676–1679.
- Sharma, B., Sarkar, A., Singh, P. and Singh, R. P., Agricultural utilization of biosolids: a review on potential effects on soil and plant grown. Waste Manage., 2017, 64, 117–132.
- Indoria, A. K. and Poonia, S. R., Phytoextractibility of lead from soil by some oilseed crops as affected by sewage sludge and farmyard manure. Arch. Agron. Soil Sci., 2006, 52, 667–677.
- Indoria, A. K., Poonia, S. R. and Sharma, K. L., Phytoextractability of Cd from soil by some oilseed species as affected by sewage sludge and farmyard manure. Commun. Soil Sci. Plant Anal., 2013, 44, 3444–3455.
- Mondal, S., Singh, R. D., Patrab, A. K. and Dwivedi, B. S., Changes in soil quality in response to short-term application of municipal sewage sludge in a typic Haplustept under cowpea– wheat cropping system. Environ. Nanotechnol. Monit. Manage., 2015, 4, 37–41.
- Department of Atomic Energy, Government of India; http://dae.nic.in/ (accessed on 6 January 2016).
- Alling, V. et al., The role of biochar in retaining nutrients in amended tropical soils. J. Plant Nutr. Soil Sci., 2014, 177, 671– 680.
- Srinivasarao, Ch. et al., Use of biochar for soil health management and greenhouse gas mitigation in India: Potential and constraints, Central Research Institute for Dryland Agriculture, Hyderabad, 2013, pp. 1–51.
- Mukherjee, A. and Lal, R., Biochar impacts on soil physical properties and greenhouse gas emissions. Agronomy, 2013, 3, 311– 318.
- Mandal, S., Singh, R. K., Kumar, A., Verma, B. C. and Ngachan, S. V., Characteristics of weed biomass-derived biochar and their effect on properties of beehive briquettes. Indian J. Hill Farming, 2013, 26, 8–12.
- Kannan, K., Selvi, V., Singh, D. V., Khola, O. P. S., Mohanraj, R. and Murugesan, A., Coir pith composting – an alternate source of organic manure for rainfed maize. In Coirpith Composting Brouchure, Central Soil and Water Conservation Research and Training Institute, Research Centre, Udhagamandalam, 2013, pp. 1–2.
- Ramalingam, A., Gangatharan, M. and Kasturi, R., Solid state bio-treatment of coir pith and paddy straw. Asian J. Microbiol. Biotechnol. Environ. Sci., 2005, 6, 141–142.
- Nedgwa, P. M. and Thompson, S. A., Integrating composting and vermicomposting in treatment and bioconversion of biosolids. Bioresour. Technol., 2001, 76, 107–112.
- Sudhakar, G., Investigation to identify crop wastes/low land weeds as alternative sources to organic to sustain the productivity of rice based system. Ph D thesis, Tamil Nadu Agricultural University, Coimbatore, 2000, pp. 1–318.
- Nagavallemma, K. P. et al., Vermicomposting: recycling wastes into valuable organic fertilizer. Global Theme on Agroecosystems Report No. 8, International Crops Research Institute for the SemiArid Tropics, Patancheru, 2004, p. 20.
- Padmavathiamma, K. P., Li, Y. L. and Kumar, U. R., An experimental study of vermin-biowaste composting for agricultural soil improvement. Bioresour. Technol., 2008, 31, 31–23.
- Ramesh, P., Singh, M. and Singh, A. B., Performance of macaroni (Triticum durum) and bread wheat (Triticum aestivum) varieties with organic and inorganic sources of nutrients under limited irrigated conditions of vertisols. Indian J. Agric. Sci., 2005, 78, 351–354.
- Das, P. K., Bhogesha, K., Sundareswaran, P., Madhana Rao, Y. R. and Sharma, D. D., Vermiculture: scope and potentiality in sericulture. Indian Silk, 1997, 36, 23–26.
- Bhogesha, K., Das, P. K. and Madhava Rao, Y. R., Effect of various sericultural composts on mulberry leaf yield and quality under irrigated condition. Indian J. Sericult., 1997, 36, 30–34.
- Kalaiyarasan, V., Nandhini, D. U. and Udhayakumar, K., Seriwaste vermicompost – a trend of new sustainable generation – a review. Agric. Rev., 2015, 36, 159–163.
- Rama Laxmi, C. S., Innovative practices: wealth out of seri-waste. Indian Silk, 2013, 3, 10–11.
- Nalatwadmath, S. K., Patil, S. L., Adhikari, R. N. and Mana Mohan, S., Effect of crop residue management on soil erosion, moisture conservation, soil properties and sorghum yield on Vertisols under dryland conditions of semi arid tropics in India. Indian J. Dryland Agric. Res. Dev., 2006, 21, 99–104.
- Sharma, K. L. et al., Long term evaluation of reduced tillage and low cost conjunctive nutrient management practices on productivity, sustainability, profitability and energy use efficiency in sorghum (Sorghum bicolor (L.) Moench) – mung bean (Vigna radiata (L.) Wilczek) system in rainfed semi-arid Alfisol. Indian J. Dryland Agric. Res. Dev., 2015, 30, 50–57.
- Osman, M., Wani, S. P., Vineela, C. and Murali, R., Quantification of nutrients recycled by tank silt and its impact on soil and crop – a pilot study in Warangal district of Andhra Pradesh. Global Theme on Agroecosystems Report no. 52, International Crops Research Institute for Semi-Arid Tropics, Patancheru, 2009, p. 20.
- Sharma, S. K., Sharma, R. K., Kothari, A. K., Osman, M. and Chary, G. R., Effect of tank silt application on productivity and economics of maize-based production system in southern Rajasthan. Indian J. Dryland Agric. Res. Dev., 2015, 30, 24–29.
- Osman, M. et al., Enhancing rainwater productivity and economic viability of rainfed crops through tank silt application. Indian J. Dryland Agric. Res. Dev., 2015, 30, 17–23.
- Sharma, S., Bhattacharya, S. and Garg, A., Greenhouse gas emission from India: a prospective. Curr. Sci., 2006, 90, 326–332.
- Garg, A., Bhattacharya, S., Shukla, P. R. and Dadhwal, V. K., Regional and sectoral assessment of greenhouse gas emissions in India. Atmos. Environ., 2001, 35, 2679–2695.
- Jain., N., Bhatia, A. and Pathak, H., Emission of air pollutants from crop residue burning in India. Aerosol Air Qual. Res., 2014, 14, 422–430.
- Gadi, R., Kulshrestha, U. C., Sarkar, A. K., Garg, S. C. and Parashar, D. C., Emissions of SO2 and NOx from bio-fuels in India. Tellus, 2003, 55, 787–795.
- Smith, P. et al., Greenhouse gas mitigation in agriculture. Philos. Trans. R. Soc. London, Ser. B., 2008, 363, 789–813.
- Lampkin, N. H., Organic farming in the European Union: overview, policies and perspectives. In Organic Farming in the European Union: Overview, Policies and Perspectives for the 21st century, Proceedings of a Joint EU and Austrian Conference, Avalon Foundation and Eurotech Management, Vienna, Baden, 27–28 May 1999, pp. 23–30.
- Kumar, S., Masto, R. E., Ram, L. C., Sarkar, P., George, J. and Selvi, V. A., Biochar preparation from Parthenium hysterophorus and its potential use in soil application. Ecol. Eng., 2013, 55, 67– 72.
- Niggli, U., Fliessbach, A., Hepperly, P. and Scialabba, N., Low greenhouse gas agriculture: mitigation and adaptation potential of sustainable farming systems. FAO, Rome, April 2009; ftp://ftp.fao.org/docrep/fao/010/ai781e/ai781e00.pdf
- Srinivasarao, Ch., Indoria, A. K. and Sharma, K. L., Effective management practices for improving soil organic matter for increasing crop productivity in rainfed agroecology of India. Curr. Sci., 2017, 112, 1497–1504.
- Indoria, A. K., Sharma, K. L., Sammi Reddy, K. and Srinivasarao, Ch., Role of soil physical properties in soil health management and crop productivity in rainfed systems – II. Management technologies and crop productivity. Curr. Sci., 2016, 110, 320–328.
- Indoria, A. K., Sharma, K. L., Sammi Reddy, K. and Srinivasarao, Ch., Role of soil physical properties in soil health management and crop productivity in rainfed systems – I: Soil physical constraints and scope. Curr. Sci., 2017, 112, 2405–2414.
- Indoria, A. K., Srinivasarao, Ch., Sharma, K. L. and Sammi Reddy, K., Conservation agriculture – a panacea to improve soil physical health. Curr. Sci., 2017, 112, 52–61.
- Soil Degradation Challenges for Sustainable Agriculture in Tropical India
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PDF Views:82
Authors
Ch. Srinivasarao
1,
S. Rakesh
1,
G. Ranjith Kumar
1,
R. Manasa
1,
G. Somashekar
1,
C. Subha Lakshmi1
1,
Sumanta Kundu
2
Affiliations
1 Indian Council of Agricultural Research (ICAR)-National Academy of Agricultural Research Management, Rajendranagar, Hyderabad 500 030, IN
2 ICAR-Central Research Institute for Dryland Agriculture, Hyderabad 500 059, IN
1 Indian Council of Agricultural Research (ICAR)-National Academy of Agricultural Research Management, Rajendranagar, Hyderabad 500 030, IN
2 ICAR-Central Research Institute for Dryland Agriculture, Hyderabad 500 059, IN
Source
Current Science, Vol 120, No 3 (2021), Pagination: 492-500Abstract
Soil degradation is a pervasive, systemic phenomenon and an urgent priority in order to ensure human wellbeing, protect biodiversity and ecosystem services. Agriculture sector is frequently affected by soil loss resulting into unproductive soil and lowered crop yields. This article focuses on critical sustainable challenges of Indian agriculture, soil degradation status and mitigation strategies as well as policies and management response options in respect of development of degraded lands. It also provides policymakers with the necessary information to develop appropriate mitigation technologies at the local, regional and national scale.Keywords
Soil Degradation, Sustainable Agriculture, Mitigation Strategies, Policies.References
- Looking Back to Change Track: GREEN India 2047 Renewed (eds Datt, D. and Nischal, S.), TERI Press, New Delhi, 2010, p. 219.
- Bhattacharyya, R. et al., Soil degradation in India: challenges and potential solutions. Sustainability, 2015, 7, 3528–3570; doi:10.3390/su7043528.
- Singh, S. K. and Parihar, P., Challenges of sustainable agriculture development in India. J. Nat. Resour. Policy Res., 2015, 2(5), 355–359.
- Alam, A., Soil degradation: a challenge to sustainable agriculture. Int. J. Sci. Res. Agric. Sci., 2014, 1(4), 50–55.
- Singh, D. K. and Singh, A. K., Groundwater situation in India: problems and perspective. Int. J. Water Res. Dev., 2002, 18(4), 563–580.
- Munns, R., Genes and salt tolerance: bringing them together. New Phytol., 2005, 167, 645–663.
- Wicke, B. et al., The global technical and economic potential of bioenergy from salt-affected soils. Energy. Environ. Sci., 2011, 4, 2669–2681.
- Singh, R., Singh, H. and Raghubanshi, A. S., Challenges and opportunities for agricultural sustainability in changing climate scenarios: a perspective on Indian agriculture. J. Trop. Ecol., 2019, 60(2), 167–185.
- Sreekanth, M., Hakeem, A. H., Ahmed, Q. J. P. and Rashid, I., Low productivity of Indian agriculture with special reference on cereals. J. Pharm. Pharmacol., 2017, 6(5), 239–243.
- Dhruvanarayana, V. V. and Babu, R., Estimation of soil erosion in India. J. Irrig. Drain. Eng., 1983, 109(4), 419–434.
- Mythili, G. and Goedecke, J., Economics of land degradation in India. In Economics of Land Degradation and Improvement – A Global Assessment for Sustainable Development (eds Nkonya, E. et al.), Springer Open, 2016, Chapter 15, pp. 431–469; doi:10.1007/978-3-319-19168-3_15.
- Mythili, G. and Jann, G., Economics of land degradation in India; 2016; doi:10.1007/978-3-319-19168-3_15.
- Subudhi, C. R. and Subudhi, R., Effect of contour bunding on yield of maize crop in north Eastern Ghat zones of Odisha. Int. J. Agric. Res., 2018, 5(9), 19–20; ISSN 2394-5907 (Print) and ISSN 2394-5915 (on-line).
- Egarter-Vigl, L., Depellegrin, D., Pereira, P., De Gischolar_main, D. and Tappeiner, U., Mapping the ecosystem service delivery chain: capacity, flow, and demand pertaining to aesthetic experiences in mountain landscapes. Sci. Total Environ., 2017, 574, 436–442; http://dx.doi.org/10.1016/j.scitotenv.2016.08.209.
- Fawusi, M. O. A., Influence of spatial arrangements on the growth: fruit and grain yields and yield components of intercropped maize and okra (Abelmoschus esculentus). Field Crops Res., 1985, 11, 345–352.
- Singh, R. J., Ahlawat, I. P. S. and Sharma, N. K., Resource use efficiency of transgenic cotton and peanut intercropping system using modified fertilization technique. Int. J. Plant Prod., 2015, 9(4), 523–540.
- Khola, O. P. S., Dube, R. K. and Sharma, N. K., Conservation and production ability of maize (Zea mays)-legume intercropping systems under varying dates of sowing. Indian J. Agron., 1999, 44(1), 40–46.
- Sharma, P. C. and Singh, A., Overview of salinity management in agriculture with emphasis on India. In Quality Seed Production, Processing and Certification of Selected Field and Vegetable Crops in Salt Affected Areas, Training Manual, ICAR-Central Soil Salinity Research Institute, Karnal, 2016, pp. 1–7.
- Kamanga, B. C., Kanyama-Phiri, G. Y., Waddington, S. R., Almekinders, C. J. and Giller, E., The evaluation and adoption of annual legumes by smallholder maize farmers for soil fertility maintenance and food diversity in central Malawi. Food Secur., 2014, 6, 45–59.
- Venkatesh, M. S. et al., Long-term effect of crop rotation and nutrient management on soil–plant nutrient cycling and nutrient budgeting in Indo-Gangetic plains of India. Arch. Agron. Soil. Sci., 2017; doi:10.1080/03650340.2017.1320392.
- Liu, Q. J., Zhang, H. Y., An, J. and Wu, Y. Z., Soil erosion processes on row sideslopes within contour ridging systems. Catena, 2014, 115, 11–18.
- Srinivasarao, Ch., Venkateswarlu, B., Dixit, S., Kundu, S. and Gayatri Devi, K., Livelihood impacts of soil health improvement in backward and tribal districts of Andhra Pradesh, CRIDA, Hyderabad, 2011, pp. 1–119.
- Srinivasarao, Ch., Sharma, K. L. and Kundu, S., Potential soil carbon sequestration in different land use management systems in peninsular India. In Carbon Management in Tropical and SubTropical Terrestrial Systems (Ghosh, P. K. et al.), Springer Nature, 2020, pp. 3–21; https://doi.org/10.1007/978-981-13-96281.
- Karad, G. U., Viradiya, M. B., Deshmukh, S. P. and Rajkumar, S., Long term effect of integrated nutrient management on yield and carbon mineralization under groundnut–wheat cropping system in medium black calcareous soil. Environ. Conserv., 2016, 22, 1465–1471.
- Srinivasarao, Ch., Indoria, A. K. and Sharma, K. L., Effective management practices for improving soil organic matter for increasing crop productivity in rainfed agroecology of India. Curr. Sci., 2017, 112, 1497–1504.
- Bharali, A., Baruah, K. K., Baruah, S. G. and Bhattacharyya, P., Impacts of integrated nutrient management on methane emission, global warming potential and carbon storage capacity in rice grown in a northeast India soil. Environ. Sci. Pollut. Res., 2017; https://doi.org/10.1007/s11356-017-0879-0.
- CSWCR&TI, Annual Report, Central Soil Water Conservation Research and Training Institute, Dehradun, 2012.
- Srinivasarao, Ch. et al., Carbon sequestration strategies under rainfed production systems of India. CRIDA, Hyderabad, 2009, 102, 102.
- Srinivasarao, Ch. et al., Carbon stocks in different soils under diverse rainfed production systems in tropical India. Commun. Soil Sci. Plant Anal., 2009, 40, 2338–2356.
- Srinivasarao, Ch., Lal, R., Kundu, S., Prasad Babu, M. B. B., Venkateswarlu, B. and Singh, K., Soil carbon sequestration in rainfed production systems in the semiarid tropics of India. Sci. Total Environ., 2014, 487, 587–603.
- Srinivasarao, Ch., Subha Lakshmi, C., Sumanta Kundu, S., Ranjith Kumar, G., Manasa, R. and Rakesh, S., Integrated nutrient management strategies for rainfed agro-ecosystems of India. Indian J. Fert., 2020, 16(4), 344–361.
- Ahmad, N., Hassan, F. and Qadir, G., Effect of subsurface soil compaction and improvement measures on soil properties. Int. J. Agric. Biol., 2007, 9, 509–513.
- Singh, K., Choudhary, O. P. and Singh, H., Effects of subsoiling on sugarcane productivity and soil properties. J. Dairy Res., 2012, 2(1), 32–36.
- FAO, what is conservation? Food and Agriculture Organization, Rome, Italy, 2010; http://www.fao.org/ag/ca.Ia.html (accessed on 28 October 2010).
- Ghosh, B. N., Dogra, P., Sharma, N. K.., Bhattacharyya, R. and Mishra, P. K., Conservation agriculture impact for soil conservation in maize–wheat cropping system in the Indian sub-Himalayas. Int. Soil Water Conserv. Res., 2015, 3(2), 112–118; ISSN 20956339; https://doi.org/10.1016/j.iswcr.2015.05.001
- Bhattacharyya, R., Tuti, M. D., Bisht, J. K., Bhatt, J. C. and Gupta, H. S., Conservation tillage and fertilization impacts on soil aggregation and carbon pools in the Indian Himalayas under an irrigated rice–wheat rotation. Soil Sci., 2012, 177, 218–228.
- Bhattacharyya, R., Fullen, M. A., Davies, K. and Booth, C. A., Use of palm-mat geo textiles for rain splash erosion control. Geomorphology, 2010, 119, 52–61.
- Singh, V. K. et al., Soil physical properties: yield trends and economics after five years of conservation agriculture based ricemaize system in north-western India. Soil Till. Res., 2016, 155, 133–148.
- Sinha, A. K. et al., Trends in key soil parameters under conservation agriculture-based sustainable intensification farming practices in the Eastern Ganga Alluvial Plains. Soil Res., 2019; https://doi.org/10.1071/SR19162.
- Sasikala, V., Tiwari, R. and Saravanam, M., A review on integrated farming system. J. Int. Acad. Res. Multidisc., 2015, 3(7), 319–328; ISSN: 2320-5083.
- Manjunatha, S. B., Shivmurthy, D., Sunil, A. S., Nagaraj, M. V. and Basavesha, K. N., Integrated farming system – an holistic approach: a review. Research and Reviews: J. Agric. Allied Sci., 2014, 3(4), 30–38; ISSN: 2319-9857 p-ISSN: 2347-226X.
- Lal, M., Patidar, J., Kumar, S. and Patidar, P., Different integrated farming system model for irrigated condition of India on basis of economic assessment: a case study: a review Int. J. Mol. Sci., 2018, 6(4), 166–175; ISSN: 2349–8528 E-ISSN: 2321–4902.
- Tripathi, S. C. and Rathi, R. C., Livestock farming system module for hills. In Souvenir, National Symposium on Technological Interventions for Sustainable Agriculture, GBPUAT, Hill Campus, Ranichuri, 3–5 May 2011, pp. 103–104.
- Mohanty, D., Patnaik, S. C., Jeevan Das, P., Parida, N. K. and Nedunchezhiyan, M., Sustainable livelihood: a success story of a tribal farmer, Orissa Review, September 2010, pp. 41–43.
- Srinivasrao, Ch., Ravindra Chary, G., Mishra, P. K., Subba Reddy, G., Sankar, G. R. M., Venkateswarlu, B. and Sikka, A. K., Rainfed farming – a compendium of doable technologies, All India Coordinated Research Project for Dryland Agriculture, Central Research Institute for Dryland Agriculture, Hyderabad, 2014, p. 194.
- Srinivasarao, Ch., Gopinath, K. A., Prasad, J. V. N. S., Prasannakumar and Singh, A. K., Climate resilient villages for sustainable food security in tropical India: concept, process, technologies institutions and impacts. Adv. Agron., 2016, 140(3), 101–214.
- Thamizoli, P. R., Rengalakshmi, K., Senthilkumar and Selvaraju, T., Agronomic rehabilitation and livelihood restoration of tsunami affected lands in Nagapattinam District of Tamil Nadu, M.S. Swaminathan Research Foundation, Chennai, 2006, p. 31.
- Nair, T., India to launch a brave new initiative to save the Critically Endangered Gharial. SPECIES – Mag. Spec. Surv. Commun., 2011, 21, 53.
- Mrinmoy, D., Gulab, Y. and Anup, D., Agroforestry and soil quality improvement in Eastern Himalayas. In Conservation Agriculture for Advancing Food Security in Changing Climate Edition: Vol. 1 (eds Das, A. et al.), Today & Tomorrow’s Printers and Publishers, New Delhi, 2017, pp. 363–386.
- Singh, G., The role of Prosopis in reclaiming high-pH soils and in meeting firewood and forage needs of small farmers. In Prosopis: Semi-Arid Fuelwood and Forage: Tree Building Consensus for the Disenfranchised, US National Academy of Sciences, Washington, DC, USA, 1996.
- Sharma, P. D. and Sarkar, A. K., Managing acid soils for enchancing productivity. Technical Bulletin; NRM Division, KAB-II, New Delhi, 2005, p. 23.
- Kaledhonkar, M., Babu, M. and Parbodh, S., Reclamation and nutrient management for salt-affected soils. Indian J. Fert., 2019, 15, 566–575.
- Anon., Biennial Report 2016–18, All India coordinated research project on management of salt-affected soils and use of saline water in agriculture, ICAR-CSSRI, Karnal, 2018, pp. 1–282.
- Mapping surface-water area using time series landsat imagery on Google Earth Engine: a case study of Telangana, India
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1 ICAR-National Academy of Agricultural Research Management, Rajendra Nagar, Hyderabad 500 030, IN
1 ICAR-National Academy of Agricultural Research Management, Rajendra Nagar, Hyderabad 500 030, IN
Source
Current Science, Vol 120, No 9 (2021), Pagination: 1491-1499Abstract
The extent of surface-water spread influences the hydrogeology and ecology of waterbodies. Remote sensing technology provides spatial and temporal datasets which aid in mapping the dynamics of surface waterbodies at the regional and global scale. In the present study, temporal changes in the surface area of waterbodies in Telangana, India, were monitored using indices like normalized difference vegetation index, normalized difference water index and modified NDWI and machine learning algorithms like a random forest using Landsat-8 data. Google Earth Engine cloud computing platform was used for processing earth observation data, based on the time series images of Landsat and compared with real-time groundwater levels. The results showed a significant increase (P < 0.01) in both surface-water area and groundwater levels in Telangana, especially after 2015, which we hypothesize could be due to the specialized water conservation project being implemented by the Government of Telangana since 2015.Keywords
Cloud computing platform, groundwater level, machine learning algorithms, remote sensing, surface area, waterbodies.References
- Du, N., Ottens, H. and Sliuzas, R., Spatial impact of urban expansion on surface water bodies – a case study of Wuhan, China. Landsc. Urban Plan., 2010, 94, 175–185; https://doi.org/10.1016/ j.landurbplan.2009.10.002.
- Melendo, J. D. V., Water as a strategic resource: international cooperation in shared basins and geowater. J. Spanish Inst. Strat. Stud., 2015; http://revista.ieee.es/article/view/274.
- Edokpayi, J. N., Odiyo, J. O. and Durowoju, O. S., Impact of wastewater on surface water quality in developing countries: a case study of South Africa. In Water Quality (ed. Hlanganani Tutu), Intech (open access), 2017, pp. 401–416; https://www.intechopen.com/books/water-quality/impact-of-wastewater-onsurface-water-quality-in-developing-countries-a-case-studyof-south-africa
- Huang, C., Chen, Y., Zhang, S. and Wu, J., Detecting, extracting, and monitoring surface water from space using optical sensors: a review. Rev. Geophys., 2018, 56, 333–360; https://doi.org/ 10.1029/2018RG000598.
- Karpatne, A., Khandelwal, A., Chen, X., Mithal, V., Faghmous, J. and Kumar, V., Global monitoring of inland water dynamics: state of the art, challenges and opportunities. In Computational Sustainability (eds Lassig, J., Kersting, K. and Morik, K.), Springer, Cham, 2016, vol. 645, pp. 121–147; https://doi.org/10.1007/978-3319-31858-5_7
- Chang, N. B., Imen, S. and Vannah, B., Remote sensing for monitoring surface water quality status and ecosystem state in relation to the nutrient cycle: a 40-year perspective. Environ. Sci. Technol., 2015, 45, 101–166; https://doi.org/10.1080/10643389.2013.829981
- Gillespie, T. W., Foody, G. M., Rocchini, D., Giorgi, A. P. and Saatchi, S., Measuring and modelling biodiversity from space. Prog. Phys. Geogr., 2008, 32, 203–221; https://doi.org/10.1177/0309133308093606.
- Schimel, D. S., Asner, G. P. and Moorcroft, P., Observing changing ecological diversity in the anthropocene. Front. Ecol. Environ., 2013, 11, 129–137; https://doi.org/10.1890/120111.
- Ustin, S. L. and Gamon, J. A., Remote sensing of plant functional types. New Phytol., 2010, 186, 795–816; https://doi.org/10.1111/ j.1469-8137.2010.03284.x.
- Wallace, J., Behn, G. and Furby, S., Vegetation condition assessment and monitoring from sequences of satellite imagery. Ecol. Manage. Restor., 2006, 7, 31–36; https://doi.org/10.1111/j.14428903.2006.00289.x.
- Domenikiotis, C., Loukas, A. and Dalezios, N. R., The use of NOAA/AVHRR satellite data for monitoring and assessment of forest fires and floods. Nat. Hazards Earth Syst. Sci., 2003, 3, 115–128; https://doi.org/10.5194/nhess-3-115-2003.
- Shrestha, R., Di, L., Yu, G., Shao, Y., Kang, L. and Zhang, B., Detection of flood and its impact on crops using NDVI – corn case. In second International Conference on Agro-Geoinformatics, Fairfax, VA, USA, 2013, pp. 200–204.
- McFeeters, S. K., The use of the normalized difference water index (NDWI) in the delineation of open water features. Int. J. Remote Sensing, 1996, 17, 1425–1432; https://doi.org/10.1080/ 01431169608948714.
- Xu, H., Modification of normalized difference water index (NDWI) to enhance open water features in remotely sensed imagery. Int. J. Remote Sensing, 2006, 27, 3025–3033.
- Anand, A. et al., Mapping the potential areas for enclosure fish culture in tropical reservoirs: geo-spatial solutions for sustainable aquaculture expansion. Spat. Inf. Res., 2019, 27, 733–747; https://doi.org/10.1007/s41324-019-00294-w.
- Acharya, T. D., Subedi, A. and Lee, D. H., Evaluation of water indices for surface water extraction in a Landsat 8 scene of Nepal. Sensors, 2018, 18, 1–15.
- Mizuochi, H., Hiyama, T., Ohta, T. and Nasahara, K. N., Evaluation of the surface water distribution in north-central Namibia based on MODIS and AMSR series. Remote Sensing, 2018, 6, 7660–7682; https://doi.org/10.3390/rs6087660.
- Akhtar, M. P., Roy, L. B. and Vishwakarma, K. M., Assessment of agricultural potential of a river command using geo-spatial techniques: a case study of Himalayan river project in Northern India. Appl. Water Sci., 2020, 10, 81; https://doi.org/10.1007/s13201020-1165-8.
- Anand, A. et al., Assessing the water spread area available for fish culture and fish production potential in inland lentic waterbodies using remote sensing: a case study from Chhattisgarh state, India. Remote Sensing Appl.: Soc. Environ., 2020, 17, 100273; https://doi.org/10.1016/j.rsase.2019.100273.
- Das, R. T. and Pal, S., Exploring geospatial changes of wetland in different hydrological paradigms using water presence frequency approach in Barind Tract of West Bengal. Spat. Inf. Res., 2017, 25, 467–479; https://doi.org/10.1007/s41324-017- 0114-6.
- Wang, Z., Liu, J., Li, J. and Zhang, D. D., Multi-spectral water index (MuWI): a native 10-m multi-spectral water index for accurate water mapping on sentinel-2. Remote Sensing, 2018, 10, 1–21; https://doi.org/10.3390/rs10101643.
- Soltanian, F. K., Abbasi, M. and Bakhtyari, H. R. R., Flood monitoring using NDWI and MNDWI spectral indices: a case study of Aghqala Flood-2019, Golestan Province, Iran. Int. Arch. Photogrammetry, Remote Sensing Spat. Inf. Sci., XLII-4/W18, 2010, 605–607; https://doi.org/10.5194/isprs-archives-XLII-4-W18-6052019.
- DeVries, B., Huang, C., Armston, J., Huang, W., Jones, J. W. and Lang, M. W., Rapid and robust monitoring of flood events using Sentinel-1 and Landsat data on the Google Earth Engine. Remote Sensing Environ., 2020, 240, 111664 24. https://doi.org/10.1016/j.rse.2020.111664 (accessed on 10 December 2020).
- MSME, Telangana – state profile 2015–16. MSME Development Institute, Hyderabad, 2016; http://dcmsme.gov.in/dips/state_wise_ dips/TS-Profile.pdf.
- Environment Protection Training and Research Institute (EPTRI), State action plan on climate change for Telangana state. A report submitted to MOEF&CC, GoI, 2017; http://moef.gov.in/ wp-content/uploads/2017/09/Telangana.pdf.
- Shelestov, A., Lavreniuk, M., Kussul, N., Novikov, A. and Skakun, S., Exploring Google Earth Engine platform for big data processing: classification of multi-temporal satellite imagery for crop mapping. Front. Earth Sci., 2017, 7, 1–10; https://doi.org/10.3389/feart.2017.00017.
- United States Geological Survey (USGS), Landsat missions, Landsat 8, 2019; https://www.usgs.gov/land-resources/nli/landsat/ landsat-8?qt-science_support_page_related_con=0#qt-science_ support_page_related_con.
- Tucker, C. J., Red and photographic infrared linear combinations for monitoring vegetation. Remote Sensing of Environ., 1979, 8, 127–150; https://doi.org/10.1016/0034- 4257(79)90013-0.
- Han-Qiu, X. A., Study on information extraction of water body with the modified normalized difference water index (mNDWI). J. Remote Sensing, 2005, 5, 589–595.
- Ashraf, M. and Nawaz, R., A comparison of change detection analyses using different band algebras for Baraila wetland with NASA’s multi-temporal landsat dataset. J. Geogr. Inf. Syst., 2015, 7, 1–19; https://doi.org/10.4236/jgis.2015.71001.
- Ji, L., Zhang, L. and Wylie, B., Analysis of dynamic thresholds for the normalized difference water index. Photogr. Eng. Remote Sensing, 2009, 75, 1307–1317; https://doi.org/10.14358/PERS.75.11.1307.
- Karsli, F., Guneroglu, A. and Dihkan, M., Spatio-temporal shoreline changes along the southern Black Sea coastal zone. J. Appl. Remote Sensing, 2011, 5, 1–14; https://doi.org/10.1117/1.3624520.
- Wang, C., Jia, M., Chen, N. and Wang, W., Long-term surface water dynamics analysis based on landsat imagery and the Google Earth Engine platform: a case study in the Middle Yangtze river basin. Remote Sensing, 2018, 10, 1–18; https://doi.org/10.3390/rs10101635.
- Nistor, M. M., Rahardjo, H., Satyanaga, A., Hao, K. Z., Xiaosheng, Q. and Sham, A. W. L., Investigation of groundwater table distribution using borehole piezometer data interpolation: case study of Singapore. Eng. Geol., 2020, 271, 105590; https://doi.org/10.1016/j.enggeo.2020.105590.
- Jie, C., Hanting, Z., Hui, Q., Jianhua, W. and Xuedi, Z., Selecting proper method for groundwater interpolation based on spatial correlation. In Fourth International Conference on Digital Manufacturing and Automation, Qingdao, China, 2013, pp. 1192–1195; https://doi.org/10.1109/ICDMA.2013.282.
- El Asmar, H. M. and Hereher, M. E., Change detection of the coastal zone east of the Nile delta using remote sensing. Environ. Earth Sci., 2011, 62, 769–777; https://doi.org/10.1007/s12665-010-0564-9.
- Nandi, D., Chowdhury, R., Mohapatra, J., Mohanta, K. and Ray, D., Automatic delineation of water bodies using multiple spectral indices. Int. J. Sci. Res. Sci., Eng. Technol., 2018, 4, 498–512.
- Ji, L., Geng, X., Sun, K., Zhao, Y. and Gong, P., Target detection method for water mapping using Landsat 8 OLI/TIRS imagery. Water, 2015, 7, 794–817.
- Acharya, T. D., Subedi, A., Huang, H. and Lee, D. H., Application of water indices in surface water change detection using Landsat imagery in Nepal. Sensors Mater., 2019, 31, 1429–1447.
- Li, L., Vrieling, A., Skidmore, A., Wang, T. and Turak, E., Monitoring the dynamics of surface water fraction from MODIS time series in a Mediterranean environment. Int. J. Appl. Earth Observ. Geoinform., 2018, 66, 135–145; https://doi.org/10.1016/j.jag.2017.11.007.
- Wakode, H. B., Baier, K., Jha, R. and Azzam, R., Analysis of urban growth using Landsat TM/ETM data and GIS – a case study of Hyderabad, India. Arab. J. Geosci., 2014, 7, 109–121; https://doi.org/10.1007/s12517-013-0843-3.
- Sunday Guardian Live, Mission Kakatiya is a boon for farmers. 2017; https://www.sundayguardianlive.com/news/12244-missionkakatiya-boon-farmers.