Natural resources : technology, economics and policy / edited by U. Aswathanarayana

Machine generated contents note: Section 1 Introduction --
1.1. Symbiotic relationship between mangroves and coastal communities --
1.2. Earth system science for global sustainability --
1.3."Virtual" natural resources --
1.4. Natural resources and globalization --
1.4.1. General considerations --
1.4.2. Different aspects of globalisation --
1.4.3. Natural resources and violent conflicts --
1.5. Innovation chain and economic growth --
References --
Section 2 Water resources management --
2.1. Holistic water resources management, based on the hydrological cycle (U. Aswathanarayana, India) --
2.1.1. Introduction --
water and culture --
2.1.2. Water balance --
2.1.3. Green and blue waters --
2.1.4. Conjunctive use of water resources --
2.1.5. Water resources endowments of countries --
2.1.6. Decision --
Support system for water resources management --
2.1.7. Paradigm of global water resources management --
2.1.8. How best to use water resources --
India as a case --
References. Contents note continued: 2.2. Economic frameworks to inform decision-making (U. Aswathanarayana, India) --
2.2.1. An integrated economic approach to water scarcity --
2.2.2. Role of the private sector in the water resources management --
2.2.3. Tools for policy makers --
2.2.4. Quo vadis? --
Reference --
2.3. Multiple perspectives on water: A synthesis (Ramaswamy R. Iyer, India) --
2.3.1. Nature of water --
2.3.2. Perspectives on water --
References --
2.4. Water pollution (U. Aswathanarayana, India) --
2.4.1. Pathways of pollution --
2.4.2. Activities that can cause groundwater pollution --
2.4.3. Leachates from solid wastes, source-wise --
2.4.4. Pollution from liquid wastes, source-wise --
2.4.5. Contaminants, type-wise --
2.4.6. Anthropogenic acidification of waters --
2.4.7. Water pollution arising from waste disposal --
2.4.8. Transport of contaminant solutes in aquifers --
References --
2.5. Sequential use of water resources (U. Aswathanarayana, India). Contents note continued: 2.5.1. Water quality in relation to water use --
2.5.2. Estimates of water value for different uses --
2.5.3. Water value in system context --
2.5.4. Price coordination of water supplies --
2.5.5. Principles of optimization --
2.5.6. Price coordination of a typical irrigation system --
2.5.7. Optimization methods in water management --
2.5.8. Allocation of water to competing users --
2.5.9. Decision-making process --
References --
2.6. Wastewater reuse systems (U. Aswathanarayana, India) --
2.6.1. Introduction --
2.6.2. Bio-pond treatment of waste water --
2.6.3. Types of wastewater reuse --
2.6.4. Use of wastewater in irrigation --
2.6.5. Geopurification --
2.6.6. Economics of wastewater reuse --
2.6.7. Health hazards in wastewater reuse --
2.6.8. Use of sewage sludge as fertilizer --
References --
2.7. Etiology of diseases arising from toxic elements in drinking water (U. Aswathanarayana, India) --
2.7.1. Routes and consequences of ingestion of toxic elements. Contents note continued: 2.7.2. Arseniasis --
2.7.3. Fluorosis --
2.7.4. Risk assessment --
References --
2.8. Water and agriculture: Usefulness of agrometeorological advisories (L.S. Rathore, N. Chattopadhyay & S.V. Chandras, India) --
2.8.1. Introduction --
2.8.2. Impact of climatic variability on agricultural water challenges --
2.8.3. Usefulness of agro-climatic information in water use --
2.8.4. Farmer-customized agrometeorological advisories --
2.8.5. Integration of agro-climatic resources with agricultural inputs --
2.8.6. Projection of water status in Indian agriculture under future climate change scenario --
2.8.7. How to produce more food (through optimization of soil-water-plant system) --
2.8.8. How to do with less water (in agriculture, industry and domestic purposes) --
2.8.9. Conclusion --
References --
2.9. Remote sensing in water resources management (Venkat Lakshmi, USA) --
2.9.1. Background and societal importance --
2.9.2. Current monitoring methodologies. Contents note continued: 2.9.3. Land surface modeling and data assimilation --
References --
2.10. Case history and exercises (B. Venkateswara Rao & V. Varalakshmi, India) --
2.10.1. Introduction --
2.10.2. Description of the study area --
2.10.3. Rainfall analysis of the catchment area --
2.10.4. Analysis of inflows to the reservoirs --
2.10.5. Verification of the cropping area in the catchments --
2.10.6. Water table contour maps and analysis --
2.10.7. Discussion on hydrographs of observation wells --
2.10.8.Composite hydrographs of piezometer wells --
2.10.9. Rainfall and water level rise relationship --
2.10.10. Influence of premonsoon groundwater levels over the recharge of rainfall water to the ground --
2.10.11. Implications of the study and conclusions --
References --
Exercises --
2.11. Basic research and R & D (B. Rajagopalan & C. Brown, USA) --
2.11.1. Background --
Traditional water resources management --
2.11.2. New paradigm for water resources management. Contents note continued: 2.11.3.R & D for managing water resources under uncertainty --
2.11.4. Colorado river management --
Case study --
References --
Section 3 Mineral resources management (U. Aswathanarayana, India) --
3.1. Introduction --
3.1.1. Environmental challenges facing the mining industry --
3.1.2. Mining, environmental protection and sustainable development --
3.1.3. Economics of environmental protection in mining --
3.1.4. Technology trends in the mining industry --
3.1.5. Automation in the mining industry --
3.1.6. Technology-driven developments in the mining industry --
3.2. Mineral demand in response to emerging technological needs --
3.2.1. Emerging technological needs --
3.2.2. Rare earth elements --
3.2.3. Gold --
3.2.4. Aluminium --
3.2.5. Copper --
3.2.6. Lead --
3.3. Control technologies for minimizing the environmental impact of mining --
3.3.1. Acid mine drainage --
3.3.2. Tailings disposal --
3.3.3. Dust control technologies --
3.3.5. Treatment of wastewater. Contents note continued: 3.3.6. Subsidence --
3.3.7. Noise and vibration --
3.3.8. Planning for mine closure --
3.4. Health and socio-economic impacts of the mining industry --
3.4.1. Health hazards of the mining industry --
3.4.2. Health hazards due to dusts --
3.4.3. Matrix diagrams --
3.4.4. Total project development --
A visionary approach --
3.5. Artisanal mining --
3.6. Ways of ameliorating the adverse consequences of mining industry --
3.6.1. Rehabilitation of mined land --
3.6.2. Beneficial use of mining wastes --
3.6.3. Reuse of mine water --
3.7. Iron ore mine of Kiruna, Sweden --
A case study --
3.8. Basic research and R & D --
References --
Section 4 Energy resources management (U. Aswathanarayana, India) --
4.1. Coal resources --
4.1.1. Importance of coal in the energy economy --
4.1.2. Environmental impact of the coal cycle --
4.1.3. Wastes from coal industries --
4.1.4. Power generation technologies --
4.1.5. China --
a country case study --
4.2. Oil and gas resources --
4.2.1. Oil. Contents note continued: 4.2.2. Natural gas --
4.2.3. Shale gas --
4.2.4. Saudi Arabia --
a country case study --
4.3. Nuclear fuel resources --
4.3.1. Introduction --
4.3.2. Resource position --
4.3.3. Cost of nuclear power --
4.3.4. Projected nuclear power capacity --
4.3.5. New reactor designs --
4.3.6.R & D areas --
4.3.7. Country case study of France --
4.4. Renewable energy resources --
4.4.1. Why renewables? --
4.4.2. Renewable energy sources --
4.5. Strategy for a low-carbon footprint --
4.5.1. Carbon emissions and climate change --
4.5.2. Mitigation of climate change --
4.6. Exercises --
References --
Section 5 Bio resources and biodiversity (S. Balaji, India) --
5.1. Introduction --
5.2. What is biodiversity? --
5.2.1. Endemism and keystone species --
5.3. Why conserve biodiversity --
5.4. Global biodiversity resources --
5.5. Erosion of biodiversity --
5.5.1. Causes for the erosion of biodiversity --
5.5.2. Habitat loss --
5.5.3. Invasive alien species --
5.5.4. Pollution. Contents note continued: 5.5.5. Human population --
5.5.6. Overexploitation --
5.5.7. Arresting biodiversity loss --
5.6. Climate change and biodiversity --
5.6.1. Role of forests in climate change mitigation --
5.7. Role of biodiversity in medicine, agriculture and forestry --
5.7.1. Biodiversity in medicine --
5.7.2. Agro-biodiversity --
5.7.3. Biodiversity and forestry --
5.8. Biodiversity and biotechnology --
5.8.1. Biotechnology for biodiversity assessment --
5.8.2. Biodiversity utilization --
5.8.3. Impacts --
5.8.4. Biotechnology for prospecting genetic diversity --
5.8.5. Genetically modified foods --
5.8.6. Environmental biotechnology --
5.8.7. Pragmatic use of biotechnology --
5.9. Economics and policy of biodiversity management --
5.9.1. Economics and policy --
5.9.2. Tangible and intangible uses of biodiversity --
5.9.3. Conservation strategy --
5.10. Future prospects --
5.10.1. The strategic plan --
Aichi targets 2011-2020 --
5.10.2. Scope for future research. Contents note continued: 5.11. Conclusion: Living in harmony with nature --
5.12. Sample exercises --
References --
Section 6 Disaster management (U. Aswathanarayana, India) --
6.1. Hazardous events (natural, mixed and technological) --
6.2. Vulnerability to hazardous events --
6.2.1. Earthquakes --
6.2.2. Tsunamis --
6.2.3. Volcanic hazards --
6.2.4. Slope failures, landslides and subsidence --
6.3. Marine hazards --
6.3.1. Introduction --
6.3.2. Types of marine hazards --
6.3.3. Natural hazards --
6.3.4. Man-made hazards --
References --
6.4. Nuclear energy accidents --
6.4.1. The Three Mile Island (TMI) accident --
6.4.2. Chernobyl reactor accident --
6.4.3. Fukushima --
Daiichi reactor accident --
6.5. Integrated disaster preparedness --
6.5.1. Dual use technologies and practices --
6.5.2. Resiliency linked to social-ecological systems --
6.5.3. Risk management through securitisation --
6.5.4. Monitoring and warning systems --
6.5.5. Science-based and people-based Hazard preparedness systems. Contents note continued: 6.5.6. Risk communication --
6.5.7. Rehabilitation measures --
6.6. Basic research and R & D --