Materias:

Tabla de Contenidos: “…Augustine, Florida</p> <p>Summary and Conclusions</p> <p>Part III Green Building Design </p> <p>Chapter 7 The Green Building Design Process </p> <p>Conventional versus Green Building Delivery Systems</p> <p>High-Performance Green Building Delivery System</p> <p>Executing the Green Building Project</p> <p>Owner Issues In High-Performance Green Building Projects</p> <p>Setting Priorities And Making Other Key Initial Decisions</p> <p>Selecting The Green Building Team</p> <p>Role Of The Leed Accredited Professional Or Green Globes Professional In The Process</p> <p>Integrated Design Process</p> <p> Role of the Charrette in the Design Process</p> <p>Green Building Documentation Requirements</p> <p>LEED Documentation</p> <p>Green Globes Documentation</p> <p>Case Study: Theaterhaus, Stuttgart, Germany</p> <p>Summary and Conclusions</p> <p>Chapter 8 The Sustainable Site and Landscape </p> <p>Land and Landscape Approaches for Green Buildings</p> <p>Land Use Issues</p> <p>Sustainable Landscapes</p> <p>Green, or living, roofs</p> <p>Vertical landscaping</p> <p>Enhancing ecosystems</p> <p>Enhancing Ecosystems</p> <p>Stormwater Management</p> <p>Low-Impact Development</p> <p>Heat Island Mitigation</p> <p>Light Trespass and Pollution Reduction</p> <p>Assessment of Sustainable Sites: The Sustainable Sites Initiative</p> <p>Case Study: Iowa Utilities Board/Consumer Advocate Office</p> <p>Summary and Conclusions</p> <p>Chapter 9 Low-Energy Building Strategies </p> <p>Building Energy Issues</p> <p>High-Performance Building Energy Design Strategies</p> <p>HVAC Systems</p> <p>Water-Heating Systems</p> <p>Electrical Power System Components</p> <p>Innovative Energy Optimization Strategies</p> <p>Smart Buildings and Energy Management Systems (EMS)</p> <p>Ozone Depleting Chemicals in HVAC Systems</p> <p>Case Study: The Pertamina Energy Tower -- A Primer on Sustainable Skyscraper Design</p> <p>Chapter 10 Built Environment Hydrologic Cycle </p> <p>Global Water Resource Depletion</p> <p>Hydrologic Cycle Terminology</p> <p>Benefits of Water Efficiency</p> <p>High-Performance Building Hydrologic Cycle Strategy</p> <p>Building Plumbing Fixture and Controls</p> <p>Nonportable Water Sources</p> <p>Wastewater Strategies</p> <p>Baseline Water Model Example</p> <p>Use of Low-Flow Fixture Strategy</p> <p>Use of Alternative Water Sources Strategy</p> <p>Case Study: Lott Clean Water Alliance, Olympia, Washington</p> <p>Blackwater Case Study: Blackwater Recycling System, Salesforce Tower, San Francisco</p> <p>Summary and Conclusions</p> <p>Chapter 11 Closing Materials Loops </p> <p>The Challenge of Materials and Product Selection</p> <p>Selecting Building Materials and Products with a Focus on A Closed-Loop Materials System</p> <p>Life Cycle Assessment</p> <p>Materials and Product Certification</p> <p>Key and Emerging Construction Materials and Products</p> <p>Case Study Of Closing The Loop: Ecoworx® Carpet Tiles</p> <p>Design for Deconstruction and Disassembly</p> <p>Case Study: Project XX Office Building, Delft, Netherlands</p> <p>Summary and Conclusions</p> <p>Chapter 12 Built Environment Carbon Footprint </p> <p>Human Impact on the Biogeochemical Carbon Cycle</p> <p>Climate Change and the Carbon Cycle</p> <p>Climate Change Mitigating</p> <p>Defining the Carbon Footprint of The Built Environment</p> <p>Reducing the Carbon Footprint of the Built Environment</p> <p>Focusing on Mitigating Project Climate Change Impact</p> <p>Carbon Neutrality and Its Applicability to Buildings</p> <p>Focusing on Mitigating Project Climate Change Impacts</p> <p>Carbon Neutrality Case Study: The Hong Kong Zero Carbon Building</p> <p>Carbon Neutrality Case Study: Glaxosmithkline Carbon Neutral Laboratory for Sustainable Chemistry (Nottingham, Uk)</p> <p>Carbon Footprint Case Study: Rinker Hall, University of Florida </p> <p>Chapter 13 Indoor Environmental Quality </p> <p>Indoor Environmental Quality: The Issues</p> <p>Integrated IEQ Design</p> <p>Addressing the Main Components of Integrated IEQ Design</p> <p>HVAC Systems and IEQ</p> <p>Emissions from Building Materials</p> <p>The WELL and FITWEL Building Standards</p> <p>Summary and Conclusions</p> <p>Part IV Green Building Implementation </p> <p>Chapter 14 Construction Operations and Commissioning</p> <p>Site Protection Planning</p> <p>Managing Indoor Air Quality during Construction</p> <p>Construction Materials Management</p> <p>Construction and Demolition Waste Management</p> <p>Commissioning</p> <p>Summary and Conclusions</p> <p>Chapter 15 Green Building Economics </p> <p>General Approach</p> <p>The Business Case for High-Performance Green Buildings</p> <p>Economics of Green Building</p> <p>Quantifying Green Building Benefits</p> <p>Managing First Costs</p> <p>Tunneling through the Cost Barrier</p> <p>Summary and Conclusions</p> <p>Chapter 16 Resilience Resilience in the Context of Sustainable Construction</p> <p>Resilience Concepts and Scope</p> <p>Codes and Standards for Built Environment Resilience</p> <p>Designing Resilient Buildings</p> <p>Green Building Assessment and Resilience…”