Abstract
Waste in its different forms is a significant environmental issue that receives a great deal of attention worldwide. Waste is generated as a result of production and consumption (domestic and industrial) activities and tends to increase with the level of prosperity and economic development of the country. Cost efficient, technology-based and sustainable management of both solid and liquid waste is crucial to economic growth and development of a healthy society in any given region. This chapter reviews traditional as well as modern approaches to solid waste management (SWM) and wastewater treatment. Sustainable methods of waste reduction, waste reuse and recycling are the preferred options when managing waste. There are many environmental benefits that can be derived from the use of these methods. They reduce or prevent greenhouse gas emissions, lessen the release of pollutants, conserve resources, save energy and minimise the demand for waste treatment technology and space. Establishment of sanitary landfills that meet standard hygienic requirements is the most widely adopted method of disposing of solid waste in developed countries. Vermicomposting and biogas technology produce reusable manure and combustible gas respectively from organic solid waste while waste-to-energy (incineration of waste) has quickly emerged as one of the most attractive renewable energy options. Wastewater if not properly disposed of, could be hazardous to human health and environment. Natural aquatic and terrestrial treatment systems with the environment-friendly designs and low-cost sanitation provide benefits for the reuse of water. Wise uses of aquatic and terrestrial plants are a means of several natural wastewater treatment methods. A decentralized wastewater treatment is being considered for most communities because of its economic and environmental advantages. Apart from natural treatment methods, membrane technology, nanotechnology, microbial fuel cells and electrocoagulation offer newer approaches to handling wastewater in a sustainable manner. The overall sustainable development ensures the path of reconciliation for society, environment, and economy in the long-term. People who generate waste, institutions who handle it and the local governance are key partners in an efficient waste management system. Need for education to create awareness on the importance of waste treatment and the sustainability aspects of the emerging technologies remains critical at all societal and governmental levels. Applications of information and communication technologies offer ingenious solutions to the problem of waste management.
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References
Agenda 21. (1992). United Nations Conference on Environment & Development, Rio de Janerio, Brazil, June 3–14, 1992. Retrieved from sustainabledevelopment.un.org/content/documents/Agenda21.pdf.
Brunner, P. H., & Rechberger, H. (2015). Waste to energy – Key element for sustainable waste management. Waste Management, 37, 3–12.
Butler, E., Hung, Y. T., Yeh, R. Y. L., & Al Ahmad, M. S. (2011). Electrocoagulation in wastewater treatment. Water, 3, 495–525.
Constable, G., & Sommerville, B. (2003). A century of innovation: Twenty engineering achievements that transformed our lives. Washington, DC: Joseph Henry Press.
Couth, R., & Trois, C. (2012). Sustainable waste management in Africa through CDM projects. Waste Management, 32, 2115–2125.
Daigger GT (2007) Creation of sustainable water resources by water reclamation and reuse. Proceedings of the 3rd international conference on sustainable water environment: integrated water resources management-new steps (pp. 79–88). Sapporo, Japan, October, 2007.
Daigger, G. T. (2007b). Wastewater management in the 21st century. Journal of Environmental Engineering, 133(7), 671–680.
Daigger, G. T. (2008). AEESP lecture-evolving urban water and residuals management paradigms: Water reclamation and reuse, decentralization, resource recovery. Proceedings of the Water Environment Federation 81st Annual Conference and Exposition, Chicago, October, 2008.
Daigger, G.T. (2008). Decentralization: A practitioner’s perspective. Proceedings of the 6th IWA leading edge water and wastewater treatment technology conference, Zurich, Switzerland, June 2008.
Daigger, G. T. (2008). New approaches and technologies for wastewater management, The bridge technologies for clean water. Salt Lake City, UT: National Academy of Engineering, 38(3).
Daigger, G. T., & Crawford, G. V. (2005). Wastewater treatment plant of the future-decision analysis approach for increased sustainability, 2nd IWA leading-edge conference on water and wastewater treatment technology. Water and environment management series. London: IWA Publishing.
Daigger, G. T., Rittmann, B. E., Adham, S., & Andreottola, G. (2005). Are membrane bioreactors ready for widespread application? Environmental Science and Technology, 39(19), 399A–406A.
DiGiano, F. A., Andreottola, G., Adham, S., et al. (2004). Membrane bioreactor technology and sustainable water. Water Environment Research, 76(3), 195–196.
Faheem, S. M., & Khan, M. A. (2009). A Study on filamentous bacteria in activated sludge process of sewage treatment plant in Dubai, United Arab Emirates. London: IWA Publication. Water Practice and Technology, 4(2).
Guerrero, L. A., Maas, G., & Hogland, W. (2013). Solid waste management challenges for cities in developing countries. Waste Management, 33, 220–232.
Halbach, T. R. (2013) International trends in solid waste handling: 2013.Solid waste management & recycling export roundtable. Department of Soil, Water and Climate, University of Minnesota, Carlson School of Management Minneapolis, Minneapolis, MN, March 14, 2013.
Iona, I., & Gheorgheb, F. F. (2014). The innovator role of technologies in waste management towards the sustainable development. Procedia Economics and Finance, 8, 420–428.
Jefferson, B., Laine, A. L., Judd, S. J., & Stephenson, T. (2000). Membrane bioreactors and their role in wastewater reuse. Waster Science and Technology, 41(1), 197–204.
Kadlec, R. H., & Knight, R. L. (1996). Treatment wetlands. New York, NY: CRC Press-Lewis Publishers.
Kim, I.S., Oh, B.S., & Hyu, H.W. (2008) Moving desalination forward. Proceedings of the Singapore international water week water convention. Singapore, June 25–26, 2008.
Logan, B. E., Hamelers, B., Rozendal, R., Schröder, U., Keller, J., Freguia, S., et al. (2006). Microbial fuel cells: Methodology and technology. Environmental Science and Technology, 40(17), 5181–5192.
Mackenbach, J. P. (2007). Medical milestones: celebrating key advances since 1840. BMJ, 334, s1–s20.
Marshall, R. E., & Farahbakhsh, K. (2013). Systems approaches to integrated solid waste management in developing countries. Waste Management, 33, 988–1003.
Martin, L. (2014). Electrocoagulation: A shocking approach to wastewater treatment. www.wateronline.com.
Rabaey, K., Boon, N., Siciliano, S. D., Verhaege, M., & Verstraete, W. (2004). Biofuel cells select for microbial consortia that self-mediate electron transfer. Applied and Environmental Microbiology, 70, 5373–5382.
Seadon, J. K. (2010). Sustainable waste management systems. Journal of Cleaner Production, 18(16–17), 1639–1651.
Shannon, M. A., Bohn, P. W., Elimelech, M., Georgladis, J. G., Mariñas, B. J., & Mayes, A. M. (2008). Science and technology for water purification in the coming decades. Nature, 452(20), 301–310.
Smith, J. E. (2009). Biotechnology (5th ed.). New York, NY: Cambridge University Press.
Sridhar, M. K. C., & Adejumo, M. (2014). Health and safety challenges, and perceptions of private sector waste operators in lagos. Nigeria Health, 6, 632–640.
Tao, G. H., Kekre, K., Qin, J. J., Oo, M. W., Viswanath, B., & Seah, H. (2006). MBR-RO for high-grade water (NEWater) production from domestic used water. Water Practice and Technology, 1(2), 1–8.
Tao, G., Kekre, K., Wei, Z., Lee, T. C., Viswanath, B., & Seah, H. (2005). Membrane bioreactors for water reclamation. Water Science and Technology, 51, 431–440.
UNEP. (1997). Source book of alternative technologies for freshwater augmentation in Latin America and the Caribbean. Osaka: UNEP-International Environmental Technology Centre. www.oas.org.
UNEP. (2010). Waste and climate change: Global trends and strategy framework. United Nations Environmental Program, Division of Technology, Industry and Economics. Retrieved from www.unep/Publications/spc/WasteClimate Change/WasteClimateChange.pdf.
United Nations. (1997). Kyoto protocol 1997: United nations convention on climate change (UNFCCC). UNFCCC. Retrieved December 11, 1997, from http://unfccc.int/kyoto_protocol/items/2830.php.
Visvanathan, C., Ben Aim, R., & Parameshwaran, K. (2000). Membrane separation bioreactors for wastewater treatment. Critical Reviews in Environmental Science and Technology, 30(1), 1–48.
Wallace, B. (2005). Becoming part of the solution: The engineer’s guide to sustainable development. Washington, DC: American Council of Engineering Companies.
Waltner-Toews, D., Kay, J., & Lister, N.-M. E. (2008). The ecosystem approach: Complexity, uncertainty, and managing for sustainability. New York, NY: Columbia University Press.
Wilson, D. C. (2007). Development drivers for waste management. Waste Management & Research, 25(3), 198–207.
Wilson, D. C., Velis, C. A., & Rodic, L. (2012). Integrated sustainable waste management in developing countries. Waste and Resource Management, 166(2), 52–68.
Xiao, Y. T., Xu, S. S., Li, Z. H., An, X. H., Zhou, L., Zhang, Y. L., et al. (2010). Progress of applied research on TiO2 photocatalysis-membrane separation coupling technology in water and wastewater treatments. Chinese Science Bulletin, 55(14), 1345–1353.
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Faheem, S.M., Khan, M.A. (2015). Waste Management Methods and Sustainablity. In: Ravindra, P. (eds) Advances in Bioprocess Technology. Springer, Cham. https://doi.org/10.1007/978-3-319-17915-5_4
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DOI: https://doi.org/10.1007/978-3-319-17915-5_4
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