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J. Jurasz - Complementarity of Variable Renewable Energy Sources Complementarity of Variable Renewable Energy Sources 1st Edition Editors: Jakub Jurasz, Alexandre Beluco No. of pages: 744 Language: English Published: May 23, 2022 Imprint: Academic Press Paperback ISBN: 9780323855273  Complementarity of Variable Renewable Energy Sources consolidates current developments on the subject, addressing all technical advances, presenting new mapping results, and bringing new insights for the continuation of research and implementation on this fascinating topic. By answering questions such as How can complementarity be used in the operation of large interconnected systems?, What is the real applicability potential of energetic complementarity?, and How will it impact energy generation systems?, this title is useful for all researchers, academic and students investigating the topic of renewable energy complementarity in systems. In just over a decade, the subject of energy complementarity has experienced a growing presence and understanding by researchers and managers of energy resources looking to enhance energy systems. Early research proposed methods to quantify complementarity, the effects of complementarity on performance of hybrid systems, and how to identify and map complementarity between solar energy, wind energy and hydroelectric energy systems. Key features Includes chapter maps to visualize system performance under different complementarity indexes Addresses complementarity in the operation of large and small to medium-sized hybrid systems Provides methods for determining complementarity between various energy sources About the editors Jakub K. Jurasz is an assistant professor at Wrocław University of Science and Technology, Poland. He is a former postdoctoral researcher at MDH University, Västerås, Sweden, as a member of the Future Energy Center Group coordinated by Prof. Jinuye Yan. His PhD thesis was dedicated to the optimal operation of solar–wind-pumped storage systems. Currently, he continues his research in the area of renewable energy sources, power system transformation, and water–food–energy nexus. Alexandre Beluco is a professor at Federal University of Rio Grande do Sul, Brazil. His doctoral thesis was dedicated to the study of energetic complementarity, and he was one of the pioneers in addressing this topic. His research work is focused on hybrid energy systems, and more recently on hybrid storage systems, looking for the effects of complementarity and also for solutions to local problems, among other topics. Table of contents Preface Chapter 1 Research trends in renewable energy complementarity: a bibliometric analysis 1.1 Introduction 1.2 Methodology 1.3 Results and discussion 1.4 Conclusion Appendix A Appendix B References Chapter 2 Metrics and indices used for the evaluation of energetic complementarity—a review 2.1 Introduction: metrics and indices 2.2 Metrics and indices that assess complementarity in time or space 2.3 Metrics that assess the reliability of the cogeneration 2.4 Complementarity between more than two sources 2.5 Final notes References Chapter 3 Multidimensional metrics for complementarity 3.1 Introduction 3.2 Fluctuation evaluation indicators 3.3 Complementarity evaluation index system 3.4 Evaluation index system for the contribution of complementarity to power system 3.5 Refined evaluation method for complementary characteristics 3.6 Conclusion List of Abbreviations Reference Chapter 4 Geographic information systems (GIS) tools in complementarity research—estimation and visualization 4.1 Introduction 4.2 Geographic information systems tools employed for assessing energetic complementarity 4.3 Assessing complementarity using geographic information systems: previous studies worldwide 4.4 Final notes References Chapter 5 A survey on temporal and spatial complementarity between wind and solar resources along the coast of northeastern Brazil 5.1 Introduction 5.2 Temporal complementarity 5.3 Spatial complementarity 5.4 Coast of northeastern Brazil 5.5 Data considered in this study 5.6 Results and discussion 5.7 Final remarks Acknowledgments References Chapter 6 Complementarity beyond correlation 6.1 Introduction 6.2 Quantifying complementarity 6.3 Examples 6.4 Case of study: complementarity in the Colombian electricity system 6.5 Discussion and final remarks Funding References Chapter 7 Global complementarity of renewable energy sources 7.1 Introduction 7.2 Methodology 7.3 Results and discussion 7.4 Complementarity between solar and wind energy on the global scale 7.5 Conclusions Appendix Acknowledgment References Chapter 8 On the role of resource complementarity in siting renewable power plants and its impact on power system design and economics 8.1 Introduction 8.2 Methodology 8.3 Case study 8.4 Results 8.5 Conclusion References Chapter 9 Complementary behavior of solar and wind energy based on the reported data on the European level—a country-level analysis 9.1 Introduction 9.2 Analysis 9.3 Discussion and conclusions Acknowledgments References Chapter 10 Meteorological assessment of coupled wind–solar power generation regimes in Spain 10.1 Introduction 10.2 Data and methods 10.3 Results 10.4 Discussion, summary, and conclusions Acknowledgments References Chapter 11 Impact of climate change on wind and solar energy sources complementarity: a case study of the northeast Brazilian region 11.1 Introduction 11.2 Preliminary concepts 11.3 Methodology 11.4 Case study 11.5 Final considerations on the case study 11.6 Conclusions References Chapter 12 A comparative study of correlation coefficients used to assess the solar and wind complementarity in Mexico 12.1 Introduction 12.2 Energetic complementarity studies 12.3 Correlation coefficients 12.4 Canonical correlation analysis 12.5 Cross-correlation 12.6 Wind and solar data 12.7 Results and discussion 12.8 Conclusions References Chapter 13 Short-term complementarity of utility-scale solar and wind power plants 13.1 Introduction 13.2 Case study 13.3 Methodology 13.4 Results and discussion 13.5 Conclusions References Chapter 14 Designing hybrid systems operation in the context of resources complementarity 14.1 Introduction 14.2 The involved cities in this study 14.3 Mathematical modeling and optimization 14.4 Results and discussion 14.5 Conclusions Acknowledgments References Chapter 15 Complementarity analysis of hybrid solar–wind power systems` operation 15.1 Introduction 15.2 Solar and wind power in Algeria 15.3 System modeling and data analysis 15.4 Optimal sizing and operation 15.5 Probability of low generation events 15.6 Conclusions References Chapter 16 Off-grid hybrid systems reliability and transmission line utilization from the perspective of renewables complementarity 16.1 Introduction 16.2 Renewable energy sources and power grid status in Algeria 16.3 Data and methods 16.4 Short discussion on complementarity 16.5 Off-grid renewables-based systems 16.6 Hybrid power stations and transmission line utilization 16.7 Future perspective and challenges 16.8 Conclusions References Chapter 17 Complementary concentrated solar power—wind hybrid system with thermal storage and ORC 17.1 Introduction 17.2 System description 17.3 Methodology and models 17.4 Results and discussion 17.5 Conclusions References Chapter 18 Complementarity of renewable energy sources in the context of the heating sector 18.1 Renewables in heating sector 18.2 Simulating system operation 18.3 Solar and wind performance in heat supply 18.4 Concluding remarks References Chapter 19 Insight into the potential of the energy production by hybrid system: small hydropower and solar photovoltaics 19.1 Introduction 19.2 Basics about hydropower energy and solar photovoltaic plants 19.3 Sizing methodologies 19.4 Conclusion References Chapter 20 Operations management of large hydro–PV hybrid power plants: case studies in China 20.1 Introduction 20.2 Robust hydroelectric unit commitment considering integration of large-scale photovoltaic power 20.3 Optimal daily generation scheduling of a hydro–PV power plant 20.4 Long-term reservoir operation to adapt to large-scale photovoltaic power generation References Chapter 21 Small hydropower plants proliferation and fluvial ecosystem conservation Nexus 21.1 Renewable energy agenda and small hydropower proliferation 21.2 Fluvial ecosystem conservation and hydrological alteration 21.3 Environmental flows significance and methods overview 21.4 Concluding remarks References Chapter 22 Complementarity and application of renewable energy sources in the marine environment 22.1 Introduction 22.2 Possibilities of the complementary of the renewables in the marine environment 22.3 Case study of marine complementarity in the Baltic Sea 22.4 Discussion on the possible applications of marine renewables Author contributions References Chapter 23 Complementarity between rare renewable energies 23.1 Introduction 23.2 What are we talking about? 23.3 Tapping untapped, using discarded 23.4 What about complementarity? 23.5 Concluding remark References Chapter 24 Renewable energies in the context of the water–food–energy nexus 24.1 Introduction to the nexus: history, concepts, models, criticisms, challenges, and opportunities 24.2 Water footprint of renewable energies 24.3 Floating photovoltaic systems 24.4 Photovoltaic water-pumping systems 24.5 Agrivoltaics 24.6 Bioenergy: water consumption and land for energy versus land for food 24.7 Wastewater systems 24.8 Conclusions Acknowledgments References Chapter 25 Applications of renewable energy sources in agriculture from complementarity perspective 25.1 Introduction 25.2 Agricultural applications powered by complementary RESs 25.3 Conclusions and future prospects Acknowledgment References Chapter 26 Governing complementarity to enhance environmental, economic, and social benefits of renewable energy 26.1 Introduction 26.2 Renewables 26.3 Complementarity 26.4 Multi-actor participation and governance 26.5 Conclusion References Chapter 27 Dancing with renewables: a holistic perspective encompassing the role of the demand side 27.1 Introduction 27.2 Discussion 27.3 Conclusions References Chapter 28 Teaching about complementarity – proposal of classes for university students – including exercises 28.1 Research trends in renewable energy complementarity: a bibliometric analysis 28.2 Metrics and indices used for the evaluation of energetic complementarity – a review 28.3 Multidimensional metrics for complementarity 28.4 Geographic information systems (GIS) tools in complementarity research – estimation and visualization 28.5 A survey on temporal and spatial complementarity between wind and solar resources along the coast of northeastern Brazil 28.6 Complementarity beyond correlation 28.7 Global complementarity of renewable energy sources 28.8 On the role of resource complementarity in siting renewable power plants and its impact on power system design and economics 28.9 Complementary behavior of solar and wind energy based on the reported data on the European level – a country-level analysis 28.10 Meteorological assessment of coupled wind-solar power generation regimes in Spain 28.11 Impact of climate change on wind and solar energy sources complementarity: a case study of the northeast Brazilian region 28.12 A comparative study of correlation coefficients used to assess the solar and wind complementarity in Mexico 28.13 Short-term complementarity of utility-scale solar and wind power plants 28.14 Designing hybrid systems considering resources complementarity 28.15 Complementarity analysis for hybrid solar-wind power systems` operation 28.16 Off-grid hybrid systems reliability and transmission line utilization from the perspective of renewables complementarity 28.17 Complementary concentrated solar power - wind hybrid system with thermal storage and ORC 28.18 Complementarity of renewable energy sources in the context of heating sector 28.19 Insight into the potential of the energy production by hybrid system 'small hydropower power plant and solar photovoltaic power plant' 28.20 Operations management of large hydro-PV hybrid power plants: case studies in China 28.21 Small hydropower plants proliferation and fluvial ecosystem conservation nexus 28.22 Complementarity and application of renewable energy sources in the marine environment 28.23 Complementarity between rare renewable energies 28.24 Complementarity in the context of water-food-energy nexus 28.25 The role and applications of renewable energies in agriculture from the complementarity perspective 28.26 Governing complementarity to enhance environmental, economic, and social benefits of renewable energy 28.27 Dancing with renewables: a holistic perspective encompassing the role of the demand side References Index 
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