We can no longer view building components as artifacts (a brick or a boiler) or as autonomous systems (air conditioning or prefabrication). Rather these components and systems are part of much larger systems of which architects are one agent. This book will help architects more broadly envision these networks including:

• canonical texts as well as contemporary thinking from well known theorists and practitioners, each contribution frames a specific range of technology in relation to society such as building process, products, economies and ecologies
• clearly structured, the book is divided into three parts; each accompanied by a comprehensive introduction by the editors
• an annotated bibliography provides a glossary of further reading
• illustrated throughout with over 100 illustrations.

The book calls for integration, a convergence and confluence of social and technical factors, discovering the capability and culpability of such; for architects to finally realize that the term building systems is best grasped as a verb, not a set of nouns.

This reader presents students, faculty and practicing architects with an expanded view of technology in architecture that transcends naive determinisms and technocratic applications; forming a more pithy intellectual context for the complex and contingent roles of technology in twenty-first century architecture.

We can no longer view building components as artifacts (a brick or a boiler) or as autonomous systems (air conditioning or prefabrication). Rather these components and systems are part of much larger systems of which architects are one agent. This book will help architects more broadly envision these networks including:

• canonical texts as well as contemporary thinking from well known theorists and practitioners, each contribution frames a specific range of technology in relation to society such as building process, products, economies and ecologies
• clearly structured, the book is divided into three parts; each accompanied by a comprehensive introduction by the editors
• an annotated bibliography provides a glossary of further reading
• illustrated throughout with over 100 illustrations.

The book calls for integration, a convergence and confluence of social and technical factors, discovering the capability and culpability of such; for architects to finally realize that the term building systems is best grasped as a verb, not a set of nouns.

This reader presents students, faculty and practicing architects with an expanded view of technology in architecture that transcends naive determinisms and technocratic applications; forming a more pithy intellectual context for the complex and contingent roles of technology in twenty-first century architecture.

The laws of thermodynamics-and their implications for architecture-have not been fully integrated into architectural design. Architecture and building science too often remain constrained by linear concepts and methodologies regarding energy that occlude significant quantities and qualities of energy. The Hierarchy of Energy in Architecture addresses this situation by providing a clear overview of what energy is and what architects can do with it. Building on the emergy method pioneered by systems ecologist Howard T. Odum, the authors situate the energy practices of architecture within the hierarchies of energy and the thermodynamics of the large, non-equilibrium, non-linear energy systems that drive buildings, cities, the planet and universe. Part of the PocketArchitecture series, the book is divided into a fundamentals section, which introduces key topics and the emergy methodology, and an applications section, which features case studies applying emergy to various architectural systems. The book provides a concise but rigorous exposure to the system boundaries of the energy systems related to buildings and as such will appeal to professional architects and architecture students.

The laws of thermodynamics-and their implications for architecture-have not been fully integrated into architectural design. Architecture and building science too often remain constrained by linear concepts and methodologies regarding energy that occlude significant quantities and qualities of energy. The Hierarchy of Energy in Architecture addresses this situation by providing a clear overview of what energy is and what architects can do with it. Building on the emergy method pioneered by systems ecologist Howard T. Odum, the authors situate the energy practices of architecture within the hierarchies of energy and the thermodynamics of the large, non-equilibrium, non-linear energy systems that drive buildings, cities, the planet and universe. Part of the PocketArchitecture series, the book is divided into a fundamentals section, which introduces key topics and the emergy methodology, and an applications section, which features case studies applying emergy to various architectural systems. The book provides a concise but rigorous exposure to the system boundaries of the energy systems related to buildings and as such will appeal to professional architects and architecture students.

Convergence is based on the thermodynamic premise that architecture should maximize its ecological and architectural power. No matter how paradoxical it might initially seem, architects should maximize energy intake, maximize energy use, and maximize energy feedback and reinforcement. This presumes that the necessary excess of architecture is in fact an architect's greatest asset when it comes to an agenda for energy, not a liability. But how do we start to understand the full range of eco-thermodynamic principles which need to be engaged with in order to achieve this? Kiel Moe explicates three factors: materials, energy systems and amortization. When these three factors converge through design, the resulting buildings begin to perform in complex, if not subtle, ways. By drawing on a range of architectural, thermodynamic, and ecological sources as well as illustrated and well-designed case studies, the author shows what architecture stands to gain by simultaneously maximizing the architectural and ecological power of buildings. .

Convergence is based on the thermodynamic premise that architecture should maximize its ecological and architectural power. No matter how paradoxical it might initially seem, architects should maximize energy intake, maximize energy use, and maximize energy feedback and reinforcement. This presumes that the necessary excess of architecture is in fact an architect's greatest asset when it comes to an agenda for energy, not a liability. But how do we start to understand the full range of eco-thermodynamic principles which need to be engaged with in order to achieve this? Kiel Moe explicates three factors: materials, energy systems and amortization. When these three factors converge through design, the resulting buildings begin to perform in complex, if not subtle, ways. By drawing on a range of architectural, thermodynamic, and ecological sources as well as illustrated and well-designed case studies, the author shows what architecture stands to gain by simultaneously maximizing the architectural and ecological power of buildings. .

What is the best way to consider energy in buildings? For over a century, the building industry has largely focused on ideas of insulation and isolation for its energetic practices. A growing movement of designers claim that other concepts and practices are required for the non-isolated energy systems of architecture. This book describes the history, theory and facts of the mainstream isolation technologies and the emerging alternative design approaches. It is a book on the scientific, material, and design history of building isolation; but more importantly, it is a book on isolated and non-isolated perspectives on energy in architecture. Written by a registered practicing architect with detailed technical knowledge, who is at the same time a researcher and experienced teacher, the aim is to understand the different scientific, architectural and cultural approaches to energy and to promote a non-isolated perspective: a thermodynamically accurate, ecologically powerful, culturally relevant, and architecturally ambitious perspective on energy in architecture.