Natural resources management has two principal dimensions: Science-illuminated (earth, space, hydrological, pedological, information, etc. sciences) management of local resources (waters, soils, bioresources, minerals, rocks, sediments, etc.) in an ecologically-sustainable manner, and Value-addition through processing of natural products, through the application of technology is most marked in the case of some mineral products. The wellness of a community is dependent upon the security of food, water, environment and energy. Such a security is best realised through science-illuminated (earth, space, hydrological, pedological, information) management of local resources (waters, soils, bioresources, minerals, rocks, sediments, etc.) in an ecologically-sustainable and people-participatory manner, plus value-addition through processing of natural products. Moreover, the addition of value may increase a community's wealth by advanced technologies, trading, exchange of knowledge, etc. Moreover, activities, employment and many other things come along with the availability of natural resources, which will require and affect policy.
Natural Resources: Technology, Economics & Policy provides guidelines for the implementation of technological, economical and policy advances in dealing with various aspects of natural resources. It is intended for researchers, professionals and students in environmental and earth sciences, mining, geography, sociology, economics and for policy makers and investors searching for potential in the natural resources industry. Ideal for consultation in combination with the editor's related publications Green Energy: Technology, Economics and Policy, Energy Portfolios and Food and Water Security.
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)
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
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?
References
2.3 Multiple perspectives on water: A synthesis (Ramaswamy R. Iyer)
2.3.1 Nature of water
2.3.2 Perspectives on water
References
2.4 Water pollution (U. Aswathanarayana)
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)
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)
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)
2.7.1 Routes and consequences of ingestion of toxic elements
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)
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
2.9.3 Land surface modeling and data assimilation
References
2.10 Case history and exercises (B. Venkateswararao & V. Varalakshmi)
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
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)
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
3.3.4 Low-waste technologies
3.3.5 Treatment of wastewater
3.3.6 Subsidence
3.3.7 Noise and vibration
3.3.8 Planning for mine closure
3.4 Health and socioeconomic 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)
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
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: Bioresources and biodiversity (S. Balaji)
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
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
5.11 Conclusion: Living in harmony with nature
5.12 Exercises
References
Section 6: Disaster management (U. Aswathanarayana)
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 sector 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 systems
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 preparedness systems
6.5.6 Risk communication
6.5.7 Rehabilitation measures
6.6 Basic research and R&D
References
Section 7: Overview and Integration – Living in harmony with nature
U. Aswathanarayana (General Editor) has teaching, R.&D., and institutional capacity building experience, in many countries. That he is indeed a polymath is evidenced by his ten, highly-acclaimed, internationally published books (most of them through A.A. Balkema of the Taylor & Francis Group) on topics as diverse as Nuclear Geology, Geoenvironment, Food and Water Security and now, Green Energy. He is the recipient of the Excellence in Geophysical Education (2005) and International (2007) Awards of the American Geophysical Union, Certificate of Recognition (2007) of the International Association of GeoChemistry, and Eminent Citizen Award in the area of water sciences (2007) of Sivananda Trust, India.
"The book will also be found useful by the experts in a particular domain, for acquiring a working knowledge of other domains. Water resources engineers will find useful the chapters on minerals management, while mining engineers will find useful the chapters on, say, energy management. All technocrats working in water, energy and mining sectors would do well to read Section 5 on 'Bio resources and bio diversity'. [...] [S]trongly recommended for all, specialists as well as others."
- Chetan Pandit, Current Science, Vol. 104, No. 1, pp. 127-128