Climate Change Science: Causes, Effects and Solutions for Global Warming

Cover
Title
Copyright
Contents
Contributors
Preface
References
Acknowledgments
1 - Enhancing crop water productivity under increasing water scarcity in South Africa
1 - Introduction
2 - Understanding water productivity
2.1 - Spatial distribution of water resources in South Africa
2.2 - Considerations in improving water productivity
2.3 - Options to improve water productivity at all levels
2.4 - Available options to improve water productivity at field level
2.5 - Options to improve water productivity at system and basin levels
2.6 - Policies related to water productivity in South Africa
3 - The value of water markets in water scarce regions
4 - Improving water productivity from a WEF nexus perspective
5 - Recommendations
6 - Conclusions
References
2 - Can renewable energy sources be a viable instrument for climate change mitigation? Evidence from EU countries via M...
Nomenclature
1 - Introduction
2 - Literature review
3 - Research methods
3.1 - CRITIC method
3.2 - TOPSIS method
3.3 COPRAS method
4 - Data and descriptive statistics
5 - Climate change mitigation profile of EU countries
6 - Empirical results
7 - Conclusion and policy implications
References
3 - Carbon emission as a result of forest land change in Islamabad, Pakistan
1. Introduction
1.1 - Forestland change
1.2 - Reasons behind foreland change
1.3 - Trend of carbon emission change
1.4 - Problem statement
2 - Aim & research questions
2.1 - Research questions of the study
3 - Materials and methods
3.1 - Study area
3.2 - Tools and techniques
3.2.1 - Calculating carbon emissions
4 - Results and discussion
4.1 LULCC—1992–2000, 2000–08, 2008–17
4.2 - Forestland to other land and carbon emissions—1992–2000, 2000–08, and 2008–17
4.3 - Forestland change for individual study sectors
5 - Conclusion
Acknowledgment
References
4 - “Integrated coastal management” enhances coastal resilience to climate change—The East Asia experience
1 Introduction
2 - ICM system
3 - ICM adoption in the East Asian Seas region
4 - Climate change impacts on the coastal area
5 ICM strengthens environmental and societal resilience
6 Conclusion
References
5 - Underground methanation, a natural way to transform carbon dioxide into methane
1 - Introduction
1.1 - Integration of the renewable energies into the electricity system
2 - Power to gas
2.1 - Power to hydrogen versus power to methane
2.1.1 - Hydrogen storage
2.1.2 - H2 injection into the gas network
2.1.3 - CO2 capture and reuse
3 - Underground methanation
3.1 - Underground hydrogen storage
3.1.1 - Types of underground storage
3.1.2 - Underground gas storage in the world
3.1.3 - Properties of hydrogen in the context of its underground storage
3.1.4 - First projects
3.1.5 - Recent projects
3.1.6 - Hydrogen interactions in the reservoir
3.1.6.1 - Abiotic reactions
3.1.6.2 - Biotic reactions
3.2 - Underground methanation reactor
3.2.1 - Concept
3.2.2 - Superficial infrastructure
3.2.3 - Microbiological characteristics
3.2.4 - Geological characteristics
3.2.5 - Results: Optimum conditions of underground methanization
3.2.6 - Limitations
3.2.7 - Comparison with surface bioreactors
4 - Conclusions
Acknowledgment
References
6 - Analysis of plant oil-based fuel characteristics for green supply chains
1 - Introduction
2 - Model structure: fuel-related properties of plant oils
3 - Conclusions
References
7 - The effects of couple layout on thermoelectric generator performance
Nomenclature
1 - Introduction
1.1 - Applications of TEG technology
1.2 - Improvements in TEG performance
1.3 - Objectives and scope
2 - Methodology
2.1 - Electrical characteristics
2.2 - Thermal transfer process
2.3 - Efficiency
2.4 - Governing equations for TEG model
2.5 - Boundary conditions for TEG model
2.6 - Numerical solution
3 - TEG model establishment and validation
3.1 - Establishment and simplification of TEG model
3.2 - Model validation
4 - Effects of layout on the TEG performance
5 - Conclusions
Acknowledgment
References
8 - Spatio-temporal patterns for human-based architecture to solve metropolitan collapse in Latin America
1 - Introduction
2 - Architecture as an intelligent living organism
2.1 - “Space-Time” rule of growth
2.2 - Intelligence of evolution
2.2.1 - Intelligence of Latin American endemic species
2.2.2 - Human intelligence through cultural evolution in Latin America
2.2.3 - Human intelligence evolution and artificial intelligence emergence
3 - Realizing spatio-temporal architecture
3.1 - Materials and methods
3.1.1 - Self-organization
3.2 - Spatio-temporal mathematical models
3.2.1 - Cellular automata
4 - Developing the spatio-temporal architecture in Latin America (case study)
4.1 - Demographic and anthropogenic study of the Colombian population
4.1.1 - Materiality and systems of bioactive design
4.1.2 - Lateral cities attained by possible adjacent and cellular automata urbanism
4.1.3 - Algorithms applied to the creation of spatio-temporal architecture
5 - Conclusion
References
9 - The nexus of climate change and urbanization
1 - Introduction
2 - Part 1: how urbanization impacts climate change
2.1 - Transportation
2.2 - Buildings’ energy demand
3 - Part 2: how climate change impacts urban life
3.1 - Increasing buildings’ energy demand for cooling
3.2 - Exacerbating air pollution
3.3 - Affecting the quality of adjacent waters
3.4 - Affecting city dwellers’ health and productivity
3.5 - Causing acid rains
3.6 - Ripple impacts on the economy
3.7 - Contributing to the wildfires impacting cities
3.8 - Affecting the quality of life and welfare
3.9 - Damaging building structures and deterioration
4 - Part 3: Fundemental climate change mitigation strategies in cities
4.1 - Emission control through transportation management
4.2 - Preservation and restoration of green space and open space in cities
4.3 - Smart growth and compact development
4.4 - Building and neighborhood renovations
4.5 - Maximized collaboration and holistic approaches
4.6 - Worldwide commitment to sustainable development in action
5 - Summary
References
10 - Bioshading system design method (BSDM)
1 - Introduction
2 - Related work
3 - Bioshading system design method
4 - Architecture domain—definition process
5 - Nature domain—abstraction process
6 - Artifact domain—emulation process
7 - Discussion
8 - Conclusions
References
11 - Green science: smart building technology to mitigate global energy and water crises
1 - Introduction
2 - Material, methods, and simulation
2.1 - Design of PV panel
2.2 - Electrostatic force generation
3 - Results and discussion
4 - Electricity transformation
4.1 - Electrostatic force analysis
4.2 - On-site water treatment
5 - Conclusions
Acknowledgments
References
12 - How green energy giants increase their revenues? Impacts on global warming
1 - Introduction
2 - Stock market data variation
2.1 - Iberdrola
2.2 - E.ON
2.3 - Alstom
2.4 - ENEL
2.5 - General Electric
2.6 - Scottish and Southern Energy
3 - Influencing factors for share price variation
3.1 - Strategic decisions
3.2 - Financial activities
3.3 - Management
3.4 - Dividend
3.5 - Other factors
4 - Results, evaluation, and discussion
5 - Conclusions
References
Index
Back cover