Getting Started

How to use this Reference Guide

This reference guide is designed to work in conjunction with the rating system. Written by expert users of LEED, it serves as a roadmap, describing the steps tied directly to documenting credit requirements and offering additional advice on best practices.

Within each section, information is organized to flow from general guidance to more specific tips and finally to supporting references and other information. Sections have been designed with a parallel structure to support way finding and minimize repetition across the guide.

Each credit category begins with an overview that discusses sustainability and market factors specific to that topic. The credits list the requirements for achievement. Readers will then find the following sections in each credit section:

• Intent & Requirements outlines the rating system requirements for achieving the prerequisite or credit. They were approved through the rating system development process and can also be found on the USGBC website.
• Behind the Intent connects credit achievement with larger sustainability issues and provides information on how the credit requirements meet the intent stated in the rating system.
• Step-by-Step Guidance suggests the implementation and documentation steps that can be used by most projects, as well as generally applicable tips and examples.
• Further Explanation provides guidance for lengthy calculations or for special project situations, such as tips for nonstandard project types or different credit approaches. It includes a Campus section and, sometimes, an International Tips section.
• Required Documentation lists the items that must be submitted for certification review.
• Related Credit Tips identifies other credits that may affect a project team's decisions and strategies for the credit in question; the relationships between credits may imply synergies or trade-offs.
• Changes from LEED for Homes 2008 indicates the changes since the 2008 version of the LEED for Homes rating system.
• Contract Language Recommendations gives examples of language that the builder or developer can use in agreements with contractors.
• Referenced Standards lists all standards related to the credit and offers web links to find them.
• Verification and Submittals outlines the supporting verification materials and submittals required from the project team and the required verification to be completed by the verification team.

Projects Outside the U.S.

The International Tips section offers advice on determining equivalency to U.S. standards or using non-U.S. standards referenced in the rating system. It is meant to complement, not replace, the other sections of the credit. Helpful advice for projects outside the U.S. may also appear in the Step-by-Step Guidance section of each credit. When no tips are needed or available, the International Tips heading does not appear.

Units of measurement are given in both Inch-Pound (IP) and International System of Units (SI). IP refers to the system of measurements based on the inch, pound, and gallon, historically derived from the English system and commonly used in the U.S. SI is the modern metric system used in most other parts of the world and defined by the General Conference on Weights and Measures.

Where “local equivalent” is specified, it means an alternative to a LEED referenced standard that is specific to a project’s locality. This standard must be widely used and accepted by industry experts and when applied, must meet the credit’s intent leading to similar or better outcomes.

Where “USGBC-approved local equivalent” is specified, it means a local standard deemed equivalent to the listed standard by the U.S. Green Building Council through its process for establishing non-U.S. equivalencies in LEED.

LEED Work Plan

Step 1. Connect with Green Rater organization

A LEED Green Rater is responsible for verification of all prerequisites and credits in the LEED residential rating systems. The Green Rater performs on-site verification and conducts diagnostic testing to ensure that the team’s strategies are effective. All projects are required to have a preliminary rating meeting with the Green Rater as early as possible in the design and construction process (Step 4). Green Raters are listed by location on the USGBC website.

A qualified energy rater is required to verify the energy components and, for LEED BD+C: Homes projects, run the energy model. Most Green Raters are also energy raters.

Step 2. Choose appropriate rating system

The residential rating systems address two kinds of residential construction: single-family and low-rise multifamily, and multifamily midrise. Throughout this reference guide, items marked “Homes” are generally appropriate for single-family buildings and low-rise multifamily buildings (up to three stories). Those marked “Multifamily Midrise” are for predominantly residential projects four stories or more above grade. Some requirements apply to both kinds of construction; for others, there are slight differences. See Rating System Selection Guidance in this reference guide for further details, particularly because certain four- and five- story projects may be appropriate for Homes rather than Multifamily Midrise.

Step 3. Check project eligibility

All projects seeking certification are required to comply with the Minimum Program Requirements and eligibility requirements for their applicable rating system, found on USGBC’s website (also see Minimum Program Requirements in this reference guide).

Major “gut” rehab projects can achieve certification under LEED:BD+C Homes or Multifamily Midrise, but partial rehab or renovation projects cannot. To be considered a major rehab project, the home must be stripped to the studs on at least one side of all external walls and the exterior ceiling, to expose the interstitial space for insulation installation and inspection. The American Society of Interior Designers’ Foundation and USGBC have partnered on the development of best practice guidelines and targeted educational resources for sustainable residential remodeling projects. This program will increase understanding of sustainable renovation project practices and benefits among homeowners, residents, design professionals, product suppliers, and service providers to build both demand and industry capacity. More information is available at regreenprogram.org.

Step 4. Define LEED project scope

Review the project’s program to determine the breadth of team influence and identify any potential limitations to certification. Considerations include the extent of the gut-rehab, if the project is an existing structure, or construction timeline (e.g., is the project already under construction?). Next, map the LEED project boundary. In most cases, this is the property line or lot line. If the project’s boundary is not obvious because of phasing, multiple ownership, or other issues, consult the Minimum Program Requirements.

Step 5. Develop LEED scorecard and preliminary rating

Establish the LEED rating that the project team desires (Certified, Silver, Gold, or Platinum) and identify supporting credits to achieve the desired rating. Make sure that all prerequisites can be met. This preliminary rating is a required first step; the Green Rater will help facilitate the preliminary rating.

Three categories—Location and Transportation, Water Efficiency, and Energy and Atmosphere—have both a prescriptive and a performance path. The project team needs to decide early on which path in each section is appropriate for the project. The Green Rater can guide the team in making this decision, taking into account the project team’s goals, region, and previous experience.

Establishing a buffer of several points above the minimum required points helps ensure success in case changes in design and construction make certain credits unachievable.

Step 6. Assign roles and responsibilities to project team

For the preliminary rating, select one team member to lead the group in setting sustainability goals and coordinating the overall documentation process for submittal to the Green Rater. Both the design and the construction representatives should be involved throughout the process to ensure consistency and clarity.

Team ownership of credit compliance can help foster integrated design while ensuring that documentation is generated consistently across credits. On a credit-by-credit basis, assign primary and supporting roles to appropriate team members for credit achievement and documentation. Although many items in LEED BD+C: Homes and Multifamily Midrise are visually verified on site by the Green Rater, other items are verified through design documents. Clarify responsibilities for ensuring that design decisions are accurately represented in drawings and specifications and that construction details match design documentation.

Establish regular meeting dates and develop clear communication channels to streamline the process and resolve issues quickly.

Step 7. Develop consistent documentation

Consistent documentation is critical to LEED certification. During construction, the team member with lead responsibility for documentation should ensure that other members provide the required plans, drawings, invoices, lists, descriptions, photographs, calculations, and other forms of documentation—as specified in the verification and submittals section for each credit. He or she should collect and save this documentation in a central location and ensure that it is secure and complete. Data should be recorded on a regular schedule to allow the team to track ongoing progress toward the credits. The Green Rater can advise the team on the completeness of the documentation.

Step 8. Schedule site inspections for verification

At a minimum, two site visits by the Green Rater and energy rater are required. The first site inspection is required after insulation has been installed but before drywall. The second is performed when the home and all landscaping are completed.

Step 9. Green Rater review and submit to USGBC for certification

The Green Rater’s review of the documentation is an essential part of certification. All credits must be verified by the Green Rater, through site inspections and review of documentation and calculations. If the Green Rater finds everything in order, he or she signs off and submits the project for quality assurance and USGBC certification review.

BD+C: Homes Project Checklist

BD+C: Multifamil Midrise Project Checklist

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Minimum Program Requirements

The Minimum Program Requirements (MPRs) are the minimum characteristics or conditions that make a project appropriate to pursue LEED certification. These requirements are foundational to all LEED projects and define the types of buildings, spaces, and neighborhoods that the LEED rating system is designed to evaluate. View the Minimum Program Requirements

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Rating System Selection Guidance

Projects are required to use the rating system that is most appropriate. However, when the decision is not clear, it is the responsibility of the project team to make a reasonable decision in selecting a rating system before registering their project. This guidance helps project teams select a LEED rating system. View the Rating System Selection Guidance

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Credit Category Overviews

• LT Overview
• SS Overview
• WE Overview
• EA Overview
• MR Overview
• EQ Overview
• IN Overview
• RP Overview

LT Overview

Building projects have substantial site-related environmental effects. Location and Transportation (LT) credits reward the choice of site locations that promote environmentally responsible land-use patterns and neighborhoods and offer environmental advantages over conventional developments. (The next credit category, Sustainable Sites, focuses on consequences for the site itself.)

Project teams can reduce fragmentation of farmland and forest and other natural areas by building within and near already-developed areas. Well-sited developments need less infrastructure, especially roads and water and sewer lines. And such developments allow residents to use a range of sustainable transportation options, including walking, bicycling, and mass transit, thereby reducing dependence on personal automobiles.

LT points can be earned in either of two ways, summarized in Figure 1.

SS Overview

Although the focus of green building is typically on the built structures, the design of the site and its natural elements can have significant environmental consequences, good or bad. The Sustainable Sites (SS) category rewards project teams for designing the site to minimize adverse effects. (The Location and Transportation category rewards project teams for choosing a preferable site location.)

How a building is incorporated into the site can benefit or harm local and regional ecosystems and reduce or increase demand for water, chemicals, and pesticides for site management. Good decisions, made early in the design process, can result in attractive, easy-to-maintain landscaping that protects native plant and animal species and contributes to the health of local and regional habitats.

Rain that falls on a site can cause soil erosion and runoff of chemicals and pesticides—or it can offset potable water demand and recharge underground aquifers. Plant growth can be a burden, requiring regular upkeep, watering, and chemicals—or it can enhance property values while improving occupants’ comfort, absorbing carbon, enriching the soil, and providing shade, aesthetic value, and habitat for native species.

Site design should take into consideration not only the aesthetic and functional preferences of the occupants but also long-term management needs, preservation principles, and potential effects on local and regional ecosystems.

 

WE Overview

In the U.S., approximately 345 billion gallons of fresh water is withdrawn per day from rivers and reservoirs to support residential, commercial, industrial, agricultural, and recreational activities. This accounts for about one-fourth of the nation’s total supply of renewable fresh water. Almost 65 percent of this water is discharged to rivers, streams, and other waterbodies after use and, in some cases, treatment. Additionally, water is withdrawn from underground aquifers. In some parts of the country, water levels in these aquifers have dropped more than 100 feet since the 1940s.

On an annual basis, the U.S. water deficit is currently estimated at 3.7 trillion gallons—that is, each year, Americans extract 3.7 trillion gallons more than they return to the natural water system to recharge aquifers and other water sources.

Water for domestic use may be delivered from a public supplier or be self-supplied (i.e., by a well). Self-supplied domestic withdrawals are an estimated 3.59 billion gallons per day.

The Energy Policy Act of 1992 mandated the use of water-conserving plumbing fixtures and fittings to reduce water use in residential, commercial, and institutional buildings. Water efficiency measures in new homes can easily reduce water usage by 30% or more. In a typical home, savings of 30,000 gallons of water a year can be achieved very cost-effectively. This results in average annual water utility savings of about $100 per year. As communities grow, increased demand for water necessitates additional maintenance and higher costs for municipal supply and treatment facilities. New homes that use water efficiently have lower water bills and reduced sewage volumes. Many water conservation strategies involve either no additional cost or short-term paybacks; other strategies, such as rainwater harvesting and graywater plumbing systems, often involve more substantial investment.

Figure 1 shows the two pathways for the Water Efficiency (WE) category in the LEED BD+C: Homes and LEED BD+C: Multifamily Midrise rating systems. In one pathway, project teams analyze total water use, both indoors and outdoors. The other pathway awards points based on indoor water use and outdoor water use separately.

 

EA Overview

Although new homes use 14% less energy per square foot than homes built in the 1980s, and 40% less energy per square foot than homes built in the 1950s, according to the U.S. Department of Energy, these efficiency improvements have not kept up the increased size of new homes. The average size of new homes has doubled over the past 50 years. As a result, total U.S. fossil fuel use in homes has been steadily increasing. The average American consumes five times more energy than the average global citizen, 10 times more than the average Chinese person, and nearly 20 times more than the average Indian.

Conventional fossil-based generation of electricity releases carbon dioxide (CO2), which contributes to global climate change. Coal-fired electric utilities emit almost one-third of the country’s anthropogenic nitrogen oxides, the precursor of smog, and two-thirds the sulfur dioxide, which causes acid rain. They also emit more fine particulate material than any other activity in the U.S. Because the human body is incapable of clearing fine particles from the lungs, these emissions are contributing factors in tens of thousands of cancer and respiratory illness–related deaths annually. Natural gas, nuclear fission, and hydroelectric generators all have adverse environmental consequences as well. Natural gas is a major source of nitrogen oxides and greenhouse gas emissions. Nuclear power carries the risk of catastrophic accidents and raises significant waste transportation and disposal issues. Hydroelectric generating plants disrupt natural water flows, disturbing aquatic habitat and reducing fish populations.

Buildings consume approximately 41% of the energy and 74% of the electricity produced in the U.S. annually, according to the U.S. Department of Energy. In 2010, total emissions from residential buildings were responsible for 1.2 billion metric tons of CO2 emissions, or 22% of the U.S. total.

Scientists predict that left unchecked, emissions of CO2 and other greenhouse gases from human activities will raise global temperatures by 2.5º to 11.5ºF (1.4º to 6.4ºC) this century. The effects will be profound and may include rising sea levels, more frequent floods and droughts, and increased spread of infectious diseases. To address the threat of climate change, greenhouse gas emissions must be reduced. Meeting the challenge will require dramatic advances in technologies and a shift in how the world economy generates and uses energy.

Absent significant improvements in environmental performance, the residential building sector will be a major contributor of global CO2 emissions. Homes have a lifespan of 50 to 100 years, during which they continually consume energy and produce CO2 emissions. Further, the U.S. population and economy are projected to grow significantly over the coming decades, increasing the need for new homes. To meet this demand, approximately 1.5 million new homes a year will be constructed by 2016.

Building green homes is one of the best strategies for meeting the challenge of climate change because the technology to reduce energy and CO2 emissions already exists. The average certified LEED home uses 30% to 40% less electricity and saves more than 100 metric tons of CO2 emissions over its lifetime. Modest investments in energy-saving and other climate-friendly technologies can make homes and communities more healthful, comfortable, durable, energy-efficient, and environmentally responsible places to live.

The average mix of end uses of energy in U.S. homes is summarized in Figure 1.

Figure 1. Energy use in U.S. homes. Modified from U.S. Energy Information Administration, Residential Consumption Survey (RECS) 2009.

The actual percentages vary with climate and location—homes in the North use proportionally more energy for space heating and less for electric air-conditioning than homes in the South, and vice versa—but these uses nevertheless represent the primary target areas for energy efficiency improvements.

Figure 2 shows the two parallel pathways through the Energy and Atmosphere (EA) credit category in the LEED BD+C: Homes and LEED BD+C: Multifamily Midrise rating systems. The performance pathway requires the use of an approved energy analysis software program to demonstrate the overall energy performance of the home’s design. The prescriptive pathway enables a project to achieve LEED points without energy modeling. The project may instead demonstrate that each of the prescriptive requirements has been achieved. Credits can be earned using either approach, but projects are encouraged to use the performance pathway.

 

MR Overview

The choice of building materials is important for sustainable homebuilding because of the extraction, processing, and transportation they require. Activities to produce building materials may pollute air and water, destroy natural habitats, and deplete natural resources. Construction and demolition wastes constitute about 40% of the total solid waste stream in the U.S.

Sources should be evaluated when materials are selected for a project. Reclaimed (i.e., salvaged postconsumer) materials can be substituted for new materials, saving costs and reducing resource use. Recycled-content products make use of material that would otherwise be deposited in landfills. Use of local materials supports the local economy and avoids the harmful effects of long-distance transport. Use of third-party–certified wood promotes good stewardship of forests and related ecosystems.

An increasing number of public and private waste management operations have reduced construction debris volumes by recycling these materials. Recovery activities typically begin at the job site, with separation into different bins or disposal areas. In some areas, regional recycling facilities accept commingled waste and separate the recyclable materials from those that must go to the landfill. These facilities can achieve waste diversion rates of 80% or greater.

One aspect of home design that is often overlooked is the assessment and mitigation of long-term durability risks to the home. Durability failures are a significant cost and cause of stress for both builders and homeowners, but many easy and low-cost strategies are available to builders who consider durability in the up-front design.

Good design decisions, particularly in the structural framing of homes, can significantly reduce demand for lumber and other materials, as well as the associated waste and embedded energy. Without changing the design, a builder can save framing materials and reduce site waste by planning appropriately and communicating the strategies to the framing contractor.

EQ Overview

Americans spend, on average, 90% of their time indoors, where levels of pollutants may run two to five times—and occasionally more than 100 times—higher than outdoors, according to the U.S. Environmental Protection Agency. Similarly, the World Health Organization reports that most of an individual’s exposure to many air pollutants comes through inhalation of indoor air. Many of the pollutants found indoors can cause health reactions in the estimated 17 million Americans who suffer from asthma and 40 million who have allergies, contributing to millions of days absent from school and work.

Homeowners are just beginning to realize the link between their health and their homes. Hazardous household pollutants include carbon monoxide, radon, formaldehyde, mold, dirt and dust, pet dander, and residue from tobacco smoke and candles. Many homeowners also store various chemicals inside their homes, including pesticides, fertilizers, solvents, grease, oils, degreasers, gasoline, antifreeze, strong detergents, thinners, and oil-based paints.

Over the past 20 years, research and experience have improved our understanding of what is involved in attaining high indoor environmental quality and revealed manufacturing and construction practices that can prevent problems from arising. Preventing indoor air quality problems is generally much less expensive than identifying and solving them after they occur. Generally, there are three types of strategies: source removal, source control, and dilution.

Source removal is the most practical way to ensure that harmful chemical compounds are not brought into the home. Evaluating the properties of adhesives, paints, carpets, composite wood products, and furniture and selecting materials with low levels of potentially irritating off-gassing can reduce occupants’ exposure. Thoughtful scheduling of deliveries and sequencing of construction activities can reduce exposure of materials to moisture and absorption of off-gassed contaminants.

Source control strategies focus on capturing pollutants that are known to exist in a home. For example, filtering the supply air stream removes particulates that would otherwise be continuously recirculated through the home. Protection of air-handling systems during construction and performing a building flushout before occupancy further reduce the potential for problems.

Dilution involves the use of fresh outside air to ventilate a home and exhaust pollutants to the outdoors. This may also help control moisture within the home. Most new homes in the U.S. do not have mechanical fresh-air ventilation systems. The typical air-handling systems in new homes merely recirculate the air within the home, continuously pumping indoor pollutants through the rooms rather than exhausting them.

Another aspect of indoor air quality is occupants’ comfort. The proper installation of automatic sensors and controls to maintain proper temperature, humidity, and ventilation in occupied spaces helps maintain optimal air quality. Surprisingly, sensors to alert a home’s occupants to deadly carbon monoxide concentrations are frequently not required by code but should be included in all new homes. Letting occupants fully and effectively control their thermal environment can reduce hot-cold complaint calls and generally raise satisfaction levels.

The Indoor Environmental Quality (EQ) credit category encourages builders to prevent air pollution and improve air quality and comfort in the homes they build.

 

IN Overview

Sustainable design strategies and measures are constantly evolving and improving. New technologies are continually introduced to the marketplace, and up-to-date scientific research influences building design strategies. Occasionally, a strategy results in building performance that greatly exceeds that required in an existing LEED credit. Other strategies may not be addressed by any LEED prerequisite or credit but warrant consideration for their sustainability benefits.

Green homebuilding strategies and techniques are most effectively implemented as part of an integrated design process, with input from individuals involved in each phase of the project. Good design can keep costs down and ensure proper integration of green techniques and achievement of project goals.

The Innovation (IN) credit category encourages project planning and design to improve the coordination and integration of the various elements in a green home. This category also creates an opportunity for projects to earn credit for implementing strategies or measures not addressed in the current LEED BD+C: Homes or LEED BD+C: Multifamily Midrise rating systems. Points can be earned for innovative strategies, exemplary performance, or regional best practices that deliver quantifiable environmental and human health benefits.

 

RP Overview

Because some environmental issues are particular to a locale, volunteers from USGBC chapters and the LEED International Roundtable have identified distinct environmental priorities within their areas and the credits that address those issues. These Regional Priority credits encourage project teams to focus on their local environmental priorities.

USGBC established a process that identified six RP credits for every location and every rating system within chapter or country boundaries. Participants were asked to determine which environmental issues were most salient in their chapter area or country. The issues could be naturally occurring (e.g., water shortages) or man-made (e.g., polluted watersheds) and could reflect environmental concerns (e.g., water shortages) or environmental assets (e.g., abundant sunlight). The areas, or zones, were defined by a combination of priority issues—for example, an urban area with an impaired watershed versus an urban area with an intact watershed. The participants then prioritized credits to address the important issues of given locations.

Because each LEED project type (e.g., a data center) may be associated with different environmental impacts, each rating system has its own RP credits.

The ultimate goal of RP credits is to enhance the ability of LEED project teams to address critical environmental issues across the country and around the world.