Note: Front Cover -- Advanced Modelling Techniques Studying Global Changes in Environmental Sciences -- Copyright -- Contents -- Contributors -- Preface -- Chapter 1: Introduction: Global changes and sustainable ecosystem management -- 1.1. Effects of Global Changes -- 1.2. Sustainable Ecosystem Management -- 1.3. Outline of This Book -- 1.3.1. Review of ecological models -- 1.3.2. Ecological network analysis and structurally dynamic models -- 1.3.3. Behavioral monitoring and species distribution models -- 1.3.4. Ecological risk assessment -- 1.3.5. Agriculture and forest ecosystems -- 1.3.6. Urban ecosystems -- 1.3.7. Estuary and marine ecosystems -- References -- Chapter 2: Toward a new generation of ecological modelling techniques: Review and bibliometrics -- 2.1. Introduction -- 2.2. Historical Development of Ecological Modelling -- 2.3. Bibliometric Analysis of Modelling Approaches -- 2.3.1. Data Sources and Analysis -- 2.3.2. Publication Output -- 2.3.3. Journal Distribution -- 2.3.4. Country/Territory Distribution and International Collaboration -- 2.3.5. Keyword Analysis -- 2.4. Brief Review of Modelling Techniques -- 2.4.1. Structurally Dynamic Model -- 2.4.2. Individual-Based Models -- 2.4.3. Support Vector Machine -- 2.4.4. Artificial Neural Networks -- 2.4.5. Tree-Based Model -- 2.4.6. Evolutionary Computation -- 2.4.7. Ordination and Classification Models -- 2.4.8. k-Nearest Neighbors -- 2.5. Future Perspectives of Ecological Modelling -- 2.5.1. Big Data Age: Data-Intensive Modelling -- 2.5.2. Hybrid Models -- 2.5.3. Model Sensitivities and Uncertainties -- References -- Chapter 3: System-wide measures in ecological network analysis -- 3.1. Introduction -- 3.2. Description of system-wide Measures -- 3.3. Ecosystem Models Used for Comparison -- 3.4. Methods -- 3.5. Observations and Discussion -- 3.5.1. Clusters of Structure-Based Measures. , 3.5.2. Clusters of Flow-Based Measures -- 3.5.3. Clusters of Storage-Based Measures -- References -- Chapter 4: Application of structurally dynamic models (SDMs) to determine impacts of climate changes -- 4.1. Introduction -- 4.2. Development of SDM -- 4.2.1. The Number of Feedbacks and Regulations Is Extremely High and Makes It Possible for the Living Organisms and Populatio -- 4.2.2. Ecosystems Show a High Degree of Heterogeneity in Space and in Time -- 4.2.3. Ecosystems and Their Biological Components, the Species, Evolve Steadily and over the Long-Term Toward Higher Complexi -- 4.3. Application of SDMs for the Assessment of Ecological Changes due to Climate Changes -- 4.4. Conclusions -- References -- Chapter 5: Modelling animal behavior to monitor effects of stressors -- 5.1. Introduction -- 5.2. Behavior Modelling: Dealing with Instantaneous or Whole Data Sets -- 5.2.1. Parameter Extraction and State Identification -- 5.2.2. Filtering and Intermittency -- 5.2.3. Statistics and Informatics -- 5.3. Higher Moments in Position Distribution -- 5.4. Identifying Behavioral States -- 5.5. Data Transformation and Filtering by Integration -- 5.6. Intermittency -- 5.7. Discussion and Conclusion -- Acknowledgment -- References -- Chapter 6: Species distribution models for sustainable ecosystem management -- 6.1. Introduction -- 6.2. Model Development Procedure -- 6.3. Selected Models: Characteristics and Examples -- 6.3.1. Decision Trees -- 6.3.1.1. General characteristics -- 6.3.1.2. Examples -- 6.3.1.3. Additional remarks -- 6.3.2. Generalised Linear Models -- 6.3.2.1. General characteristics -- 6.3.2.2. Examples -- 6.3.2.3. Additional remarks -- 6.3.3. Artificial Neural Networks -- 6.3.3.1. General characteristics -- 6.3.3.2. Examples -- 6.3.3.3. Additional remarks -- 6.3.4. Fuzzy Logic -- 6.3.4.1. General characteristics -- 6.3.4.2. Examples. , 6.3.4.3. Additional remarks -- 6.3.5. Bayesian Belief Networks -- 6.3.5.1. General characteristics -- 6.3.5.2. Examples -- 6.3.5.3. Additional remarks -- 6.3.6. Summary of Advantages and Drawbacks -- 6.4. Future Perspectives -- References -- Chapter 7: Ecosystem risk assessment modelling method for emerging pollutants -- 7.1. Review of Ecological Risk Assessment Model Methods -- 7.2. The Selected Model Method -- 7.3. Case Study: Application of AQUATOX Models for Ecosystem Risk Assessment of Polycyclic Aromatic Hydrocarbons in Lake Ecos -- 7.3.1. Application of Models -- 7.3.2. Models -- 7.3.2.1. AQUATOX model -- 7.3.2.2. Parameterization -- 7.3.2.2.1. Biomass and physiological parameters of organisms -- 7.3.2.2.2. Characteristics of Baiyangdian Lake -- 7.3.2.2.3. PAHs model parameters -- 7.3.2.2.4. Determining PAHs water contamination -- 7.3.2.2.5. Sensitivity analysis -- 7.3.3. Results of Model Application -- 7.3.3.1. Model calibration -- 7.3.3.2. Sensitivity analysis -- 7.3.3.3. PAHs risk estimation -- 7.3.4. Discussion on the Model Application -- 7.3.4.1. Compare experiment-derived NOEC with model NOEC for PAHs -- 7.3.4.2. Compare traditional method with model method for ecological risk assessment for PAHs -- 7.4. Perspectives -- Acknowledgments -- References -- Chapter 8: Development of species sensitivity distribution (SSD) models for setting up the management priority with water qua -- 8.1. Introduction -- 8.2. Methods -- 8.2.1. BMC Platform Development for SSD Models -- 8.2.1.1. BMC structure -- 8.2.1.2. BMC functions -- 8.2.1.2.1. Fitting SSD models -- 8.2.1.2.2. Determining the best fitting model based on DIC -- 8.2.1.2.3. Uncertainty analysis -- 8.2.1.2.4. Calculating the eco-risk indicator: PAF and msPAF -- 8.2.2. Framework for Determination of WQC and Screening of PCCs -- 8.2.2.1. WQCs calculation -- 8.2.2.2. PCCs screening. , 8.2.3. Overview of BTB Areas, Occurrence of PTSs, and Ecotoxicity Data Preprocessing -- 8.3. Results and Discussion -- 8.3.1. Evaluation of the BMC Platform -- 8.3.1.1. Selection of the best SSD models -- 8.3.1.2. Priority and posterior distribution of SSDs parameters -- 8.3.1.3. CI for uncertainty analysis -- 8.3.1.4. Validation of SSD models -- 8.3.2. Eco-risks with Uncertainty -- 8.3.2.1. Generic eco-risks for a specific substance -- 8.3.2.2. Joint eco-risk for multiple substances based on response addition -- 8.3.3. Evaluation of Various WQC Strategies -- 8.3.3.1. Abundance of toxicity data -- 8.3.3.2. Limitation of toxicity data -- 8.3.3.3. Lack of toxicity data -- 8.3.3.4. Implication for improvement of the local WQC in BTB -- 8.3.4. Ranking and Screening Using Various PCC Strategies -- 8.3.4.1. PNEC -- 8.3.4.2. Eco-risk calculated by BMC -- 8.3.4.3. EEC/PNEC -- 8.3.4.4. PCC list in BTB area -- 8.3.4.5. Implication for update of the local PCC list in BTB -- 8.4. Conclusion -- Acknowledgments -- References -- Chapter 9: Modelling mixed forest stands: Methodological challenges and approaches -- 9.1. Introduction -- 9.2. Review Methodology -- 9.2.1. Literature Review on Modelling Mixed Forest Stands -- 9.2.2. Ranking of Forest Models -- 9.3. Results and Discussion -- 9.3.1. Patterns of Ecological Model Use in Mixed Forests -- 9.3.2. Model Ranking -- 9.3.2.1. FORMIX -- 9.3.2.2. FORMIND -- 9.3.2.3. SILVA -- 9.3.2.4. FORECAST -- 9.3.3. Comparison of the Top-Ranked Models -- 9.4. Conclusions -- Acknowledgments -- References -- Chapter 10: Decision in agroecosystems advanced modelling techniques studying global changes in environmental sciences -- 10.1. Introduction -- 10.2. Approaches Based on Management Strategy Simulation -- 10.2.1. Simulation of Discrete Events in Agroecosystem Dynamics -- 10.2.2. Simulation of Agroecosystem Control. , 10.3. Design of Agroecosystem Management Strategy -- 10.3.1. Hierarchical Planning -- 10.3.1.1. HTN planning concepts -- 10.3.1.2. Planning approach in HTNs -- 10.3.1.3. Illustration based on the problem of selecting an operating mode in agriculture -- 10.3.2. Planning as Weighted Constraint Satisfaction -- 10.3.2.1. Constraint satisfaction problem -- 10.3.2.2. Networks of weighted constraints -- 10.3.2.3. Illustration based on crop allocation -- 10.3.3. Planning Under Uncertainty with Markov Decision Processes -- 10.3.3.1. Markov decision processes -- 10.3.3.2. Illustration using a forest management problem -- 10.4. Strategy Design by Simulation and Learning -- 10.5. Illustrations -- 10.5.1. SAFIHR: Modelling a Farming Agent -- 10.5.1.1. Decision problem -- 10.5.1.2. SAFIHR: Continuous planning -- 10.5.1.3. Overview of the overall operation -- 10.6. Conclusion -- References -- Chapter 11: Ecosystem services in relation to carbon cycle of Asansol-Durgapur urban system, India -- 11.1. Introduction -- 11.2. Methods -- 11.2.1. Study Area -- 11.2.2. Urban Forest -- 11.2.3. Agriculture -- 11.2.4. Anthropogenic Activities -- 11.2.5. Cattle Production -- 11.3. Analysis and Discussion -- 11.3.1. Ecosystem Services and Disservices of Urban Forest -- 11.3.2. Ecosystem Services and Disservices of Agricultural Field -- 11.3.3. Ecosystem Services and Disservices Through Anthropogenic Activities -- 11.3.4. Ecosystem Services and Disservices Through Cattle Production -- 11.3.5. Impact on Biodiversity -- 11.3.6. Cultural Services and Disservices -- 11.3.7. Future Perspective of Ecosystem Services -- 11.4. Conclusions -- Acknowledgments -- References -- Chapter 12: Modelling the effects of climate change in estuarine ecosystems with coupled hydrodynamic and biogeochemical mode -- 12.1. Introduction -- 12.2. Coupled Hydrodynamic and Biogeochemical Models. , 12.3. Models as Effective Tools to Support Estuarine Climate Change Impacts Assessment.

Note: Cover -- Half Title -- Title -- Copyright -- Dedication -- Contents -- List of contributors -- Preface -- Foreword -- Acknowledgements -- List of journals -- 1 Environmental science on the move -- 2 The sustainability debate -- 3 Environmental politics and policy processes -- 4 Environmental and ecological economics -- 5 Biodiversity and ethics -- 6 Population, adaptation and resilience -- 7 Climate change -- 8 Managing the oceans -- 9 Coastal processes and management -- 10 GIS and environmental management -- 11 Soil erosion and land degradation -- 12 River processes and management -- 13 Groundwater pollution and protection -- 14 Marine and estuarine pollution -- 15 Urban air pollution and public health -- 16 Preventing disease -- 17 Environmental risk management -- 18 Waste management -- 19 Managing the global commons -- Index.

Note: Intro -- Preface -- Introduction - Perspectives of Water Resources Management -- Abstract -- 1.1. Water and the Society -- 1.2. Availability of Water on the Earth -- 1.3. Hydrologic Cycle and Human Intervention -- 1.4. Global Climate Change and the Water Resource -- 1.5. Future Challenges of Water Resources Management -- Relevant Journals -- References -- Assessment of Water Resources -- Abstract -- 2.1. Estimation of Surface Water Resource -- 2.2. Investigation of Groundwater -- 2.2.1. Planning an Investigation -- 2.2.2. Steps Involved in a Site Investigation -- Field Reconnaissance -- Literature Search -- Determination of Data Requirement and Selection of Method -- 2.2.3. Approaches of Investigation -- 2.3. MechanicalApproach -- Drilling of Exploratory Bore Wells -- Avoiding Cross Contamination during Drilling -- Limitations -- Sampling Interval and Representation -- 2.4. Geo-PhysicalApproach -- Principle of Geophysical Approach -- 2.5. ElectricalMethod -- Principle of the Method -- 2.6. Electromagnetic Method -- Principle of the Method -- 2.7. Estimation of Groundwater Potential -- 2.7.1. Quantitative Estimation of Groundwater -- 2.7.2. Groundwater Availability for Pumping in Terms of Potential Recharge -- 2.7.3. Groundwater Availability in Terms of Safe Yield -- Determination of Specific Yield -- 2.7.4. Water Budget Approach -- Expression of Water Budget -- I-Input -- Estimation of Potential Recharge -- O-Output -- Surface Runoff -- Groundwater Discharge -- Evapotranspiration -- S - Storage -- Estimation of Absolute Change (Amount) -- 2.8. Groundwater Development Potential and Issues in Saline/Coastal Areas -- 2.9. Environmental Flow Assessment -- Building Block Method (BBM) -- Drift Method -- Relevant Journals -- Exercises -- Estimation of Groundwater Recharge -- Abstract -- 3.1. Concept, Purpose and Significance of Recharge Estimation. , Concept -- Purpose -- Significance -- 3.2. Relevant Terminologies -- Infiltration -- Percolation -- Seepage -- Actual Recharge -- Potential Recharge -- Direct/Diffuse Recharge -- Indirect Recharge -- Localized/Focused Recharge -- Artificial Recharge -- Natural Recharge -- Induced Recharge -- Base-Flow -- Darcy's Equation or Law -- Deep Drainage -- Drainage Basin -- Groundwater Basin -- Hydrologic Budget or Water Budget -- Piston Flow or Plug Flow -- Preferential Recharge -- Recharge Area -- Rejected Recharge -- Residence Time -- Residual -- 3.3. Sources and Mechanism of Recharge -- 3.4. Factors Affecting Recharge -- Soil Factor -- Topography -- Land-Surface and Vegetation -- Sub-Surface Geology -- Climate -- Rainfall Amount and Its Distribution -- Evaporative Demand of the Atmosphere -- Existence of Water Bodies or Streams -- Storage Capacity of the Aquifer -- Depth to Aquifer -- 3.5. GW Recharge-Discharge/Withdrawal Relationship and Sustainability Issues -- 3.6. Functional Form of Recharge and Limiting Conditions -- 3.6.1. Functional Form -- 3.6.2. Limiting Conditions -- 3.7. Recharge Estimation - Available Approaches and Methods -- Initiating Recharge Study/Preliminary Recharge Estimate -- Recharge Estimation Techniques -- 3.7.1. Water Budget (or Water Balance) Method -- Principle of the Method -- Boundaries Require -- Mathematical Formulation of Water Budget Equation -- Merits of Water Budget Method -- Demerits of Water Budget Method -- 3.7.2. Water-Table Fluctuation Method -- Principle of the Method -- Appropriateness/Suitability of the Method -- Assumptions -- Mathematical Formulation -- Limitations -- Merits of the Method -- Demerits of the Method -- 3.7.3. Lysimeter Method -- Measurement Procedure -- ET Measurement -- Limitations -- Merits of Lysimeter Method -- Demerits/Shortcomings -- 3.7.4. Seepage Meter Method -- Principle of the Method. , Detail Method -- Merits -- Demerits -- 3.7.5. Field Plot Water Balance -- Principle -- Detail Method -- Merits of the Method -- Demerits -- 3.7.6. Soil-Water Balance Approach -- Merits -- Demerits -- 3.7.7. Zero-Flux Plane -- Principle -- Methods -- In Absence of a Zero Flux Plane -- Limitations -- Merits -- Demerits -- 3.7.8. Darcy's Law Approach -- 3.7.8.1. Darcy's Law Method for Unsaturated Zone -- Principle -- Method -- Suitability/Limitations -- Merits -- Demerits -- 3.7.8.2. Darcy's Law Method for Saturated Zone -- Merits -- Demerits/Shortcomings -- 3.7.9. Base-Flow Discharge -- Principle of the Method -- Detail Method -- Merits -- Demerits -- 3.7.10. Numerical Method -- 3.7.10.1. Numerical Method for Watershed modeling -- Merits -- Demerits -- 3.7.10.2. Numerical Modeling for Unsaturated-Zone Studies -- Merits -- Demerits -- 3.7.10.3. Numerical Model for Saturated-Unsaturated Flow -- Merits -- Demerits -- 3.7.11. Tracer Techniques -- Characteristics of an Ideal Tracer -- 3.7.11.1. Chemical Tracer -- Perspectives and Procedure -- Merits -- Demerits -- 3.7.11.2. Isotopic Tracer -- Stable Isotope -- Radioactive Isotope -- Detail Working Method -- Merits -- Demerits -- 3.7.11.3. Environmental Tracers -- Chloride Mass Balance (CMB) Approach -- Perspectives and Methods -- Merits -- Demerits -- 3.7.11.4. Historical Tracer -- Perspectives and Procedure -- Merits -- Demerits -- 3.7.11.5. Groundwater Dating -- Perspectives and Methods -- Age from 3H/3He Data -- Use of 14C for Groundwater Age -- Recharge Rate from GW Age -- Characteristics and Considerations -- Merits -- Demerits -- 3.7.11.6. Limitations/Restrictions of Using Tracer -- 3.7.11.7. Interpretation of Tracer Results -- 3.7.11.8. Merits of Tracer Techniques over Other Methods, and Concerns -- Merits -- Concerns -- 3.7.12. Empirical Method -- Anderson et al. (1992) Formula -- Chaturvedi Formula. , Kumar and Seethapathi Formula -- Merits of Empirical Methods -- Demerits -- Future Refinement -- 3.7.13. Application of Multiple Techniques -- 3.8. Recharge Estimation Related to Aquifer Vulnerability to Contamination -- 3.9. Choosing an Appropriate Method for Recharge Estimation -- 3.9.1. Factors to be Considered in Selecting a Recharge Estimation Method -- Aim or Objective of Recharge Estimation -- Required Accuracy of Recharge Estimate -- Geomorphology of the Target Area -- Climate -- Geology -- Source and Mechanism of Recharge -- Temporal and Spatial Scale Required -- Availability of Time and Money -- Limitations/Suitability of the Methods themselves -- 3.9.2. Optimization among Different Factors and Estimating Recharge -- 3.10. Developing a Conceptual Model of Recharge/Conceptualizing a Recharge Model -- 3.11. Challenges in Predictive Relations and Recharge Generalization -- 3.12. Geological Mapping of the Recharge Areas -- General Guidelines for Mapping Recharge Area -- 3.13. Methods for Estimating/Measuring Components of Water Budget Equation -- 3.13.1. Evapotranspiration -- Direct Measurement of ET by Lysimeter -- Indirect Method -- From Field Plot -- From Crop Coefficient -- 3.13.2. Surface Runoff -- From Crop Fields -- SCS Runoff Method -- Peak Runoff from Single Storm Event -- 3.14. Worked Out Problems -- Example 3.1 -- Solution -- Example 3.2 -- Solution -- Example 3.3 -- Solution -- Example 3.4 -- Solution -- Example 3.5 -- Solution -- Example 3.6 -- Solution -- Example 3.7 -- Solution -- Relevant Journals -- Questions/Exercise -- References -- Water-Well Construction and Well Hydraulics -- Abstract -- 4.1. Construction of Water-Well -- 4.1.1. Importance of Proper Design and Construction of Well -- 4.1.2. Types of Well -- Bored Wells -- Drilled Wells -- 4.1.3. Well Construction -- 4.1.3.1. Principal Activities in Well Construction. , Site Selection -- Drilling -- 4.1.3.2. Drilling Methods -- 4.1.3.3. Definition of Relevant Terminologies -- 4.2. Well Design -- 4.2.1. Design Elements and Design Considerations -- Well Depth -- Casing Size and Material Type -- Well Screen -- Slot Size Openings -- Screen Length, Pattern, Total Open Area, and Placement -- Screen Material -- Filter Material -- Casing Materials -- 4.2.2. Design Criteria and Procedure -- Diameter of Slot/SCREEN opening -- Screen Open Area -- Length of Screen -- Position of Screen -- Screen Material -- Hydraulic Criteria/Velocity of Water -- Diameter of Screen Pipe, Vertical Velocity -- Gravel Pack/Filter Material -- 4.3. Well Completion and Development -- 4.3.1. Well Completion -- Well Casing and Sealing -- The Annular Seal -- Annulus Seal -- Well Cap -- Filter Material -- 4.3.2. Well Development -- 4.3.3. Disinfection of Well -- 4.3.4. Economic Considerations -- 4.4. Well Hydraulics -- 4.4.1. Relevant Terminologies -- Specific Capacity -- Well Capacity or Yield -- Well Efficiency -- 4.4.2. Well Yield in Aquifer -- 4.4.2.1. Flow of Water to Well in Unconfined Aquifer -- Theim Equation -- 4.4.2.2. Flow of Water to Well in Confined AQUIFER -- Theis Equation -- Derivation of the Equation -- 4.5. Pumping Test/Well Yield Test and Determination of Aquifer Parameters -- 4.5.1. Relevant Terminologies -- Residual Drawdown -- Specific Capacity -- Well Efficiency -- 4.5.2. Perspectives of Pumping Test -- 4.5.3. General Assumptions in Pumping Test -- 4.5.4. Constant Rate Test -- Observation Wells -- 4.5.5. Step Wise Test -- 4.5.6. Analysis of Pump Test Data -- Theis Method -- Cooper-Jacob Method -- Time-Drawdown Approach -- Distance-Drawdown Approach -- Theis Recovery Approach -- Limitations -- Relevant Journals -- Questions/Exercises -- References -- Management of Water Resources -- Abstract. , 5.1. Concept of Water Resources Management.

Note: Front Cover -- Energy Services Fundamentals and Financing -- Copyright Page -- Contents -- List of Contributors -- 1 Energy services -- 1 Energy services: concepts, applications and historical background -- 1.1 Introduction -- 1.2 Energy and population growth -- 1.3 Energy saving in buildings -- 1.4 Energy use in agriculture -- 1.5 Renewable energy technologies -- 1.5.1 Solar energy -- 1.5.2 Efficient bioenergy use -- 1.5.2.1 Briquette processes -- 1.5.2.2 Improved cook stoves -- 1.5.2.3 Biogas technology -- 1.5.2.4 Improved forest and tree management -- 1.5.2.5 Gasification application -- 1.5.3 Combined heat and power -- 1.5.4 Hydrogen production -- 1.5.5 Hydropower generation -- 1.5.6 Wind energy -- 1.6 Energy and sustainable development -- 1.7 Global warming -- 1.8 Recommendations -- 1.9 Conclusion -- References -- 2 Energy financing schemas -- 2 The promotion of renewable energy communities in the European Union -- 2.1 Overview -- 2.2 The link between the provision of energy services and the increase of energy efficiency -- 2.3 The efficiency gains stemming from distributed generation of energy production -- 2.4 The concept of renewable energy community -- 2.5 The promotion of renewable energy communities in EU law -- 2.6 The promotion of renewable energy communities in the draft National Energy and Climate Plans -- 2.7 Conclusion -- References -- 3 Financial schemes for energy efficiency projects: lessons learnt from in-country demonstrations -- 3.1 Introduction -- 3.2 The proposed methodology -- 3.3 Innovative financing schemes -- 3.3.1 Crowdfunding -- 3.3.2 Energy performance contracting -- 3.3.3 Green bonds -- 3.3.4 Guarantee funds -- 3.3.5 Revolving funds -- 3.3.6 Soft loans -- 3.3.7 Third-party financing -- 3.4 Case study countries -- 3.4.1 Bulgaria -- 3.4.2 Greece -- 3.4.3 Lithuania -- 3.4.4 Spain -- 3.5 Key actors identification. , 3.6 Knowledge transfer -- 3.6.1 Peer-to-Peer learning -- 3.6.2 Capacity building activities -- 3.7 Conclusions -- References -- 3 Energy systems in buildings -- 4 Energy in buildings and districts -- 4.1 Introduction -- 4.2 Thermal comfort -- 4.3 User behavior -- 4.4 Weather conditions under climate change and growing urbanization -- 4.5 Envelope and materials -- 4.6 From passive to nearly zero-energy building design -- 4.7 Smart buildings and home automation -- 4.8 From smart buildings to smart districts and cities -- 4.9 Concluding discussion -- References -- 5 Renewable energy integration as an alternative to the traditional ground-source heat pump system -- Nomenclature -- 5.1 Introduction -- 5.2 Methodology -- 5.2.1 Description of the proposed solution -- 5.2.2 Test procedure -- 5.3 Technical calculation -- 5.3.1 Thermal module -- 5.3.1.1 Geothermal energy -- 5.3.1.2 Thermal solar energy -- 5.3.2 Power module -- 5.3.2.1 Photovoltaic solar energy -- 5.3.2.2 Wind energy -- 5.3.3 Contribution of the suggested installation -- 5.4 Economic and environmental analysis -- 5.4.1 Economic analysis -- 5.4.2 Environmental evaluation -- 5.5 Discussion -- 5.5.1 Sensitivity analysis -- 5.5.1.1 Electricity price -- 5.5.1.2 Electric rate -- 5.5.1.3 CO2 emission factor -- 5.6 Conclusions -- Acknowledgments -- References -- 6 Energy-saving strategies on university campus buildings: Covenant University as case study -- 6.1 Introduction -- 6.1.1 Energy modeling software for buildings -- 6.1.2 Energy conservation measures in buildings -- 6.2 Materials and methods -- 6.2.1 Study location -- 6.2.2 Procedure for data collection -- 6.2.3 Instrumentation and procedure for data analysis -- 6.2.4 Economic analysis -- 6.2.5 Assessment of environmental impacts -- 6.3 Results and discussions -- 6.3.1 Result of energy audit in cafeterias1 and 2. , 6.3.2 Result of energy audit in Mechanical Engineering building -- 6.3.3 Result of energy audit in university library -- 6.3.4 Result of energy audit in health center -- 6.3.5 Result of energy audit in the students' halls of residence -- 6.3.6 Qualitative recommendation analysis -- 6.3.6.1 Replacement of lighting fixtures with light-emitting diode bulbs -- 6.3.6.2 Installation of solar panels on the roofs of selected buildings -- 6.4 Conclusion -- References -- 7 Energy conversion systems and Energy storage systems -- 7.1 Introduction -- 7.2 Energy systems in buildings -- 7.2.1 Energy generation systems -- 7.2.1.1 Combined heat and power system -- 7.2.1.2 Solar photovoltaic system -- 7.2.1.3 Solar thermal system -- 7.2.1.4 Organic Rankine cycle system -- 7.2.1.5 Geothermal system -- 7.2.1.6 Wind turbine system -- 7.2.2 Energy conversion systems -- 7.2.2.1 Heating systems -- 7.2.2.2 Cooling systems -- 7.2.2.3 Ventilation systems -- 7.2.3 Energy storage systems -- 7.2.3.1 Battery energy storage system -- 7.2.3.2 Thermal energy storage system -- 7.3 Conclusion -- References -- 8 Energy systems in buildings -- 8.1 Introduction -- 8.2 Energy-efficient building envelopes -- 8.2.1 Increasing thermal resistance of the building envelope -- 8.2.2 Climate-specific design of energy-efficient envelopes -- 8.3 Renewable energy sources for building energy application -- 8.3.1 Analyzing electrical/thermal loads of a building -- 8.3.2 Consideration of local codes and requirements for renewable energy systems -- 8.3.3 Solar energy systems -- 8.3.3.1 Solar water heating -- 8.3.3.1.1 Flat-plate collectors -- 8.3.3.1.2 Evacuated tube solar thermal collectors -- 8.3.3.1.3 Choice of solar thermal collectors -- 8.3.3.1.3.1 Cost -- 8.3.3.1.3.2 Performance -- 8.3.3.1.3.3 Installation -- 8.3.4 Building-integrated photovoltaic systems -- 8.4 Solar thermal energy storage. , 8.4.1 Types of thermal energy storage technologies -- 8.4.1.1 Sensible heat storage system -- 8.4.1.1.1 Sensible solid heat storage system -- 8.4.1.1.2 Sensible liquid heat storage system -- 8.4.1.2 Sensible cold storage system -- 8.4.1.3 Latent heat storage system -- 8.4.1.4 Thermochemical storage -- 8.5 Wind energy -- 8.5.1 Brief introduction -- 8.5.2 Wind resource assessment -- 8.5.3 Building-integrated/mounted wind turbine -- 8.5.3.1 Building-integrated wind turbines -- 8.5.3.2 Building-mounted wind turbines -- 8.5.3.3 Building-augmented wind turbines -- 8.5.4 Optimizing building-integrated/mounted wind turbine devices -- 8.5.5 Small/micro wind turbines for building application -- 8.6 Heat pumps -- 8.6.1 Air-source heat pumps -- 8.6.2 Ground-source heat pumps -- 8.6.3 Working principles of heat pumps -- 8.6.3.1 The heating cycle -- 8.6.3.2 The cooling cycle -- 8.6.3.3 The defrost cycle -- 8.6.4 Performance measures -- 8.7 Biomass -- 8.8 Summary -- References -- 4 Energy efficiency in industrial sector -- 9 Energy efficiency and renewable energy sources for industrial sector -- 9.1 Introduction -- 9.2 Global energy trends -- 9.3 Energy consumption and emissions in industry -- 9.3.1 General trends -- 9.3.2 Energy and carbon-intensive industrial sectors -- 9.4 Energy efficiency in industry for climate change mitigation -- 9.4.1 The need for innovation -- 9.5 Energy efficiency and renewable sources in industry -- 9.5.1 Bioenergy -- 9.5.2 Solar heat -- 9.6 Case study in Turkey -- 9.6.1 National Energy Efficiency Action Plan -- 9.6.2 General overview -- 9.6.3 Industry and technology -- 9.6.4 Aim of the development plans -- 9.7 Policy options -- 9.7.1 Lessons learned -- 9.7.2 International agreements -- 9.7.3 Procurement -- 9.8 Conclusions -- Acknowledgment -- References -- 10 Energy efficiency in tourism sector: eco-innovation measures and energy. , 10.1 Introduction -- 10.2 State of the arts -- 10.3 Methods and data -- 10.4 Results and discussion -- 10.5 Conclusions -- References -- 5 Energy services markets: development and status quo -- 11 Energy service markets: status quo and development -- 11.1 Introduction -- 11.2 The European framework for energy services -- 11.2.1 Legal framework -- 11.2.2 The European Union energy service markets: market volume, offers, and barriers -- 11.3 The German energy service market -- 11.3.1 Legal framework and information sources -- 11.3.2 Market overview -- 11.4 Developments of segments of the service market -- 11.4.1 Advice services -- 11.4.2 Energy management -- 11.4.3 Contracting -- 11.5 Market development -- 11.6 Conclusions: lessons learned from the German case -- References -- 12 Worldwide trends in energy market research -- 12.1 Introduction -- 12.2 Data -- 12.3 Results -- 12.3.1 Subjects from worldwide publications -- 12.3.2 Journals metric analysis -- 12.3.3 Countries, affiliations, and their main topics -- 12.3.4 Keywords from worldwide publications -- 12.3.5 Cluster analysis based on keywords -- References -- 13 Which aspects may prevent the development of energy service companies? The impact of barriers and country-specific condi... -- 13.1 Introduction -- 13.2 Which are the problems confronted by energy efficiency actions and policy instruments? -- 13.3 Which are the most relevant barriers confronted by energy service companies in different regions? -- 13.4 Removing barriers and promoting energy service companies -- 13.4.1 Actions to remove economic and market barriers -- 13.4.2 Actions to remove funding barriers -- 13.4.3 Enabling frameworks for energy service companies and other energy efficiency actions -- 13.5 Lessons learned and conclusions -- Acknowledgments -- References -- Further reading -- Index -- Back Cover.