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Sustainable Energy Storage in the Scope of Circular Economy Comprehensive resource reviewing recent developments in the design and application of energy storage devices Sustainable Energy Storage in the Scope of Circular Economy reviews the recent developments in energy storage devices based on sustainable materials within the framework of the circular economy, addressing the sustainable design and application of energy storage devices with consideration of the key advantages and remaining challenges in this rapidly evolving research field. Topics covered include: Sustainable materials for batteries and fuel cell devices Multifunctional sustainable materials for energy storage Energy storage devices in the scope of the Internet of Things Sustainable energy storage devices and device design for sensors and actuators Waste prevention for energy storage devices based on second life and recycling procedures With detailed information on today’s most effective energy storage devices, Sustainable Energy Storage in the Scope of Circular Economy is a key resource for academic researchers, industrial scientists and engineers, and students in related programs of study who wish to understand the state of the art in this field.
Sustainable Energy Storage in the Scope of Circular Economy Comprehensive resource reviewing recent developments in the design and application of energy storage devices Sustainable Energy Storage in the Scope of Circular Economy reviews the recent developments in energy storage devices based on sustainable materials within the framework of the circular economy, addressing the sustainable design and application of energy storage devices with consideration of the key advantages and remaining challenges in this rapidly evolving research field. Topics covered include: Sustainable materials for batteries and fuel cell devices Multifunctional sustainable materials for energy storage Energy storage devices in the scope of the Internet of Things Sustainable energy storage devices and device design for sensors and actuators Waste prevention for energy storage devices based on second life and recycling procedures With detailed information on today’s most effective energy storage devices, Sustainable Energy Storage in the Scope of Circular Economy is a key resource for academic researchers, industrial scientists and engineers, and students in related programs of study who wish to understand the state of the art in this field.
The growth of renewable energy technologies, mainly wind and solar, demands the development of practical and economically viable energy storage technologies. This book explores the current state-of-the-art of large-scale energy storage and examines the likely environmental impacts of the main categories based on the types of energy stored.
Critical minerals play a vital role in the ongoing energy transition, which aims to shift global energy systems towards more sustainable and low-carbon alternatives. These minerals, also known as critical minerals, are essential components in various clean energy technologies such as wind turbines, solar panels, electric vehicles, and energy storage systems. They possess unique properties that enable efficient energy generation, storage, and transmission. For instance, neodymium, a rare earth element, is crucial for the production of high-performance magnets used in wind turbines and electric motors. Lithium, another critical mineral, is a key component in rechargeable batteries powering electric vehicles and energy storage solutions. As the demand for clean energy technologies continues to rise, securing a sustainable and reliable supply of critical minerals becomes increasingly important to support the global energy transition and reduce dependence on fossil fuels. In this book, we investigate various aspects of critical mineral governance in the context of sustainability transition. We give perspectives around the critical metal requirements of sustainability transition in a forward-looking manner. We discuss the answers to the following questions: What role do the critical raw materials play in the transition to a sustainable economy and energy systems transformation? What are the bottlenecks in achieving a sustainable critical material supply? How do the critical minerals enable renewable energy transition and sustainable development? What is their role in the sustainability transition? How is mineral criticality assessed? And how critical are minerals? What are some regional differences in terms of critical mineral availability, processing capacity, and the supply chain? What strategy should be followed in deciding between primary raw materials and secondary raw materials in supplying critical raw materials for the transition to a sustainable economy? What is the (known) critical material budget, and how does it fit with the climate pledges? The authors of the chapters of this book take a multi-perspective approach and provide insights from industrial ecology, environmental engineering, and sustainable management of natural resources. The information provided will help readers to understand critical metal requirements of present and future key technologies and will help societies to develop and implement sustainable supply strategies.
Çukurova University, Turkey in collaboration with Ljubljana University, Slovenia and the International Energy Agency Implementing Agreement on Energy Conservation Through Energy Storage (IEA ECES IA) organized a NATO Advanced Study Institute on Thermal Energy Storage for Sustainable Energy Consumption – Fundamentals, Case Studies and Design (NATO ASI TESSEC), in Cesme, Izmir, Turkey in June, 2005. This book contains manuscripts based on the lectures included in the scientific programme of the NATO ASI TESSEC.
The book contains selected and peer-reviewed papers presented during the ‘International Workshop on Renewable Energy and Storage Devices for Sustainable Development’ (IWRESD-2021). The book covers recent research on various applications and scientific developments in the areas of renewable energy. These topics are solar cells, sustainable energy conversion, processing technologies, instrumentation, energy storage devices, solar thermal applications, batteries, new materials, and processes to develop low-cost renewable energy-based technologies, etc. This book will be of interest to researchers and engineers across a variety of fields.
The book Materials for Sustainable Energy Storage Devices at the Nanoscale anticipates covering all electrochemical energy storage devices such as supercapacitors, lithium-ion batteries (LIBs), and fuel cells, transformation and enhancement materials for solar cells, photocatalysis, etc. The focal objective of the book is to deliver stunning and current information to the materials application at nanoscale to researchers and scientists in our contemporary time towardthe enhancement of energy conversion and storage devices. However, the contents of the proposed book, Materials for Sustainable Energy Storage at the Nanoscale, will cover various fundamental principles and wide knowledge of different energy conversion and storage devices with respect to their advancement due to the emergence of nanoscale materials for sustainable storage devices. This book is targeted to be award-winning as well as a reference book for researchers and scientists working on different types of nanoscale materials-based energy storage and conversion devices. Features Comprehensive overview of energy storage devices, an important field of interest for researchers worldwide Explores the importance and growing impact of batteries and supercapacitors Emphasizes the fundamental theories, electrochemical mechanism, and its computational view point and discusses recent developments in electrode designing based on nanomaterials, separators, and fabrication of advanced devices and their performances Fabian I. Ezema is a professor at the University of Nigeria, Nsukka. He earned a PhD in Physics and Astronomy from the University of Nigeria, Nsukka. His research focused on several areas of Materials Science, from synthesis and characterizations of particles and thin-film materials through chemical routes with emphasis on energy applications. For the last 15 years, he has been working on energy conversion and storage (cathodes, anodes, supercapacitors, solar cells, among others), including novel methods of synthesis, characterization and evaluation of the electrochemical and optical properties. He has published about 180 papers in various international journals and given over 50 talks at various conferences. His h-index is 21 with over 1500 citations and he has served as reviewer for several high impact journals and as an editorial board member. Dr. M.Anusuya, M.Sc., M.Phil., B.Ed., PhD is specialized in Material science, Thin Film Technology, Nano Science, and Crystallography. She is working as a Registrar of Indra Ganesan Group of Institutions, Trichy, Tamilnadu, India. Earlier to this, she served as a Vice-Principal at Trichy Engineering College, Trichy, Tamilnadu, India.. Being an administrator and teacher, with more than 25 years’ experience, for her perpetual excellence in academics she has been recognized with many awards. She has received over 45 awards in Academic and Social Activity. She has published more than 30 research papers in National and International journals, 7 chapters in edited books, 5 patents, presented 50 papers in the conferences and organized more than 200 webinars, both national and internationally. Dr Assumpta C. Nwanya is a Lecturer and a FLAIR (Future Leaders - African Independent Research) Scholar at the Department of Physics and Astronomy, University of Nigeria, Nsukka. She obtained her PhD in 2017 (University of Nigeria, Nsukka) with specialisation in the synthesis of nanostructured materials for applications in photovoltaics and electrochemical energy storage (batteries and supercapacitors) as well as for sensing. She was a Postdoctoral Fellow under the UNESCO-University of South Africa (UNISA) Africa Chair in Nanoscience and Nanotechnology (2018-2020). She is a research Affiliate with the SensorLab, University of the Western Cape Sensor Laboratories, Cape Town, South Africa. Dr Nwanya is a very active researcher and has published more than 85 scientific articles in high impact journals and has a Google Scholar’s H-index of 24 and 1475 citations.
In this thesis, the battery storage needed for a 100% renewable economy was calculated. It was determined that the use of batteries as a worldwide energy storage solution is not viable. Other systems, such as power-to-gas, would undoubtedly be a better match, as they are much less resource-intense, and they could be combined with the existing natural gas infrastructure for lowered costs. Data was gathered for two regions that would be studied in detail. These regions were (1) Germany, Austria and Luxemburg, and (2) California. An in-depth analysis of the load and renewable generation (from solar and wind) profiles was done, which was used to calculate the amount of battery storage that would be needed in the area, as well as the requirements that an electrolyzer should be able to meet. Data was also gathered for the world, which enabled a study about consumption, generation and current renewable capacity, among others. Solar irradiation and wind maps were used to estimate the potential of each of the renewable sources studied to provide energy in the scenario of a 100% renewable economy. A theoretical approach about electrolyzer technologies, batteries and practical aspects of hydrogen as a gas fuel can also be found in the thesis. The available data for the two regions studied, along with the results of their storage calculations, was used to calculate the fraction of energy that was provided by each of the renewable sources studied. With this information, an equation was obtained and used to calculate the storage needed for other regions in the world if their approximate renewable potential (fraction) and consumption were known. The estimated total energy storage for the world was then calculated considering each of the continents and was found to be a total of 19,981 TWh (100% roundtrip efficiency - ideal battery). Since the average energy density of batteries is known, it is estimated that this amount of storage would require a 133,205 Mt battery, and since the estimated composition of lithium-ion batteries is also known, it was calculated that to build such an amount of storage would be quite resource-intense: 3,143.64 Mt of lithium and 25,815.13 Mt of cobalt. If the reader takes into consideration that the lithium and cobalt reserves are estimated to be about 53 Mt and 145 Mt, respectively, it is easy to see that the calculated amounts required for the battery are, by far, too large to be executed. Due to the low cost of extracted lithium, the fraction of the metal used today that comes from recycling is scaringly close to zero. Most of the recycling processes for lithium are currently only at research stage, and the majority of them combine physical (battery dismantlement and crushing, along with physical separation of compounds) and chemical processes (leaching, extractions, precipitations), the latter being the ones that have traditionally been used in the mine industry to extract metals (hydrometallurgy). They use harsh chemicals that can be cleaned and reused, and finally sent to a dedicated treatment plant as it is done in the chemical industry. These results were obtained by means of gathering and analyzing data on energy consumption and generation profiles, and considering renewable capacities for solar and wind, in the case of the specific regions; considering information on global and continental-based energy consumption and generation amounts, and renewable potentials for the worldwide estimations; and studying the composition and characteristics of the lithium-ion batteries used today, along with the available critical metals reserves, to calculate the amounts of resources that would be needed to fabricate the calculated energy storage devices.
Energy materials are particularly important from a sustainability perspective for advancing renewable energy systems, including energy production and storage. Their appropriate use and development require quantitative assessment methods. Life Cycle Assessment (LCA) is a method to support sustainable development that can be used to identify environmental hotspots and compare different technologies. The purpose of this research is to support development of several energy materials and make LCA a more relevant tool for sustainability assessment by extending its use in two emerging directions: assessment of technologies at the early stage of development, and by supporting more resource-effective choices for a circular economy. The research objectives focus on informing the development of technologies and identifying methodological challenges and opportunities by applying LCA to three energy-technology case studies, each at a different technological maturity level. In the first case study, alkaline batteries, currently at a high maturity level (incumbent products), are evaluated using LCA in combination with a circular economy indicator, the Material Circularity Indicator (MCI). The aim was to investigate opportunities to combine the two methods, while considering trade-offs between indicators for different strategies for battery design and management. In the second case study, nickel-cobalt hydroxide charge storage electrodes, currently at a low maturity level (laboratory-scale), are evaluated to investigate environmental hotspots and preferred synthesis route. In the third case study, organic photovoltaic portable chargers for small electronics, currently at a medium maturity level (pilot-scale), are evaluated for replacing conventional electricity grid for charging a mobile phone. The results of the alkaline batteries case study show the value and meaning of the MCI circular economy indicator to evaluate resource strategies as compared to LCA category and indicator results. In this context, an approach for combining and presenting the MCI indicator is proposed, and a need to improve characterization of material quality losses of secondary (recycled) material was identified. The electrodes case study offers insights on the environmental hotspots and relative status among technology alternatives, including the benefit of certain process stages and synthesis routes. The most favorable operating parameters in terms of current density and device lifetime expectations are identified. The analysis of photovoltaic chargers shows their environmental-performance potential given the geographical and use-intensity contexts. The chargers have shown as potentially valuable substitutes to local electricity grids in three of six countries given frequent use, and for specific impact categories. Case studies on electrodes and chargers demonstrate uncertainties in relation to allocation of reference flow to functional unit, which are addressed conducting scenario and break-even analysis. Given challenge and carried out responses, involve increasing efforts in the interpretation phase of LCA, an observation with potentially broader implications to the assessment of emerging technologies in LCA. Further research should consider how circular economy indicators and could be used with and complement quantitative assessment methods such as LCA. In the context of LCA of emerging technologies, it is recommended that more emphasis is given to further classification of future-oriented LCA studies of emerging technologies, in order to better frame and organize methodological advancements in this area. A recommendation is also made in consideration to application of attributional and consequential LCA approaches in guiding technology development at different stages of technological maturity.
This book presents design principles, performance assessment and robust optimization of different poly-generation systems using renewable energy sources and storage technologies. Uncertainties associated with demands or the intermittent nature of renewables are considered in decision making processes. Economic and environmental benefits of these systems in comparison with traditional fossil fuels based ones are also provided. Case studies, numerical results, discussions, and concluding remarks have been presented for each proposed system/strategy. This book is a useful tool for students, researchers, and engineers trying to design and evaluate different zero-energy and zero-emission stand-alone grids.