- Table View
- List View
Energy Sustainability through Retail Electricity Markets: The Power Trading Agent Competition (Power TAC) Experience (Applied Innovation and Technology Management)
by John Collins Wolfgang Ketter Andreas L. SymeonidisThe world is moving away from demand-driven electricity markets supplied by centralized generation and distribution of fossil-fuel-produced electricity. Increasing reliance on weather-dependent renewable sources will require a shift toward a supply-driven paradigm, while beneficial electrification, including widespread adoption of electric vehicles, heat pumps, and batteries will offer considerable but widely distributed demand flexibility that can be used to compensate for supply variability. The open-source Power Trading Agent Competition (Power TAC) platform simulates a decentralized future, modeling the high complexity of future retail electricity markets. This book describes a variety of approaches to profitable trading in realistic wholesale and retail electricity markets. It presents actionable insights from extensive exploration of policies and business models for retail electricity markets gained from a decade of Power TAC tournaments, and from research inspired by the Power TAC experience. Featuring contributions from tournament designers, competitors, and scientists combining best practices from computer science and economics and management science, this book is of benefit to academics, researchers, practitioners and policy makers in sustainable energy and wholesale and retail electricity markets.
Energy-Sustainable Advanced Materials
by Mark Alston Timothy N. LambertThis book highlights progress towards the capture, storage, and utilization of energy through the development of advanced materials and systems based on abundant elements, materials, and commodities. Energy is critical to human sustainability and a global-scale deployment of renewable energy systems will be required. Hence, the chapters integrate the fundamental aspects that enable the technical advancements in detail, along with an emphasis on the need for highly sustainable materials to enable real impact for humankind: To determine innovation of energy capture and storage through characterizations of materials in areas of electrical generation and electrical storage systems; To demonstrate better performance, economic and environmental advantages than the current state of the art; To define new chemistries and materials for innovations in energy density design through lower operational temperatures, improve safety, expanding operational voltage, battery durability lifetimes, and reduce system costs. Advances critical technical and commercial objectives for novel high energy density materials;Evaluates operational material models for optimizing energy capture that are integrated by configurations as a system; Illustrates utilization of material life cycle assessment for high energy outputs generators for sustainable materials.
Energy Systems: A New Approach to Engineering Thermodynamics
by Renaud GicquelConsidered as particularly difficult by generations of students and engineers, thermodynamics applied to energy systems can now be taught with an original instruction method. Energy Systems applies a completely different approach to the calculation, application and theory of multiple energy conversion technologies. It aims to create the reader’s foundation for understanding and applying the design principles to all kinds of energy cycles, including renewable energy. Proven to be simpler and more reflective than existing methods, it deals with energy system modeling, instead of the thermodynamic foundations, as the primary objective. Although its style is drastically different from other textbooks, no concession is made to coverage: with encouraging pace, the complete range from basic thermodynamics to the most advanced energy systems is addressed. The accompanying Thermoptim™ portal (http://thermoptim.org) presents the software and manuals (in English and French) to solve over 200 examples, and programming and design tools for exercises of all levels of complexity. The portal explains to the user how to build appropriate models to bridge the technological reality with the theoretical basis of energy engineering. Offering quick overviews through e-learning modules moreover, the portal is user-friendly and enables users to quickly improve their proficiency. Students can freely download the Thermoptim modeling software demo version (available in seven languages), and extended options are available to lecturers. A professional edition is also available and has been adopted by many companies and research institutes worldwide (www.s4e2.com). This volume is intended as a textbook for courses in applied thermodynamics, energy systems, energy conversion and thermal engineering taken by senior undergraduate and graduate-level students in mechanical, energy, chemical and petroleum engineering. Students should already have taken a first-year course in thermodynamics. The refreshing approach and exceptionally rich coverage make it a great reference tool for researchers and professionals as well.
Energy Systems: A Project-Based Approach to Sustainability Thinking for Energy Conversion Systems
by Leon LiebenbergENERGY SYSTEMS Reimagine the future of energy production and use with this innovative and state-of-the-art guide This multidisciplinary and comprehensive text features an up-to-date summary of salient energy technologies for quick reference by students and practitioners of energy engineering. Uniquely, the book employs a guided self-study approach with theory provided in “bite-sized” chunks, several worked examples, quantitative and qualitative practice problems, 10 real-world mini-projects, and interviews with young energy innovators and engineering students. The book poses many big and pressing questions, asking the reader to “reimagine our future,” particularly with a focus on sustainable energy. These questions are aligned with characteristics of an entrepreneurial mindset, which are emphasized throughout the book. The book reviews the fundamentals of thermodynamics, fluid mechanics, and quantum mechanics. Chapters explore the full range of energy conversion technologies, including energy supply and demand, the science of global warming, interpretations of sustainability, chemical fuels, carbon capture and storage, internal and external combustion engines, vapor power and refrigeration plants, nuclear power, solar-electricity, solar-heat, fuel cells, wind energy, water energy, and energy storage. The book ends with a brief investigation into what we can do to decarbonize the transportation, industry, buildings, and electric power sectors. Energy Systems: A Project-Based Approach to Sustainability Thinking for Energy Conversion Systems offers an accessible overview of this important subject with an innovative, easy-to-use organization. Built to facilitate active learning and representing the latest research and industrial practice, Energy Systems provides readers with tools and information to evaluate energy systems and to reimagine potential energy solutions. Readers of Energy Systems will also find: Organization designed to blend seamlessly with a 14-week course schedule A balance of robust theoretical and industry-related knowledge and real-world examples throughout Teaching resources including mini-projects, practice problems, remedial appendices, and online study notes Energy Systems is ideal for students and instructors in courses relating to Energy Conversion Systems, Energy Science, Sustainable/Renewable Energy, and the interrelated Social, Technological, Economic, Environmental, and Political aspects. The book will also appeal to practitioners of energy engineering via the numerous state-of-the-art summaries and real-world problems.
Energy Systems and Management
by Ali Nezihi Bilge Ayhan Özgür Toy Mehmet Erdem GünayReaders of this work will find examinations of the current status and future status for energy sources and technologies, their environmental interactions and the relevant global energy policies. The work begins with an overview of Energy Technologies for a Sustainable Future, which examines the correlation between population, economy and energy consumption in the past, and reviews the conventional and renewable energy sources as well as the management of them to sustain the ever-growing energy demand in the future. The rest of the chapters are divided into 3 parts; the first part of the book, "Energy Sources, Technologies and Environment", consists of 12 chapters, which include research on new energy technologies and evaluation of their environmental effects. The second part "Advanced Energy Materials" includes 7 chapters devoted to research on material science for new energy technologies. The final section titled "Energy Management, Economics and Policy" is comprised of 10 chapters about planning, controlling and monitoring energy related processes together with the policies to satisfy the needs of increasing population and growing economy. The chapters are selected works from the International Conference on Energy and Management, which was organized by Istanbul Bilgi University Department of Energy Systems Engineering and PALMET Energy to share the knowledge on the recent trends, scientific developments, innovations and management methods in energy, and held on 5-7th June 2014 at Istanbul Bilgi University.
Energy Systems and Nanotechnology (Advances in Sustainability Science and Technology)
by Dharmendra Tripathi R. K. SharmaThis book presents a very useful and readable collection of chapters in nanotechnologies for energy conversion, storage, and utilization, offering new results which are sure to be of interest to researchers, students, and engineers in the field of nanotechnologies and energy. Readers will find energy systems and nanotechnology very useful in many ways such as generation of energy policy, waste management, nanofluid preparation and numerical modelling, energy storage, and many other energy-related areas. It is also useful as reference book for many energy and nanofluid-related courses being taken up by graduate and undergraduate students. In particular, this book provides insights into various forms of renewable energy, such as biogas, solar energy, photovoltaic, solar cells, and solar thermal energy storage. Also, it deals with the CFD simulations of various aspects of nanofluids/hybrid nanofluids.
Energy Systems And Sustainability: Power For A Sustainable Future
by Bob Everett Godfrey Boyle Stephen Peake Janet RamageHow can we provide clean, safe, sustainable energy supplies for the world despite rising population levels and increasing economic development? Today, energy and sustainability are of primary concern and form the focus of this book and its companion volume, Renewable Energy. Interdisciplinary in its approach and global in its perspective, this book provides a contemporary exploration of the economic, social, environmental, and policy issues raised by current systems of energy use, as well as describing their key physical and engineering features. The historical evolution of the world's energy systems, the principles underlying their use, and their present status and future prospects are analysed, while emphasizing the important issue of sustainability. Beginning with a survey of basic energy concepts, the book describes the magnitude and patterns of human energy needs at various levels. Focus then turns to an overview of the fossil and nuclear-fuelled energy that, together with hydroelectric power and traditional biofuels, supply most of the world's commercial energy needs. Sections on economics describes the basic methods by which the monetary costs of energy are calculated, and discuss the issue of 'external' costs of energy production. The concluding chapters consider the sustainabliity problems associated with both fossil and nuclear fuel use, and ways in which they might be ameliorated by various technological and social developments. This is done in the context of a rising use of renewable energy. · Extensive coverage of the important concepts and issues underpinning modern energy production and its future prospects · Adopts an interdisciplinary approach making the text readable by engineer and policy maker alike Online Resource Centre The Online Resource Centre to accompany Energy systems and Sustainability features: For students: · Links to sources of further information and up-to-date energy statistics · Self-assessment questions For registered adopters of the book: · Figures from the book, available for download
Energy Systems, Drives and Automations: Proceedings of ESDA 2019 (Lecture Notes in Electrical Engineering #664)
by Afzal Sikander Dulal Acharjee Chandan Kumar Chanda Pranab Kumar Mondal Piyush VermaThis book gathers selected research papers presented at the Second International Conference on Energy Systems, Drives and Automations (ESDA 2019), held in Kolkata on 28–29 December 2019. It covers a broad range of topics in the fields of renewable energy, power management, drive systems for electrical machines and automation. Also discussing a variety of related tools and techniques, the book offers a valuable resource for researchers, professionals and students in electrical and mechanical engineering disciplines.
Energy Systems, Drives and Automations: Proceedings of ESDA 2021 (Lecture Notes in Electrical Engineering #1057)
by Jerzy Ryszard Szymanski Chandan Kumar Chanda Pranab Kumar Mondal Kamrul Alam KhanThis book covers the proceedings of the 4th International Conference on Energy Systems, Drives, and Automations (ESDA2021). It comprises interesting topics in renewable energy, power management, drives of electrical machines, and automation. It also discusses different tools and techniques to match the conference theme. This book also comprehensively discusses related tools and techniques and is a valuable resource for researchers and professionals in electrical and mechanical engineering disciplines.
Energy Systems Evaluation: Sustainability Assessment (Green Energy and Technology)
by Jingzheng RenThis book presents various methods for sustainability assessment of energy systems, under various different conditions and scenarios. It answers the questions of how to measure the sustainability of energy systems by adopting appropriate metrics and methods. This book provides readers with a comprehensive view of the frontiers of sustainability assessment methods for energy system analysis. It presents various methodologies, allowing readers to understand: the complete metrics for sustainability assessment; life cycle thinking for sustainability assessment of energy systems; and the advanced sustainability assessment methods for energy systems. This book is of interest to researchers, engineers, decision makers, and postgraduate students within the field of energy systems, sustainability, and decision analysis.
Energy Systems Evaluation: Multi-Criteria Decision Analysis (Green Energy and Technology)
by Jingzheng RenThis book presents various multi-criteria analysis methods for sustainability-oriented analysis and decision-making for energy systems, under various different conditions and scenarios. It presents methodologies to answer the questions relating to which of the options are the most sustainable among the alternatives, and how multi-criteria decision analysis methods can be used to select the most sustainable energy systems. A systematic innovative methodological framework is presented, which enables the most appropriate energy system to be selected under different conditions including: Scientific decision support tools for sustainable energy system selection; Fuzzy, grey, and rough sets based multi-criteria decision analysis; Decision-making models under uncertainties; and The combination of life cycle thinking and multi-criteria decision analysis This book is of interest to researchers, engineers, decision makers, and postgraduate students within the field of energy systems, sustainability, and multi-criteria decision analysis.
Energy Systems in the Era of Energy Vectors
by Vincenzo Naso Fabio OrecchiniWhat lies beyond the era of fossil fuels? While most answers focus on different primary energy resources, Energy Systems in the Era of Energy Vectors provides a completely new approach. Instead of providing a traditional consumption analysis of classical primary energy resources such as oil, coal, nuclear power and gas, Energy Systems in the Era of Energy Vectors describes and assesses energy technologies, markets and future strategies, focusing on their capacity to produce, exchange, and use energy vectors. Special attention is given to the renewable energy resources available in different areas of the world and made exploitable by the integration of energy vectors in the global energy system. Clear definitions of energy vectors and energy systems are used as the basis for a complete explanation and assessment of up-to-date, available technologies for energy resources, transport and storage systems, conversion and use. The energy vectors scheme allows the potential realization of a worldwide sustainable energy system to fulfill global development expectations by minimizing both the impact on the environment, and the international political frictions for access to limited and concentrated resources. Energy Systems in the Era of Energy Vectors is an informative read for researchers and advanced students in industrial, energy and environmental engineering. It also contains valuable information for managers and technicians working in the energy sector.
Energy Systems Modeling: Principles and Applications
by Hooman FarzanehThis book serves as an introductory reference guide for those studying the application of models in energy systems. The book opens with a taxonomy of energy models and treatment of descriptive and analytical models, providing the reader with a foundation of the basic principles underlying the energy models and positioning these principles in the context of energy system studies. In turn, the book provides valuable insights into the varied applications of different energy models to answer complex questions, including those concerning specific aspects of energy policy measures dealing with issues of supply and demand. Case studies are provided in all of the chapters, offering real-world examples of how existing models fit the classification methods outlined here. The book’s remaining chapters address a broad range of principles and applications, taking the reader from the basic principles involved, to state-of-the-art energy production and consumption processes, using modeling and validation/illustration in case studies to do so. With its in-depth mathematical foundation, this book serves as a comprehensive collection of work on modeling energy systems and processes, taking inexperienced graduate students from the basics through to a high-level understanding of the modeling processes in question, while also providing professionals and academic researchers in the field of energy planning with an up-to-date reference guide covering the latest works.
Energy Systems Modeling and Policy Analysis
by B K BalaEnergy Systems Modeling and Policy Analysis covers a wide spectrum of topics including policy analysis and the optimal operational planning of integrated energy systems using a systems approach. This book details the importance of energy modeling and policy analysis, system dynamics and linear programming, modeling of energy supplies, energy demand, and environmental impact. Integrated energy systems at micro- and macro-levels, the application of simulation techniques for integrated rural energy systems, and integrated electric power systems/smart grids are covered as well. Features: Covers topics such as modeling, optimization and control of energy systems, and data analysis collected using a SCADA system Uses system dynamics methodology (based on control systems theory) as well as other modeling tools Focuses on energy and environmental issues Provides optimal operational planning and management of integrated electric power systems and smart grids Covers the simulated planning and management of integrated national electric power systems using system dynamics This book is aimed at graduate students in electrical engineering, energy technology, microgrids, energy policy, and control systems.
Energy Systems of Complex Buildings
by Andrzej Ziębik Krzysztof HoinkaThe production and consumption of energy carriers in complex buildings take place within the network of interconnected energy processes. For this reason, a change carried out in one energy process influences other energy processes. Therefore, all balance equations of energy carriers should be investigated as a whole, and energy management of complex buildings creates a large energy system with internal relationships between energy installations and the equipment, as well as external relationships with the environment. Energy Systems of Complex Buildings presents the system approach to the energy-ecological analysis of energy management in complex buildings. Mathematical models of balancing the direct energy consumption, as well as cumulative energy consumption and cumulative emission of noxious substances are based on input-output analysis. Algorithms devoted to system analysis in the exploitation of energy management of complex buildings are included. In the case of ecological analysis, a new approach is presented basing on the idea of thermoecological costs. In this way, two groups of noxious influence (depletion of non-renewable energy resources and emissions of noxious substances) are taken into account. The LCA energy-ecological analysis of complex buildings has also been presented. Students, building designers, energy auditors, and researchers will learn the methodology of evaluating the energy and ecological effects by applying new technologies and devices in buildings, which influence future investigations concerning the energy and ecological analysis of complex buildings.
Energy Systems Security
by John G. VoellerEnergy Systems Security features articles from the Wiley Handbook of Science and Technology for Homeland Security covering topics related to electricity transmission grids and their protection, risk assessment of energy systems, analysis of interdependent energy networks. Methods to manage electricity transmission disturbances so as to avoid blackouts are discussed, and self-healing energy system and a nano-enabled power source are presented.
Energy Systems Transition: Digitalization, Decarbonization, Decentralization and Democratization (Power Systems)
by Vahid Vahidinasab Behnam Mohammadi-IvatlooEnergy Systems Transition: Digitalization, Decarbonization, Decentralization, and Democratization provides a thorough multidisciplinary overview of the operation of modern green energy systems and examines the role of 4D energy transition in global decarbonization mitigation efforts for meeting long-term climate goals. Contributions present practical aspects and approaches with evidence from applications to real-world energy systems, offering in-depth technical discussions, case studies, and examples to help readers understand the methods, current challenges, and future directions. A hands-on reference to energy distribution systems, it is suitable for researchers and industry practitioners from different branches of engineering, energy, data science, economics, and operation research.
Energy Technologies and Economics
by Patrick A. Narbel Jan Petter Hansen Jan R. LienThis is an easy-to-read textbook providing the reader with the basis to comprehend the major energy technologies from a physical and economical perspective. The journey through the book begins with some background theory on the physics and economics of energy. Major energy technologies (fossil, nuclear and renewable) are explored in-depth, explaining how they work and the costs involved. Finally, the journey ends by exploring the technical and economic feasibility of supplying the world by 2050 with sustainable energy only. Numerous examples are provided to allow the reader to relate important concepts to real-life. The reader's understanding of the material can then be tested using the exercises at the end of each chapter. This textbook is the first to thoroughly present the physics and the economics of energy. It is intended for graduate students and practitioners interested in the field of energy. It also enables the general reader to distinguish between political statement and fact.
Energy Technology 2016: Carbon Dioxide Management and Other Technologies
by Nawshad Haque Li Li Lei Zhang Neale R. Neelameggham Jingxi Zhu Amit Pandey Dirk E. Verhulst Soumendra N. Basu Donna Post Guillen Xuan Liu Tao WangTopics on CO2 sequestration and reduction in greenhouse gas emissions from process engineering and materials for clean energy are covered. Papers addressing sustainable technologies in extractive metallurgy, materials processing and manufacturing industries with reduced energy consumption and CO2 emission are also included, as well as industrial energy efficient technologies including innovative ore beneficiation, smelting technologies, recycling and waste heat recovery. The book also carries contributions from all areas of non-nuclear and non-traditional energy sources, including renewable energy sources such as solar, wind, biomass, etc. The book also emphasizes novel mineral beneficiation, processing, and extraction techniques leading to waste minimization of critical rare-earth materials used in energy systems (e.g., magnets, display and lighting devices). Papers from the following symposia are presented in the book: Energy Technologies and Carbon Dioxide Management High-temperature Systems for Energy Conversion and Storage
Energy Technology 2018: Carbon Dioxide Management And Other Technologies (The Minerals, Metals & Materials Series)
by Tao Wang Lei Zhang Shadia Ikhmayies Mingming Zhang Amit Pandey Donna Post Guillen Cong Wang Elsa Olivetti Huimin Lu Xiaofei Guan Ziqi Sun Neale R Neelameggham John A. Howarter Dirk Verhulst Allie Anderson York R. Smith Sarma PisupatiThis collection focuses on energy efficient technologies including innovative ore beneficiation, smelting technologies, recycling and waste heat recovery. The volume also covers various technological aspects of sustainable energy ecosystems, processes that improve energy efficiency, reduce thermal emissions, and reduce carbon dioxide and other greenhouse emissions. Papers addressing renewable energy resources for metals and materials production, waste heat recovery and other industrial energy efficient technologies, new concepts or devices for energy generation and conversion, energy efficiency improvement in process engineering, sustainability and life cycle assessment of energy systems, as well as the thermodynamics and modeling for sustainable metallurgical processes are included. This volume also includes topics on CO2 sequestration and reduction in greenhouse gas emissions from process engineering, sustainable technologies in extractive metallurgy, as well as the materials processing and manufacturing industries with reduced energy consumption and CO2 emission. Contributions from all areas of non-nuclear and non-traditional energy sources, such as solar, wind, and biomass are also included in this volume. Papers from the following symposia are presented in the book: Energy Technologies and CO2 Management Advanced Materials for Energy Conversion and Storage Deriving Value from Challenging Waste Streams: Recycling and Sustainability Joint Session Solar Cell Silicon Stored Renewable Energy in Coal
Energy Technology 2019: Carbon Dioxide Management and Other Technologies (The Minerals, Metals & Materials Series)
by Tao Wang Xiaobo Chen Donna Post Guillen Lei Zhang Ziqi Sun Cong Wang Nawshad Haque John A. Howarter Neale R Neelameggham Shadia Ikhmayies York R. Smith Leili Tafaghodi Amit PandeyThis collection addresses the need for sustainable technologies with reduced energy consumption and pollutants and the development and application of alternative sustainable energy to maintain a green environment and energy supply. Contributions focus on energy-efficient technologies including innovative ore beneficiation, smelting technologies, and recycling and waste heat recovery, as well as emerging novel energy technologies. Papers also cover various technological aspects of sustainable energy ecosystems, processes that improve energy efficiency, reduce thermal emissions, and reduce carbon dioxide and other greenhouse emissions. Papers from the following symposia are presented in the book: Energy Technologies and Carbon Dioxide ManagementSolar Cell Silicon Advanced Materials for Energy Conversion and Storage
Energy Technology 2020: Recycling, Carbon Dioxide Management, and Other Technologies (The Minerals, Metals & Materials Series)
by Lei Zhang Mingming Zhang Cong Wang Elsa Olivetti Ziqi Sun John A. Howarter Xiaobo Chen Alafara Abdullahi Baba Alan Luo Yulin Zhong Adam PowellThis collection addresses the pressing needs for sustainable technologies with reduced energy consumption and environmental pollutions and the development and application of alternative sustainable energy to maintain a green environment and efficient and long-lasting energy supply. Contributors represent both industry and academia and focus on new and efficient energy technologies including innovative ore beneficiation, smelting technologies, and recycling and waste heat recovery, as well as emerging novel energy solutions. The volume also covers a broad range of mature and new technological aspects of sustainable energy ecosystems, processes that improve energy efficiency, reduce thermal emissions, and reduce carbon dioxide and other greenhouse emissions. Authors also explore the valorization of materials and their embodied energy including byproducts or coproducts from ferrous and nonferrous industries, batteries, electronics, and other complex secondary materials.
Energy Technology 2021: Carbon Dioxide Management and Other Technologies (The Minerals, Metals & Materials Series)
by Alafara Abdullahi Baba Lei Zhang Donna P. Guillen Neale R. Neelameggham Hong Peng Yulin ZhongClean and sustainable energy is of paramount importance for industrial activities, economic development, environment, and welfare of civilians. As such, research on generation, storage, and application of clean energy is a central concern of both academia and industry. This collection addresses the pressing needs for sustainable technologies with reduced energy consumption and environmental pollutions and the development and application of alternative sustainable energy to maintain a green environment and efficient and long-lasting energy supply. Contributors represent both industry and academia and focus on new and efficient energy technologies including innovative ore beneficiation, smelting technologies, and recycling and waste heat recovery, as well as emerging novel energy solutions. The volume also covers a broad range of mature and new technological aspects of sustainable energy ecosystems, processes that improve energy efficiency, reduce thermal emissions, and reduce carbon dioxide and other greenhouse emissions.
Energy Technology 2023: Carbon Dioxide Management and Other Technologies (The Minerals, Metals & Materials Series)
by Shafiq Alam Donna Post Guillen Fiseha Tesfaye Lei Zhang Susanna A. C. Hockaday Neale R. Neelameggham Hong Peng Nawshad Haque Yan LiuClean and sustainable energy is of paramount importance for industrial activities, economic development, environment, and public welfare. Aiming to reach NetZero, researchers in both academia and industry as well as policymakers are now putting tremendous efforts into the generation, storage, and applications of clean energy. This collection focuses on new and efficient energy technologies including innovative ore beneficiation, smelting technologies, recycling and waste heat recovery, and emerging novel energy solutions. The volume also covers a broad range of mature and new technological aspects of sustainable energy ecosystems, processes that improve energy efficiency, reduce thermal intensity and pollutants, and reduce carbon dioxide and other greenhouse emissions. Topics include, but are not limited to:• Energy efficient technologies for minerals, metals & materials processing • Clean energy technologies, such as biomass, solar, wind, geothermal, nuclear including SMRs, hydrogen, etc. • Renewable energy resources to reduce the consumption of traditional fossil fuels • Emerging technologies for renewable energy harvesting, conversion, and storage • New concepts or devices for energy generation, conversion, and distribution • Waste heat recovery and other industrial energy efficient technologies • Energy education and energy regulation • Scale-up, stability, and life-cycle analysis of energy technologies and improvement of existing energy-intensive processes • Theory and simulation in energy harvesting, conversion, and storage • Design, operation, and optimization of processes for energy generation (e.g., carbon capture) and conversion of energy carriers • Energy efficiency improvement in process engineering (e.g., for biomass conversion and improved combustion) and electrical engineering (e.g., for power conversion and developing smart grids) • Thermo-electric/electrolysis/photo-electrolysis/fundamentals of PV • Emission control, CO2 capture, and conversion • Carbon sequestration techniques • CO2 and other greenhouse gas reduction metallurgy in ferrous (iron & steel making and forming), non-ferrous and reactive metals including critical rare-earth metals • Sustainability and life cycle assessment of energy systems • Thermodynamics and modelling for sustainable metallurgical processes • 'Smart cool materials' for urban heat island mitigation (such as cool roof infrared reflecting material, and low-temperature heat absorbers for use in air conditioner condensers - like 'endothermic materials') • Methodologies for reducing the cost of energy materials production • Circular economy and developing resource efficiency model for cutting down the transport from remote places • Materials extraction and processing steps for enhancing energy efficiencies in batteries, supercapacitors, and energy efficient cells • Foundational industry (metals-alloys, chemicals, refractories, cement) and energy economy and role of mineral extraction
Energy Technology 2024: Carbon Dioxide Management and Other Technologies (The Minerals, Metals & Materials Series)
by Chukwunwike Iloeje Shafiq Alam Donna Post Guillen Fiseha Tesfaye Lei Zhang Susanna A. C. Hockaday Neale R. Neelameggham Hong Peng Nawshad Haque Onuralp Yücel Alafara Abdullahi BabaThis collection is focused on industrial energy sustainability and CO2 management, including processes that improve energy efficiency and reduce or eliminate industrial GHG emissions. Topics address technology areas such as clean energy technologies, innovative beneficiation, smelting technologies, process intensification, as well as CO2 capture and conversion for industrial applications. Areas of interest include, but are not limited to: · Decarbonizing Materials Processing · Use of low carbon fuels, feedstock, and renewable energy resources for materials processing. · Emerging processes and techniques for industrial CO2 capture, conversion/upgrade · CO2 and other GHG reduction metallurgy in ferrous, non-ferrous and reactive metals processing, including rare-earth metals. · Energy Efficiency & Industrial Electrification · Electrification of industrial process heat and electrified production of energy carriers (e.g., hydrogen, ammonia) · Energy efficiency improvements for materials processing and smart manufacturing for optimized process control · System integration and thermal integration of process heat, waste heat recovery, and other technologies for industrial energy efficiency · Sustainability Analysis · Techno-economic life-cycle, resource efficiency and circular economy modeling of energy-intensive processes and associated material supply chains · The role of energy education and regulation in energy and materials sustainability