Commercial energy storage has moved from the margins to the mainstream as it fosters flexibility in our smarter, increasingly integrated energy systems. Natural gas has been identified by many as the fuel to take us to the no-carbon horizon; where a hydrogen economy waits on development. These two actors are already connected in precursor applications as transitional solutions for hydrogen handling and transportation are sought ahead of a fully established hydrogen infrastructure. This monograph explores some of leading advances in methane and hydrogen storage as well as the interesting link between these two important elements in our evolving energy system mosaic. Topics covered include: hydrogen absorption for storage; power-to-gas for energy system integration and storage; methanation for power-to-gas applications; production of hydrogen from methane decarbonisation into power to gas scenarios; power-to-gas in an ancillary service market; methane in MOFs: where, why and how; thermal management as a key in storing adsorbed natural gas; and gas hydrate potential and development for methane storage.

Residential buildings consume about a quarter of all energy (including electrical and thermal) in industrialized countries and emit around 20% of the carbon emissions there. Older and outdated heating and cooling technology causes high energy demand and, depending on building type, secondary causes can include ventilation and lighting. Technology is available to mitigate high energy consumption, and to enable the use of renewable or environmentally friendly energy, partly generated locally. This book, written by international experts from academia as well as industry, compiles and describes several key technologies available to reduce a residential building's energy consumption. Key themes include local energy generation, such as the use of sunlight to reduce heating needs, and photovoltaics for electricity. Case studies are included in most chapters to provide real-world context for the technologies described.

This book reflects the current state of knowledge on sustainability in a wide range of fields, from engineering to agriculture, to education. Though primarily intended to offer an update for experts and researchers in the field, it can also be used as a valuable educational tool for relevant undergraduate and graduate courses. Key aspects covered include the better and more responsible engineering and management of energy conversion processes, the development of renewable energy technologies, and improvements in conventional energy utilization and food production. In addition, the book addresses green buildings, the green economy, waste and recycling, water, ecopolitics and social sustainability.

This book reveals key challenges to ensuring the secure and sustainable production and use of energy resources, and provides corresponding solutions. It discusses the latest advances in renewable energy generation, and includes studies on climate change and social sustainability. In turn, the book goes beyond theory and describes practical challenges and solutions associated with energy and sustainability. In particular, it addresses: * renewable energy conversion technologies; * transmission, storage and consumption; * green buildings and the green economy; and * waste and recycling. The book presents the current state of knowledge on renewable energy and sustainability, supported by detailed examples and case studies, making it not only a cutting-edge source of information for experts and researchers in the field, but also an educational tool for related undergraduate and graduate courses.

Human beings require nourishment for the body, mind, and soul. To nourish tomorrow demands sustainable, clean and healthy food, water, air, healthcare, energy, living quarters, communities, and governance for everyone. This volume brings together twenty-four experts — comprising engineers, scientists, economists, architects, academics, and public servants from around the world — to share their views on how we could sustainably nourish people and the planet.In this book, the theme of building environments in which life — human and non-human — can co-exist, grow, and thrive in, is explored from multiple aspects. From agriculture and food security to drinking water, energy generation, energy storage, waste management and treatment, to building for and encouraging biodiversity in marinas, to establishing resilient communities that can recover quickly from both manmade and natural disasters.This book is a valuable resource for readers in the fields of biological science, agriculture, and sustainability. It is also a thought-provoking volume for those who simply want to know more about the complex issue of nourishing the world.

The intermittency of renewable energy sources is making increased deployment of storage technology necessary. Technologies are needed with high round-trip efficiency and at low cost to allow renewables to undercut fossil fuels. The cost of lithium batteries has fallen, but producing them comes with a substantial carbon footprint, as well as a cost to the local environment. Compressed air energy storage (CAES) uses excess electricity, particularly from wind farms, to compress air. Re-expansion of the air then drives machinery to recoup the electric power. Prototypes have capacities of several hundred MW. Challenges lie in conserving the thermal energy associated with compressing air and leakage of that heat, materials, power electronics, connection with the power generator, and grid integration. This comprehensive book provides a systematic overview of the current state of CAES technology. After an introduction to motivation and principles, the key components are covered, and then the principal types of systems in the order of technical maturity: diabatic, adiabatic, and isothermal. Experts from industry write about their experiences with existing major systems and prototypes. Economic aspects, power electronics and machinery, as well as special systems for offshore applications, are dealt with. Researchers in academia and industry alike, in particular at energy storage technology manufacturers and utilities, as well as advanced students and energy experts in think tanks will find this work valuable reading.

Wind power is a pillar of low emission energy systems. Designing more efficient wind turbines and farms, and increasing reliability and flexibility, is an area of intense research and development. In order to overcome the intermittent character of wind power, both the individual turbines and the wind farm as a whole must be considered. Many recent advances have been achieved in multiple aspects of utility-scale wind power. This structured research review conveys recent progress, with chapters written by an international team of experts. Organized into five parts, the book covers the aerodynamics of turbines and farms including layout; control techniques; environmental concerns including noise and bird and bat collisions; the intermittency issue including forecasting, storage and hybrid wind-PV plants; and offshore wind farms. From the general principles of aerodynamics to detailed and systematic coverage of the latest developments, Utility-scale Wind Turbines and Wind Farms provides a convenient and up-to-date source of information for academic researchers and R&D professionals working in this field.

This book brings together the state-of-the-art in energy and resources research. It covers wind, solar, hydro and geothermal energy, as well as more conventional power generation technologies, such as internal combustion engines. Related areas of research such as the environmental sciences, carbon dioxide emissions, and energy storage are also addressed.

This book gathers the proceedings of the Energy and Sustainability 2018 Symposium (EAS 2018) held in Windsor, Canada in June 2018. It brings together the state-of-the-art on specific aspects of the current energy status, and covers a wide range of energy and engineering systems, from internal combustion engines to electric vehicles, from the atmosphere, solar and wind, to underground geothermal and underwater turbines and energy storage. The book demonstrates how conventional internal combustion engines have advanced dramatically in terms of both performance and emissions over the past century. It also studies how life-supporting elements, such as water and greenhouses, must be prioritized and protected to ensure a sustainable future. The book offers a valuable source of information for future leaders, engineers, environmentalists, social forerunners, and decision-makers alike. It also provides a reference guide for both undergraduate and graduate students in engineering, the natural and social sciences, business and economics.

C. S. Lewis rightly instructed, "The task of the modern educator is not to cut down jungles, but to irrigate deserts." This book aims to achieve this task by pushing the frontiers of scholarship for securing a sustainable future through green energy and infrastructure. This encompasses the notion that what we create is in harmony and integration with both the spatial and temporal domains. Through numerous practical examples and illustrations, this book examines a comprehensive review of the latest science on indoor environmental health, energy requirements for buildings, and the "greening" of infrastructure. Also, it provides a discussion on the underlying properties of biomass and its influence on furthering energy conversion technologies. Energy storage is essential for driving the integration of renewable energy, and different storage approaches are discussed in terms of power balancing, grid stability, and reliability. Features: Focuses on the importance of coupling green energy with green infrastructure Provides an unbiased update of the state-of-the-art of sustainability science Discusses utilizing sustainable building materials for simultaneous improvement in energy, economic, and environmental bottom lines for industry Illuminates practical steps that need to be undertaken to achieve a greener infrastructure Green Energy and Infrastructure: Securing a Sustainable Future is appropriate for researchers, students, and decision-makers seeking the latest, practical information on environmental sustainability.

This book includes the proceedings of the Mitigating Climate Change 2021 Symposium and Industry Summit (MCC2021), which brings together research from experts in academia, industry, and policy arenas to uncover the challenges, sharpen existing solutions, and formulate cutting-edge means to mitigate climate change. It highlights the need to create sustainable measures at all fronts including adaptation, policy, finance, renewable energy, solar, wind, thermoelectric, green transportation, and sustainable healthcare. This symposium will disseminate the state-of-the-art breakthroughs and promote collaborations to maximize opportunities for innovative solutions.

Sustainable Engineering for Life Tomorrow examines the future of sustainable engineering and architecture. The contributors' analyses of sustainable solutions, such as wind and solar power, offer valuable insights for future policy-making, scholarship, and the management of energy-intensive facilities.

This volume brings together 18 experts with diverse backgrounds and expertise from around the globe to tackle climate change from multiple angles. A comprehensive exposition of the interconnection between ocean, weather, and climate variability is a pre-requisite for understanding the challenge. The solution approach encompasses a better appreciation of the roof, refined solar energy estimation, heightened heat exchange effectiveness, improved understanding of photovoltaic operation in the Arctic, and integration of thermoelectric with photovoltaic. Adaptation is an essential and immediate remedy that every individual must take part in, understanding that men and women respond to the thermal environment differently. Imagine future buildings made from appetizing materials, closing a sustainable design process with self-sufficient communities. Would hydrogen become a crucial part of the mitigation?

Based on state-of-the-art science and technologies, this book disseminates the latest advancements concerning the relationship between renewable energy and climate change and presents the best practices to further utilize renewable energy for mitigation. It examines issues of climate change from different renewable energy fronts by the respective experts from around the world. While high-level and in-depth technological advancements are judiciously presented, it also discusses different types of renewable energy and the associated technologies in consideration of the various perspectives of economy, availability, and societal implications in different regions. Features: Discusses the concept of leapfrogging renewable energy technologies in developing countries for the purpose of minimizing human-induced climate change impacts as rapidly as possible Includes various options from high technology to sustainable agriculture Presents and compares the latest novel and emerging potential technologies Outlines how to advance renewable energy by improving energy storage and optimizing financial incentives and management Renewable Energy for Mitigating Climate Change enlightens readers from a renewable energy perspective on how to best tackle the challenges of climate change. This is a must-read for senior undergraduate and graduate students in environmental studies, decision- and policymakers, educators, and every environmental steward. The interests of all stakeholders, especially future generations, form the thread connecting all the chapters together into a powerful tool to mitigate global climate change.

Sustainable Engineering for Life Tomorrow examines the future of sustainable engineering and architecture. The contributors' analyses of sustainable solutions, such as wind and solar power, offer valuable insights fur future policy-making, scholarship, and the management of energy-intensive facilities.

This book includes the proceedings of the Sustaining Tomorrow 2020 symposium and summit which bring together research from experts in academia, industry, and policy arenas to uncover the challenges and to forge solutions to sustain tomorrow. To sustain tomorrow, we need to continuously make headway in Agriculture, Engineering, Energy, Environment, Economics, Water, among other necessities. This book disseminates the most recent advances in these fields and promotes collaborations to maximize opportunities for innovative solutions. Though primarily intended to offer an update for experts and researchers in the field, this book is equally useful as a valuable educational tool for relevant undergraduate and graduate courses. Key aspects covered include the better and more responsible engineering and management of energy conversion and conservation processes, the furthering of renewable energy technologies, improvements in water-agriculture nexus and energy-environment-economics relationship, and endorsing education, implementation, and evaluation of all-embracing sustainability.

The most productive way to engage society as a whole with issues of sustainability is to involve them in the development and execution of the solutions. Pragmatic Engineering and Lifestyle draws together international experts from engineering and architecture to disclose the latest insights into forging viable means to sustain tomorrow’s needs. Focusing on breaking through the remaining barriers and fully realizing promising remedies by explicitly examining the social aspect of engineering and urban design, the authors present state of the art research on, among other topics, simple and responsible engineering and living, ecological and socially friendly buildings and infrastructures, socially resilient farming, and agroecology. Pragmatic Engineering and Lifestyle is an indispensable collection for tomorrow's engineers, architects, and policy makers.

This book brings together the state-of-the-art in energy and resources research. It covers wind, solar, hydro and geothermal energy, as well as more conventional power generation technologies, such as internal combustion engines. Related areas of research such as the environmental sciences, carbon dioxide emissions, and energy storage are also addressed.

This book reflects the current state of knowledge on sustainability in a wide range of fields, from engineering to agriculture, to education. Though primarily intended to offer an update for experts and researchers in the field, it can also be used as a valuable educational tool for relevant undergraduate and graduate courses. Key aspects covered include the better and more responsible engineering and management of energy conversion processes, the development of renewable energy technologies, and improvements in conventional energy utilization and food production. In addition, the book addresses green buildings, the green economy, waste and recycling, water, ecopolitics and social sustainability.

Human thermal comfort, namely in the areas of heating, ventilation and air conditioning (collectively known as 'HVAC'), is ubiquitous wherever human habitation may be found. Today, a large portion of the developed world's current energy demands are used to artificially keep the temperatures of our environments comfortable. It is therefore imperative for everyone, decision-makers and engineers alike, involved with the future of energy to be appropriately acquainted with HVAC.Lecture Notes on Engineering Human Thermal Comfort explains the quintessence of engineering human thermal comfort through straight-forward writing designed to help students better comprehend the materials presented. Illustrative figures, anecdotal banter, and ironical analogies interject the necessary technical humdrum to provide timeous stimuli in the midst of arduous technical details.This book is primarily for senior undergraduate engineering students interested in engineering human thermal comfort. It invokes some undergraduate knowledge of thermodynamics, heat transfer, and fluid mechanics as needed, to enable students to appreciate thermal comfort engineering without the need to seek out other textbooks.

Environmental Management of Air, Water, Agriculture, and Energy brings together the most current state of knowledge on four major elements for sustaining life on planet Earth: air, water, food, and energy. It examines how green technology aids in mitigating the global water, energy, and climate change crises, including the use of electrostatic force and green infrastructure. The concepts of underwater vegetation and aquatic cultivation, as well as vertical farms, are presented to spark discussion on emerging water-energy-food nexus lessons, experiences, and opportunities. This book takes a comprehensive global-scale approach to examining potential future environmental scenarios and outcomes. Features: Analyzes the most recent research findings in each of the areas covered Synthesizes the state-of-the-art understanding Recommends ways to strive forward and to shape future research Serves as an educational tool for educators and students Supported by detailed examples and case studies, this book serves not only as an up-to-date source of information for environmental experts and researchers in the field, but also as an educational tool for relevant undergraduate and graduate courses. It is also suitable for industry professionals concerned with preserving planet Earth for generations to come.

This book includes the proceedings of the Sustaining Tomorrow 2020 symposium and summit which bring together research from experts in academia, industry, and policy arenas to uncover the challenges and to forge solutions to sustain tomorrow. To sustain tomorrow, we need to continuously make headway in Agriculture, Engineering, Energy, Environment, Economics, Water, among other necessities. This book disseminates the most recent advances in these fields and promotes collaborations to maximize opportunities for innovative solutions. Though primarily intended to offer an update for experts and researchers in the field, this book is equally useful as a valuable educational tool for relevant undergraduate and graduate courses. Key aspects covered include the better and more responsible engineering and management of energy conversion and conservation processes, the furthering of renewable energy technologies, improvements in water-agriculture nexus and energy-environment-economics relationship, and endorsing education, implementation, and evaluation of all-embracing sustainability.

We cannot continue on a business-as-usual, carbon fuel dependent mode of operation, because the consequences of doing so are catching up with us. So, what must we do to ensure there is a tomorrow? In this book, experts from around the world come together to shed light on what we can do to preserve and expand resources key to the survival of human civilization - from the state-of-the-art of innovative engineering; to the latest status on energy, energy mix, and advancements in renewable energy - including the complementary energy storage using hydrogen; or innovative architecture for more sustainable buildings, including retrofitting of aging tall buildings; innovative ways to improve our air, water and coastline with nearshore biodiversity reclamation; to the subject of sustainable development through the water-energy-food nexus. This volume is recommended for research and graduate courses on energy and sustainability, and policymakers interested in the subjects.

A sustainable community energy system is an approach to supplying a local community - ranging from a few homes or farms to entire cities - with its energy requirements from renewable energy or high-efficiency co-generation energy sources. Such systems are frequently based on wind power, solar power, biomass, either singly or in combination. Community energy projects have been growing in numbers in several key regions. This book provides an overview of existing and emerging community energy technologies. Topics covered include data-driven methods for prediction of small to medium wind turbines performance; optimisation of wind farms for communities; financing for community wind and photovoltaic project development; community-level solar thermal systems; solar water desalination for small communities; community solar photovoltaic projects; assessing wind loads for urban photovoltaic installations; design optimisation of multi-energy hubs for community energy projects; battery based storage for communities; power-to-gas and power-to-power for storage and ancillary services in urban areas; smart multi-energy microgrids; and conservation and demand management in community energy systems. Wind and Solar Based Energy Systems for Communities is essential reading for researchers and engineers working to develop community energy systems and advance the transition to a clean energy future.