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 Older and outdated heating and cooling technology causes high energy demand and, depending on building type, secondary causes can include ventilation and lighting.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.

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.

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.

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.