1. Sustainable Architecture- BACKGROUND
1.1 What is Sustainable Development?
“Sustainable development is development which meets the needs of the present without compromising the ability of future generation to meet their own needs.” — World Commission on Environment and Development, Our Common Future, pp. 4, Oxford University Press, New York, 1987. This definition has been formulated by the World Commission on Environment and Development (WCED), led by the norwegian prime minister Gro Harlem Brundtland, in 1987.
The word development in this definition implicates two important aspects of the concept: It is omnidisciplinary, it cannot be limited to a number of disciplines or areas, but it is applicable to the whole world and everyone and everything on it, now and in the future. Secondly, there is no set aim, but the continuation of development is the aim of the development. The definition is based on two concepts:
- the concept of needs, comprising of the conditions for maintaining an acceptable life standard for all people, and
- the concept of limits of the capacity of the environment to fulfill the needs of the present and the future, determined by the state of technology and social organisation.
The needs consist firstly of basic needs such as food, clothing, housing and employment. Secondly, every individual, in every part of the world should have the opportunity to try and raise his or her life standard above this absolute minimum. The limits consist of natural limitations like finite resources, but also of declining productivity caused by overexploitation of resources, declining quality of water and shrinking of biodiversity. For our common future, it would therefore be best if needs are best fulfilled while limits are not increased, but preferably decreased. This would lead to the quite simple conclusion that all political, technical and social developments can easily be evaluated in the light of sustainable development by these two arguments. Any development should help fulfill needs and should not increase limitations.
1.2 Various Viewpoints
Many other definitions of sustainable development have also been offered, some general and some more precise. The followings illustrate the variety of foci evident in discussions of sustainable development.
- “. . . requires meeting the basic needs of all people and extending opportunities for economic and social advancement. Finally, the term also implies the capacity of development projects to endure organizationally and financially. A development initiative is considered sustainable if, in addition to protecting the environment and creating opportunity, it is able to carry out activities and generate its own financial resources after donor contributions have run out.” Bread for the World, Background Paper No. 129, Washington, DC, March 1993.
- “[improves] . . . the quality of human life while living within the carrying capacity of supporting ecosystems.” International Union for the Conservation of Nature and Natural Resources (IUCN), World Conservation Union, United Nation Environment Programme (UNEP), and World Wide Fund for Nature (WWF), Caring for the Earth, pp. 10, IUCN/UNEP/WWF, Gland, Switzerland, 1991.
- “[uses] . . . natural renewable resources in a manner that does not eliminate or degrade them or otherwise dimish their renewable usefulness for future generations while maintaining effectively constant or non-declining stocks of natural resources such as soil, groundwater, and biomass.” World Resources Institute, Dimensions of sustainable development, World Resources 1992-93: A Guide to the Global Environment, pp. 2, Oxford University Press, New York, 1992.
- “[maximizes] . . . the net benefits of economic development, subject to maintaining the services and quality of natural resources.” R. Goodland and G. Ledec, Neoclassical economics and principles of sustainable development, Ecological Modeling 38 (1987): 36.
- “[is based on the premise that] . . . current decisions should not impair the prospects for maintaining or improving future living standards . . . This implies that our economic systems should be managed so that we live off the dividend of our resources, maintaining and improving the asset base.” R. Repetto, World Enough and Time, pp. 15-16, Yale University Press, New Haven, CT, 1986.
- ” . . . is taken to mean a positive rate of change in the quality of life of people, based on a system that permits this positive rate of change to be maintained indefinitely.” L. M. Eisgruber, Sustainable development, ethics, and the Endangered Species Act, Choices, Third Quarter 1993, pp. 4-8.
- ” . . . is development without growth — a physically steady-state economy that may continue to develop greater capacity to satisfy human wants by increasing the efficiency of resource use, but not by increasing resource throughput.” H. E. Daly, Steady state economics: concepts, questions, and politics, Ecological Economics 6 (1992): 333-338.
- ” . . . is the search and the carrying out of rational strategies that allow society to manage, in equilibrium and perpetuity, its interaction with the natural system (biotic/abiotic) such that society, as a whole, benefits and the natural system keeps a level that permits its recuperation.” E. Gutierrez-Espeleta, Indicadores de sostenibilidad: instrumentos para la evaluacion de las politicas nacionales”, unpublished paper presented at 50th Anniversity Conference of the Economic Sciences Faculty sponsored by the University of Costa Rica, San Jose, Costa Rica, Nov. 19, 1993.
1.3 Three Dimensions
Environmental Sustainability Architecture
The idea of environmental sustainability is to leave the Earth in as good or better shape for future generations than we found it for ourselves. By a definition, human activity is only environmentally sustainable when it can be performed or maintained indefinitely without depleting natural resources or degrading the natural environment.
- Resource consumption would be minimal
- Materials consumed would be made ENTIRELY of 100% post-consumer recycled materials or from renewable resources (which were harvested without harm to the environment and without depletion of the resource base)
- Recycling of waste streams would be 100%
- Energy would be conserved and energy supplies would be ENTIRELY renewable and non-polluting (solar thermal and electric, wind power, biomass, etc.)
1.4 Further Reading
- Definition of Sustainability [AGS]
- Definitions of Sustainability [SDIC]
- The Economics of Sustainability [US-EPA]
- Global Sustainability Concepts [University of California Irvine]
- Interactive Learning About Sustainable Development [IISD]
- Sustainable Development: Education for Engineers & Others
- Sustainable Development Information [Five E’s]
- “Sustainability” by Robert Gilman, from the 1992 UIA/AIA “Call for Sustainable Community Solutions” [Context Institute]
- Sustainability and Sustainable Development [University of Reading, UK]
- Thoughts on Sustainability [eDesign]
- What is sustainable development? [SustainAbility.com]
- What is “Sustainability”? [Florida Sustainable Communities Center]
- What is Sustainability? [US EPA]
- What Is Sustainability? [by Susan Murcott of MIT]
- Conceptual Frameworks
“Architecture presents a unique challenge in the field of sustainability. Construction projects typically consume large amounts of materials, produce tons of waste, and often involve weighing the preservation of buildings that have historical significance against the desire for the development of newer, more modern designs.” — The Earth Pledge (www.earthpledge.org)
2.1 Sustainable Construction
Sustainable construction is defined as “the creation and responsible management of a healthy built environment based on resource efficient and ecological principles“. Sustainably designed buildings aim to lessen their impact on our environment through energy and resource efficiency. It includes the following principles:
- minimising non-renewable resource consumption
- enhancing the natural environment
- eliminating or minimising the use of toxins
Accordning to an OECD Project, “Sustainable building” can be defined as those buildings that have minimum adverse impacts on the built and natural environment, in terms of the buildings themselves, their immediate surroundings and the broader regional and global setting. “Sustainable building” may be defined as building practices, which strive for integral quality (including economic, social and environmental performance) in a very broad way. Thus, the rational use of natural resources and appropriate management of the building stock will contribute to saving scarce resources, reducing energy consumption (energy conservation), and improving environmental quality.
Sustainable building involves considering the entire life cycle of buildings, taking environmental quality, functional quality and future values into account. In the past, attention has been primarily focused on the size of the building stock in many countries. Quality issues have hardly played a significant role. However, in strict quantity terms, the building and housing market is now saturated in most countries, and the demand for quality is growing in importance. Accordingly, policies that contribute to the sustainability of building practices should be implemented, with recognition of the importance of existing market conditions. Both the environmental initiatives of the construction sector and the demands of users are key factors in the market. Governments will be able to give a considerable impulse to sustainable buildings by encouraging these developments. The OECD project has identified five objectives for sustainable buildings:
- Resource Efficiency
- Energy Efficiency (including Greenhouse Gas Emissions Reduction)
- Pollution Prevention (including Indoor Air Quality and Noise Abatement)
- Harmonisation with Environment (including Environmental Assessment)
- Integrated and Systemic Approaches (including Environmental Management System)
Green Code for Architecture
[From: Greening Government: Towards More Sustainable Construction: Green Guide for Managers on the Government Estate, Department for Environment, Food & Rural Affairs, UK]
Based on the objectives of the Building Research Establishment’s Environmental Assessment Method (BREEAM) The principles are:
- demolish and rebuild only when it is not economical or practicable to reuse, adapt or extend an existing structure;
- reduce the need for transport during demolition, refurbishment and construction and tightly control all processes to reduce noise, dust, vibration, pollution and waste;
- make the most of the site, eg. by studying its history and purpose, local micro-climates and the prevailing winds and weather patterns, solar orientation, provision of public transport and the form of surrounding buildings;
- design the building to minimise the cost of ownership and its impact on the environment over its life span by making it easily maintainable and by incorporating techniques and technologies for conserving energy and water and reducing emissions to land, water and air;
- wherever feasible, use the construction techniques which are indigenous to the area, learning from local traditions in materials and design;
- put the function of the building and the comfort of its occupants well before any statement it is intended to make about the owner or its designer. That is, make it secure, flexible and adaptable (to meet future requirements) and able to facilitate and promote communications between staff;
- build to the appropriate quality and to last. Longevity depends much on form, finishes and the method of assembly employed as on the material used.
- avoid using materials from non renewable sources or which cannot be reused or recycled, especially in structures which have a short life;
2.2 Environmental Architecture
Five principles of an environmental architecture (Thomas A. Fisher, AIA, November, 1992):
- Healthful Interior Environment. All possible measures are to be taken to ensure that materials and building systems do not emit toxic substances and gasses into the interior atmosphere. Additional measures are to be taken to clean and revitalize interior air with filtration and plantings.
- Energy Efficiency. All possible measures are to be taken to ensure that the building’s use of energy is minimal. Cooling, heating and lighting systems are to use methods and products that conserve or eliminate energy use.
- Ecologically Benign Materials. All possible measures are to be taken to use building materials and products that minimize destruction of the global environment. Wood is to be selected based on non destructive forestry practices. Other materials and products are to be considered based on the toxic waste out put of production.
- Environmental Form. All possible measures are to be taken to relate the form and plan of the design to the site, the region and the climate. Measures are to be taken to “heal” and augment the ecology of the site. Accomodations are to be made for recycling and energy efficiency. Measures are to be taken to relate the form of building to a harmonious relationship between the inhabitants and nature.
- Good Design. All possible measures are to be taken to achieve an efficient, long lasting and elegant relationship of use areas, circulation, building form, mechanical systems and construction technology. Symbolic relationships with appropriate history, the Earth and spiritual principles are to be searched for and expressed. Finished buildings shall be well built, easy to use and beautiful.
Architect William McDonough defined the breadth of what Green Building is:
- The Hannover Principles
- Harvest all their own water and energy needs on site.
- Be adapted specifically to site and climate and evolve as conditions change.
- Operate pollution-free and generate no wastes that aren’t useful for some other process in the building or immediate environment.
- Promote the health and well-being of all inhabitants, as a healthy ecosystem does.
- Be comprise of integrated systems that maximize efficiency and comfort.
- Improve the health and diversity of the local ecosystem rather than degrade it.
- Be beautiful and inspire us to dream.
— Jason F. McLennan, BNIM Architects
2.3 Ecological Building
|1.||the science of the relationship and interaction of living organisms with their inanimate (e.g. climate, soil) and their animate environment, as well as the study of resource and energy management in the biosphere and its sub-categories.|
|2.||the study of the detrimental effects of modern civilization on the environment, with a view toward prevention or reversal through conservation.|
|1.||careful, thrifty management of resources, such as money, materials, or labor.|
|2.||an orderly, functional arrangement of parts; on organized system.|
|3.||efficient, sparing, or conservative use.|
A movement in contemporary architecture. This movement aims to create environmentally friendly, energy-efficient buildings and developments by effectively managing natural resources. This entails passively and actively harnessing solar energy and using materials which, in their manufacture, application, and disposal, do the least possible damage to the so-called ‘free resources’ water, ground, and air.
2.4 Green Building
“It’s not easy being green.” — Kermit the Frog, 1972.
A green approach to the built environment involves a holistic approach to the design of buildings. All the resources that go into a building, be they materials, fuels or the contribution of the users need to be considered if a sustainable architecture is to be produced. Producing green buildings involves resolving many conflicting issues and requirements. Each design decision has environmental implications. Measures for green buildings can be divided into four areas:
- reducing energy in use
- minimising external pollution and environmental damage
- reducing embodied energy and resource depletion
- minimising internal pollution and damage to health
What Makes a Building Green?
A “green” building places a high priority on health, environmental and resource conservation performance over its life-cycle. These new priorities expand and complement the classical building design concerns: economy, utility, durability, and delight. Green design emphasizes a number of new environmental, resource and occupant health concerns:
- Reduce human exposure to noxious materials.
- Conserve non-renewable energy and scarce materials.
- Minimize life-cycle ecological impact of energy and materials used.
- Use renewable energy and materials that are sustainably harvested.
- Protect and restore local air, water, soils, flora and fauna.
- Support pedestrians, bicycles, mass transit and other alternatives to fossil-fueled vehicles.
Most green buildings are high-quality buildings; they last longer, cost less to operate and maintain, and provide greater occupant satisfaction than standard developments. Sophisticated buyers and lessors prefer them, and are often willing to pay a premium for their advantages. What surprises many people unfamiliar with this design movement is that good green buildings often cost little or no more to build than conventional designs. Commitment to better performance, close teamwork throughout the design process, openness to new approaches, and information on how these are best applied are more important than a large construction budget.
Sustainable design is the thoughtful integration of architecture with electrical, mechanical, and structural engineering. In addition to concern for the traditional
aesthetics of massing, proportion, scale, texture, shadow, and light, the facility design team needs to be concerned with long term costs: environmental, economic, and human.
The Rocky Mountain Institute outlines five elements for sustainable design:
- Planning and design should be thorough. Sustainable design is “front loaded” compared with traditional design. Early decisions have the greatest impact on energy efficiency, passive solar design, daylighting, and natural cooling.
- Sustainable design is more of a philosophy of building than a prescriptive building style. Sustainable buildings don’t have any particular look or style.
- Sustainable buildings don’t have to cost more, nor are they more complicated than traditional construction.
- Integrated design, that is design where each component is considered part of a greater whole, is critical to successful sustainable design.
- Minimizing energy consumption and promoting human health should be the organizing principles of sustainable design. The other elements of design can be organized: energy saving architectural features, energy conserving building envelope, and energy-efficient and health-promoting mechanical, electrical, and plumbing systems.
Principles of Sustainable Design
- Understanding Place – Sustainable design begins with an intimate understanding of place. If we are sensitive to the nuances of place, we can inhabit without destroying it. Understanding place helps determine design practices such as solar orientation of a building on the site, preservation of the natural environment, and access to public transportation.
- Connecting with Nature – Whether the design site is a building in the inner city or in a more natural setting, connecting with nature brings the designed environment back to life. Effective design helps inform us of our place within nature.
- Understanding Natural Processes – In nature there is not waste. The byproduct of one organism becomes the food for another. In other words, natural systems are made of closed loops. By working with living processes, we respect the needs of all species. Engaging processes that regenerate rather than deplete, we become more alive. Making natural cycles and processes visible brings the designed environment back to life.
- Understanding Environmental Impact – Sustainable design attempts to have an understanding of the environmental impact of the design by evaluating the site, the embodied energy and toxicity of the materials, and the energy efficiency of design,materials and construction techniques. Negative environmental impact can be mitigated through use of sustainably harvested building materials and finishes, materials with low toxicity in manufacturing and installation, and recycling building materials while on the job site.
- Embracing Co-creative Design Processes – Sustainable designers are finding it is important to listen to every voice. Collaboration with systems consultants, engineers and other experts happens early in the design process, instead of an afterthought. Designers are also listening to the voices of local communities. Design charettes for the end user (neighbourhood residents or office employers) are becoming a standard practice.
- Understanding People – Sustainable design must take into consideration the wide range of cultures, races, religions and habits of the people who are going to be using and inhabiting the built environment. This requires sensitivity and empathy on the needs of the people and the community.
“Sustainable architecture involves a combination of values: aesthetic, environmental, social, political, and moral. It’s about using one’s imagination and technical knowledge to engage in a central aspect of the practice — designing and building in harmony with our environment. The smart architect thinks rationally about a combination of issues including sustainability, durability, longevity, appropriate materials, and sense of place. The challenge is finding the balance between environmental considerations and econmic constraints. Consideration must be given to the needs of our communities and the ecosystem that supports them.” — Sanuel Mockbee, Auburn University
2.5 Further Reading
- Agenda 21 on Sustainable Construction [CIB]
- Defining Sustainable Architecture (by Jack A. Kremers), Architronic v4n3.02
- Green Building Basics
- Green Building Primer [B.E.S.T.]
- Green Buildings – The Growing Emphasis on Building Performance and Occupant Health
- Patterns of Sustainable Design [www.homeasta.org]
- Rural Sustainability (slide show)
- Sustainable Architecture Online Course [Boston Architectural Center]
- Sustainable Architecture: A Definition (by John Norton), Habitat Debate Vol. 5 No. 2
- Sustainable Architecture White Papers [Table of Content][720.47 S96]
- Sustainable building in the Netherlands (by P.W. Heijimen)
- Sustainable Construction [CBPP]
- Sustainable Design [AIA COTE]
- Urban Sustainability (slide show)
- What is Sustainable Design? – Basic Sustainable Design Principles [www.homeasta.org]
- Energy Efficiency
- Material Efficiency
- Water Efficiency
- Regional Design
- What It Means to Be Green [Architectural Record]
Sustainable Urban Design
- What is Sustainable Urban Development? [University of Salford]
- Sustainable Urban Design and Climate [Bureau of Meteorology Australia]
- Principles of sustainable urban design [Barton, H., 1996. Going green by design, Urban Design Quarterly, January 1996, available at http://www2.rudi.net/ej/udq/57/ggd.html]:
- Principle 1: Increasing Local Self-Sufficiency
- Principle 2: Human Needs
- Principle 3: Structure Development Around Energy-Efficient Movement Networks
- Principle 4: The Open Space Network
- Principle 5: Linear Concentration
- Principle 6: An Energy Strategy
- Principle 7: Water Strategy
Integrating land-use, transport and environmental planning is important to minimise the need for travel and to promote efficient and effective mode of transport, including walking. There are four principal ways to influence transport system efficiency and energy consumption:
- urban and land-use planning;
- modal mix (cars, trucks, rail, air, etc.);
- behavioural and operational aspects (occupancy of vehicles, driver behaviour, system characteristics); and
- vehicle efficiency and fuel choice.
Pedestrianisation is to restrict vehicle access to a street or area for the exclusive use of pedestrians. It provides a pleasant and safe environment for pedestrians, and are ideal venues for shopping, social and cultural activities such as street markets and fairs.
- Proposed concepts in Hong Kong
- The Third Comprehensive Transport Study : Final Report
Sustainable Cities and Green Development
- Cities as Superorganisms
- Sustainable Cities: Environmentally Sustainable Urban Development
- Green Development Guiding Principles
- Green Development: Integrating Ecology and Real Estate
The benefits from the energy-efficient siting and design of buildings are economic (saving money), social (reducing fuel poverty); and ecological (reducing resource exploitation and emissions). Every new development ideally should have an explicit energy strategy, setting out how these
benefits are to be achieved.
Computer energy simulations can be used to assess energy conservation measures early and throughout the design process. The expanded design team collaborates early in conceptual design to generate many alternative concepts for building form, envelope and landscaping, focusing on minimizing peak energy loads, demand and consumption. Computer energy simulation is used to assess their effectiveness in energy conservation, and their construction costs. Typically, heating and cooling load reductions from better glazing, insulation, efficient lighting, daylighting and other measures allows smaller and less expensive HVAC equipment and systems, resulting in little or no increase in construction cost compared to conventional designs. Simulations are used to refine designs and ensure that energy-conservation and capital cost goals are met; and to demonstrate compliance with regulatory requirements.
- Building Energy Efficiency Research (BEER)
- Energy Design Resources
- Energy-Saving Technology in Business-Related Buildings [UNEP Global Environmental Centre]
- Renewable Energy
Water conservation methods:
- Low flush toilets
- Dual flush toilets (3/6 litres)
- Vacuum or compressed air toilets
- Cistern displacement devices
- Waterless toilets
- Composting toilets (heated or unheated)
- Incinerating toilets
- Urinal controls (infrared, radar, autoflush)
- Waterless urinals
- Wash hand basins:-
- Push taps
- Flow control, self closing
- Tap flow regulators
- Shower mixers
- Water saving showerheads
- Self closing shower system
- Outside and garden:-
- Water control
- Clothes Washers:-
- Water saving washers
- Control & usage
- Water supply:-
- Auto shut off and pressure regulators
- Rain water and grey water:-
- Rain water recycling systems
- Grey water recycling systems
The quantity of energy required by all the activities associated with a production process, including the relative proportions consumed in all activities upstream to the acquisition of natural resources and the share of energy used in making equipment and other supporting functions. i.e. direct plus indirect energy.
The energy input required to quarry, transport and manufacture building materials, plus the energy used in the construction
process, can amount to a quarter of the ‘lifetime’ energy requirement of a very energy-efficient building. To reduce embodied
energy, without compromising longevity or efficiency:
- re-use existing buildings and structures wherever possible (provided their energy costs in use can be reduced to an acceptable level).
- design buildings for long life, with ease of maintenance and adaptability to changing needs
- construct buildings and infrastructure out of local and low- energy materials where possible
- reduce the proportion of high rise, detached or single-storey developments
- design layouts which minimise the extent to roadway and utility pipework per dwelling
- create a strategy
- Prefabrication [CityU CIVCAL]
- Prefabrication in Hong Kong Public Housing
- Harmony Site Visit
- Concord Site Visit
“Waste – a resource in the wrong place” — An old Chinese proverb.
Waste prevention Waste Management Strategies
- Recyclying construction and demolition materials
- Architectural reuse (include adaptive reuse, conservative disassembly, and reusing salvaged materials)
- Design for material recovery (durability, disassembly, adaptive reuse)
- Sustainable development
- On-site reuse
- On-site recovery
- Off-site reuse
- Off-site recovery
|waste v.||waste n.|
|1. to use, consume, spend, or expend thoughtlessly or carelessly||1. a place, region, or land that is uninhabited or uncultivated|
|2. to cause to lose energy, strength, or vigor; exhaust, tire, or enfeeble||2. a devasted or destroyed region, town, or building; a ruin|
|3. to fail to take advantage of or use for profit||3. a useless or worthless by-product, as from a manufacturing process|
|4. to destroy completely||4. garbage; trash|
Humans are the only species on Earth that produce waste which is not a raw material or nutrient for another species. We are the only species to produce wastes that can be broadly toxic and build up for long periods of time. As William McDonough, Dean of the University of Virginia School of Architecture, has said, a sustainable society would eliminate the concept of waste. Waste is not simply an unwanted and sometimes harmful by-product of life; it is a raw material out of place. Waste and pollution demonstrate gross inefficiency in the economic system since they represent resources that are no longer available for use and/or create harm in humans and other species.
- Sustainable Communities [Sustainability Report]
- Sustainability and Sustainable Communities
- Sustainable Cities White Papers [Earth Pledge]
3.7 Indoor Environment
- Indoor air quality
- Visual quality
- Acoustic quality
- Noise control
- Controllability of systems
4.1 Design Guides (online or downloadable)
- ACC Sustainable Facility Guide, 2000. [US Air Force] (PDF)
- Austin Chronicle’s Green Building Guide, 1994.
- Building Green on a Budget [Environmental Building News]
- Checklist for Environmentally Responsible Design and Construction [Environmental Building News]
- Ecotecture [Department of Design and Environmental Analysis,Cornell University]
- Energy Design Guidelines for High Performance Schools
- Energy smart building design: How to make it happen
- Environmental Assessment Guide for Public Housing (October 1996) [HUD]
- Environmental Sustainability Checklist [City of Austin Green Building Program]
- Good Residential Design Guide – Your Home [www.greenhouse.gov.au]
- Green Office Guide [www.greenhouse.gov.au]
- Green Products Guide [Architectural Record]
- Greening Federal Facilities (a resource guide) [USDOE]
- Greening Government: Towards More Sustainable Construction: Green Guide for Managers on the Government Estate [UK Department for Environment, Food & Rural Affairs]
- Greening Portland’s Affordable Housing [City of Portland]
- GSA Real Property Sustainable Development Guide [US General Services Administration]
- A Guide for Managing and Minimizing Building and Demolition Waste [PolyU]
- The Guide to Green Buildings Resources [Green Building British Columbia]
- Guidelines for the design of more sustainable buildings: durability, adaptability and energy conservation issues [University of Strathclyde]
- Guidelines for Total Building Commissioning [State of Florida]
- High Performance Building Guidelines [New York City Department of Design and Construction]
- High Performance Green Building Guidelines [Commonwealth of Pennsylvania]
- High Performance Guidelines: Triangle Region Public Facilities
- Home Remodeling Green Building Guidelines [Alameda County Waste Management Authority]
- Hugh L. Carey Battery Park City Authority Residential Environmental Guidelines
- Introduction to Sustainable Design, by Jong-Jin Kim, University of Michigan, December 1998. (PDF)
- NAHB Research Center, Guide to Developing Green Building Programs, National Association of Home Builders, 1999. (PDF)
- Minnesota Sustainable Design Guide, University of Minnesota, 1999.
- Model Green Office Leasing Specifications [Commonwealth of Pennsylvania]
- National Best Practice Manual for Building High Performance Schools
- New Home Construction Green Building Guidelines [Alameda County Waste Management Authority]
- NWBuildNet’s Environmental Guide
- Process Guidelines for High-Performance Buildings [State of Florida]
- Santa Monica Green Buildings Design & Construction Guidelines
- Sustainable Building Residential Rehabilitation Guidebook (PDF)
- Sustainable Building Sourcebook, Green Building Program of the City of Austin, Texas (HTML by Bill Christensen), 1998.
- Sustainable Building Technical Manual, Public Technology Inc., US Green Building Council, 1996.
- Sustainable Decision Guide For City of Saint Paul Facilities
- Sustainable Design Brochure, Hellmuth, Obata + Kassabaum, Inc.(HOK), St. Louis, Missouri, 1998.
- The Sustainable Design Resource Guide, American Insitute of Architects Committee on the Environment (COTE) and Architects, Designers and Planners for Social Responsibility (ADPSR Colorado), Third Edition, 1997.
- The Sustainable Design Resource Guide: Colorado & the Western Mountain Region, Denver AIA Committee on the Environment, 2000.
- Whole Building Design Guide, 2000.
- Whole Building Design Guide, US Navy, 1997.
- Site selection and planning
- Budget planning
- Capital planning
- Programme planning
- Client awareness and goal setting
- Green vision, project goals & green design criteria
- Team development
- Well-integrated design
- Resource management
- Performance goals
Operation & Maintenance
- Commissioning of building systems
- Building operation
- Maintenance practices
- Assessment Methods: Design [University of Salford]
- ATHENA Sustainable Materials Institute
- BEES (Building for Environmental and Economic Sustainability)
- BRE Environmental Profiles
- BREEAM UK
- BREEAM Canada
- Copy from CSA
- Building Environmental Quality Evaluation for Sustainability Through Time (BEQUEST)
- Construction and City Related Sustainability Indicators CRISP
- EcoHome (UK)
- Info from Battle McCarthy
- Eco-Pro (Finland)
- Eco-Quantum (Netherlands)
- ENVEST (environmental impact estimating design software) [UK BRE]
- Assessment Process & Benifits [Battle McCarthy]
- Environmental Support Solutions
- EQUER (France)
- Green Building Assessment Tool – GBTool 1.3
- A Second-Generation Environmental Performance Assessment System for Buildings
- Green Building Rating System (Korea)
- Green Globes
- Interactive Tools Survey [University of Weimar, Germany]
- International Association for Impact Assessments (IAIA)
- LCAid (Australia)
- LEED Green Building Rating System
- LISA (LCA in Sustainable Architecture)
- New Measures for Building Performance
- SimPro life-cycle assessment software (PRe, Product Ecology Consultants)
- Indoor air quality audit
- Life cycle energy audit
- Initial embodied energy
- Recurring embodied energy
- Operational energy
- Greenhouse gas assessment
- Lighting, thermal and ventilation (LTV) audit
- Hydraulic audit
- Life cycle costing audit
- Post occupancy evaluation
- Bellagio Principles: Guidelines for the Practical Assessment of Progress Towards Sustainable Development
- species richness, abundance, diversity;
- ecological diversity;
- high number of endemic species;
- high number of important gene pools;
Three forms of biodiversity:
Natural environment to protect:
- Water stream
Impact of urban development
- direct species loss
- habitat destruction/fragmentation
- habitat degradation (pollution, decrease in size) e.g. due to disturbance, noise, light
- food web disruption
- No development
- minimise impacts
- Compensation (on site or off site)
- habitat creation/restoration