LEED Core Concepts Guide (3rd Ed) - PDF

Summary

This book provides an introduction to LEED and green building, covering core concepts and principles. It explores the environmental impacts of buildings and the rise of the green building industry. Focusing on sustainable design, it details how green building can improve communities and create healthy spaces.

Full Transcript

LEED®
Core Concepts
Guide

An Introduction
to LEED and
Green Building

THIRD EDITION
 LEED® Core Concepts Guide:
An Introduction to LEED and Green Building

THIRD EDITION
PURCHASE AGREEMENT AND LICENSE TO USE LEED® CORE
CONCEPTS GUIDE: AN INTRODUCTION TO LEED AND GREEN
BUILDING, THIRD EDITION

The U.S. Green Building Council (USGBC) devoted significant time and resources to create this
Guide and all of its LEED™ publications. All LEED publications are protected by statutory copyright
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Core Concepts Guide: An Introduction to LEED and Green Building, Third Edition (the “Guide”),
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None of the parties involved in the funding or creation of the Guide, including the U.S. Green
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Although the information contained in the Guide is believed to be reliable and accurate, the Guide is
provided as-is with no warranty of any kind, either expressed or implied including, but not
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have a right to assert against such parties as a result of the use of, or reliance on, the Guide.

PUBLISHED BY:
U.S. Green Building Council
2101 L Street NW
Suite 500
Washington, DC 20037

TRADEMARK
LEED® is a registered trademark of the U.S. Green Building Council.
ISBN: 978-1-932444-34-6
ACKNOWLEDGEMENTS
Thanks to all of the consultants that developed the
content of this guide, based on their many years of
experience in the green building industry:
Karen Blust, CTG Energetics, Inc.
Natalie Bodenhamer, CTG Energetics, Inc.
John Boecker, 7group
Clare Jones, CTG Energetics, Inc.
Lani Kalemba, CTG Energetics, Inc.
Joshua Joy Kamensky, CTG Energetics, Inc.
Nick Rajkovich, University of Michigan
Kathy Roper, Georgia Institute of Technology
Heather Joy Rosenberg, CTG Energetics, Inc.
Chris Shaffner, The Green Engineer, LLP
Lynn Simon, Simon & Associates, Inc.
Joel Todd, Environmental Consultant

Thanks to U.S. Green Building Council staff who
managed this project:
Jacquelyn Erdman
Julia Feder
Karol Kaiser
Jacob Monroe
Jenny Poole
Jen Schill
Contents
IMAGINE IT........................................... 1
A letter from the President, CEO and Founding Chair

SECTION 1. INTRODUCTION TO GREEN BUILDINGS AND COMMUNITIES........ 2
The Environmental Impacts of Buildings
What is Green Building?
The Rise of the Green Building Industry
Green Building and Climate Change
Green Building Over Time
Green Building and Location
Green Building Costs and Savings
Beyond Green
Green Building Expertise

SECTION 2. SUSTAINABLE THINKING........................... 18
Systems Thinking
Life-cycle Approach
Integrative Process

SECTION 3. SUSTAINABLE THINKING AT WORK:
NEW PROCESSES FOR BUILDING GREEN......................... 32
Getting Started
Establishing an Iterative Process
Team Selection
Goal Setting
Observation of the System
Exploration and Selection of Technologies and Strategies
Implementation
On going Performance

SECTION 4. GREEN BUILDING CORE CONCEPTS AND
APPLICATION STRATEGIES................................. 50
Location and Transportation
Sustainable Sites
Water Efficiency
Energy and Atmosphere
Materials and Resources
Indoor Environmental Quality
Innovation

SECTION 5. ABOUT USGBC AND LEED........................... 84
About USGBC
About LEED

CONCLUSION......................................... 94

APPENDICES......................................... 96
A: Resources
B: Case Study Information
 Imagine It
A letter from the
President, CEO and
Founding Chair

RICK FEDRIZZI
President, CEO and Founding Chair
U.S. Green Building Council
CORE
L EED CON
L EED CORE GU ID E G—UIDE
CON CEPTS
CEPTS EDIR
— TH
T HIRD E DIT I ON
I ON
ITD

H
Imagine getting up on a warm spring morning and deciding it’s
the perfect day to ride your bike to work. Invigorated by your
morning ride and eager to start the day, you head into your
office. As you pass through a common area, you see a group of
coworkers deep in a collaborative work session. They’re seated
around a gorgeous oak table hand-crafted by local artisans and
made entirely of wood reclaimed from a tree that fell naturally in
a nearby forest.

Imagine getting to your desk and sitting down without flipping a light switch—the huge floor-to-ceiling
windows nearby provide plenty of natural springtime light, and if it gets cloudy this afternoon, sensors in
your work area will kick on overhead lighting to an appropriate level of brightness. Meanwhile, your personal
control of the temperature in your work area allows you to stay warm even as your neighbor, who has a higher
cold tolerance, works at a temperature that’s comfortable for him.

Imagine being surrounded by decorative elements that invoke nature and keep you connected to the natural
world even while you’re inside. Imagine an herb garden in the office cafeteria and an educational display in
the office lobby—constant reminders for you and your company’s visitors of just what it is that makes your
building so special.

And imagine leaving the office to find that it has started raining. But not to worry, you just duck around the
corner to one of the many bus stops nearby. You mount your bike to the rack on the front of the bus and
climb aboard.

You settle into your seat at the end of a full day of work, feeling the positive effects of having spent your day
in an environment filled with clean indoor air, with plenty of exposure to natural light. Your mind is clear and
your energy and spirits high, knowing that your workday cost substantially less in energy and water use than
it would have in a more traditional building.

This is what it feels like for me and my colleagues at the LEED Platinum U.S. Green Building Council
headquarters in Washington, D.C. It is what it’s like for the thousands upon thousands of people worldwide
who work in LEED-certified office space. And if you tweak the details, it is what it’s like for all the students
nationwide who study in green schools and live in green dorms, and for the increasing number of families
who live in green homes.

Now, imagine that designing, building, operating, marketing, supporting, or celebrating green buildings was
at the heart of your everyday work. Imagine being a green building professional.

With the LEED Core Concepts Guide, you’re on your way to just such a career. We hope you enjoy the journey,
and we look forward to the innovations you’ll bring as part of the green building community.
I MAGIN E IT

1
2
L EED CORE CORE
L EED CON CON CEPTS
CEPTS GU ID E G—UIDE — TH
T HIRD EDIR
ITD E DIT I ON
I ON

and Communities
Green Buildings
Introduction to
Section 1
Our built environment is all around us; it provides the setting
for all our lives’ events, big and small. And whether we notice
it or not, our built environment plays a huge role in our natural
environment, our economic environment, and our cultural
environment. The built environment provides a context for facing
and addressing humankind’s greatest contemporary challenges.

Green building is fundamentally a process of continual improvement. It is a process by which today’s “best
practices” become tomorrow’s standard practices, a rising foundation for ever-higher levels of performance.
Green building can help us create more vital communities, more healthful indoor and outdoor spaces,
and stronger connections to nature. The green building movement strives to effect a permanent shift
in prevailing design, planning, construction, and operations practices, resulting in lower-impact, more
sustainable, and ultimately regenerative built environments.

For the purposes of this guide, “built environment” refers to any environment that is man-made and
provides a structure for human activity. These environments range from shelters and individual buildings
to neighborhoods and vast metropolitan areas. This guide explains the reasons we must change traditional
building practices. It presents fundamental concepts of green building and provides a summary of the
application strategies that will help you be a more effective participant in the green building process.

The remainder of this section of the guide gives the rationale for green building and the related concept of
sustainability. The core concepts of sustainable thinking are explored in Section 2. Section 3 looks at important
components of the sustainable design and operations process. Section 4 reviews the application of green
technologies and strategies. Section 5 offers more information on the programs of the U.S. Green Building
Council (USGBC), particularly the Leadership in Energy and Environmental Design (LEED) certification
system. Additional resources are listed in the Appendix, and educational opportunities to support your growth
and success as a green building professional are available from USGBC at usgbc.org/education.

THE ENVIRONMENTAL IMPACTS OF BUILDINGS

Why is green building necessary? Buildings and communities, including the resources used to create them
and the energy, water, and materials needed to operate them, have a significant effect on the environment
and human health. In the United States, buildings account for:
14% of potable water consumption1
30% of waste output
40% of raw materials use2
38% of carbon dioxide emissions
24% to 50% of energy use
72% of electricity consumption3
S ECT IO N 1

1 J.F. Kenny, N.L. Barber, S.S. Hutson, K.S. Linsey, J.K. Lovelace, & M.A. Maupin. Estimated use of water in the United States in 2005:
U.S. Geological Survey Circular 1344, (2009).
2 D.M. Roodman & N. Lenssen “A Building Revolution: How Ecology and Health Concerns Are Transforming Construction,”
Worldwatch Paper 124 (Worldwatch Institute, 1995).
3 Energy Information Administration, EIA Annual Energy Outlook (EIA, 2008).
3
 THE CUMULATIVE EFFECT OF CONVENTIONAL PRACTICES IN
THE BUILDING INDUSTRY HAS PROFOUND IMPLICATIONS FOR
HUMAN HEALTH, THE ENVIRONMENT, AND THE ECONOMY:
Clearing of land for development often destroys wildlife habitat
Extracting, manufacturing, and transporting materials may pollute water and air,
release toxic chemicals, and emit greenhouse gases
Building operations require large inputs of energy and water and generate
substantial waste streams
Transportation to and from buildings by commuters and service providers
compounds the harmful environmental effects associated with vehicle use, such
as increased energy consumption and pollution

By building green, we can reduce that environmental damage. In many cases, green buildings can even
enhance the health of the environment and the people who use them.

A study by the New Buildings Institute found that in green buildings, average energy use intensities
(energy consumed per unit of floor space) are 24% lower than in typical buildings.4 Additionally, the
U.S. General Services Administration surveyed 12 green buildings in its portfolio and found these savings
and improvements:
26% less energy usage
27% higher levels of occupant satisfaction
13% lower maintenance costs
33% lower emissions of carbon dioxide (CO2)5

120

100

80

60
Youngstown CH/FB
L EED CORE CON CEPTS G UIDE — TH IR D E DIT I ON

Omaha NPS FB
Greeneville CH
Fresno CH/FB

Davenport CH

40
Lakewood FB
Santa Ana FB

Cleveland CH
Knoxville FB

Omaha DHS

Denver CH
Ogden FB

20

0

ENERGY USE INTENSITY (kBtu/sf/yr)

Figure 1.1. Energy Use Intensities for Sustainably Designed U.S. Government Buildings (Source: GSA 2008)
The dotted line indicates the national average energy use intensity.

4 Turner, C. & Frankel, Energy Performance of LEED® for New Construction Buildings (2008),
newbuildings.org/sites/default/files/Energy_Performance_of_LEED-NC_Buildings-Final_3-4-08b.pdf.
5 Public Buildings Service, “Assessing Green Building Performance: A Post Occupancy Evaluation of 12 GSA Buildings”
(General Services Administration, 2008), gsa.gov/graphics/pbs/GSA_Assessing_Green_Full_Report.pdf.

4
The study concluded that the federal government’s green buildings outperform national averages in all
measured performance areas—energy, operating costs, water use, occupant satisfaction, and carbon
emissions. The agency attributed this performance to a fully integrated approach to sustainable design that
addressed environmental, financial, and occupant satisfaction issues. This higher performance will last
throughout a building’s lifetime if the facility is also operated and maintained for sustainability.

WHAT IS GREEN BUILDING?

Sustainability is not a one-time treatment or product. Instead, green building is a process that applies to
buildings, their sites, their interiors, their operations, and the communities in which they are situated.
The process of green building flows throughout the entire life-cycle of a project, beginning at the inception
of a project idea and continuing seamlessly until the project reaches the end of its life and its parts are
recycled or reused.

In this guide, the term green building encompasses planning, design, construction, operations, and
ultimately end-of-life recycling or renewal of structures. Green building pursues solutions that represent
a healthy and dynamic balance between environmental, social, and economic benefits.

Sustainability and “green,” often used interchangeably, are about more than just reducing environmental
impacts. Sustainability means creating places that are environmentally responsible, healthful, just, equitable,
and profitable. Greening the built environment means looking holistically at natural, human, and economic
systems and finding solutions that support quality of life for all.

Triple bottom line is also often used to refer to the concept of sustainability. The term was coined by John
Elkington, cofounder of the business consultancy SustainAbility, in his 1998 book Cannibals with Forks:
the Triple Bottom Line of 21st Century Business. First applied to socially responsible business, the term can
characterize all kinds of projects in the built environment. The triple bottom line concept incorporates a
long-term view for assessing potential effects and best practices for three kinds of resources:
PEOPLE (SOCIAL CAPITAL). All the costs and benefits to the people who design, construct, live in,
work in, and constitute the local community and are influenced, directly or indirectly, by a project
PLANET (NATURAL CAPITAL). All the costs and benefits of a project on the natural environment,
locally and globally
PROFIT (ECONOMIC CAPITAL). All the economic costs and benefits of a project for all the
stakeholders (not just the project owner)

The goal of the triple bottom line, in terms of the built environment, is to ensure that buildings and
communities create value for all stakeholders, not just a restricted few. For example, an energy-efficient
building that saves the owners money but makes the occupants sick is not sustainable, nor is a material that
has a small carbon footprint but was made in a sweatshop, nor is an eco-resort that displaces threatened
species or local people.
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5
 Economic
Prosperity

THE
TRIPLE
Environmental BOTTOM
Stewardship LINE

Social
Responsibility

Figure 1.2. The Triple Bottom Line

A commitment to the triple bottom line means a commitment to look beyond the status quo. It requires
consideration of whole communities and whole systems, both at home and around the world. Research is
needed to determine the impacts of a given project and find new solutions that are truly sustainable. New
tools and processes are required to help projects arrive at integrative, synergistic, sustainable solutions.

The triple bottom line requires a shift in perspective about both the costs and the benefits of our decisions.
The term externalities is used by economists to describe costs or benefits incurred by parties who are not
part of a transaction. For example, the purchase price of a car does not account for the wear and tear it
will have on public roads or the pollution it will put into the environment. To shift the valuation process
to account for such negative externalities, building professionals require new metrics. The green building
process and rating systems have begun to encourage quantification of externalities. The focus has been first
on environmental metrics, but the list is expanding to include indicators of social justice and public health.
L EED CORE CON CEPTS G UIDE — TH IR D E DIT I ON

Making buildings more healthful, more comfortable, and more conducive to productivity for their occupants
has special significance in light of studies conducted by the U.S. Environmental Protection Agency (EPA),
which found that people in the United States spend, on average, 90% of their time indoors.6 Occupants of
green buildings are typically exposed to far lower levels of indoor pollutants and have significantly greater
satisfaction with air quality and lighting than occupants of conventional buildings. Research conducted at
Carnegie Mellon University shows that these benefits can translate into a 2% to 16% increase in workers’
and students’ productivity. Even small increases in productivity can dramatically increase the value of
a building.7

6 U.S. Environmental Protection Agency, The Inside Story: A Guide to Indoor Air Quality. U.S. EPA/Office of Air and Radiation.
Office of Radiation and Indoor Air (6609J) Cosponsored with the Consumer Product Safety Commission, EPA 402-K-93-007.
epa.gov/iaq/pubs/insidestory.html.
7 V. Loftness, V. Hartkopf, B. Gurtekin, and Y. Hua, “Building Investment Decision Support (BIDS™): Cost-Benefit Tool to Promote
High Performance Components, Flexible Infrastructures and Systems Integration for Sustainable Commercial Buildings and
Productive Organizations,” Report on university research (AIA, 2005).

6
 THE RISE OF THE GREEN BUILDING INDUSTRY

Many of the elements of green building are not new or even unique. Before the widespread availability of
inexpensive fossil fuels for energy use and transportation, builders understood the principles of passive
design, capturing sunlight and wind for natural lighting, heating, and cooling. In many ways, green building
represents a return to simpler, low-tech solutions. At the same time, there are now many high-tech strategies
available to improve the performance of the built environment. Green building is about finding the best
combination of solutions to create built environments that seamlessly integrate the best of the old and the
new in intelligent and creative ways.

The USGBC was formed in 1992, a time when the field was beginning to define itself, to promote and
encourage green building. A member-based organization, USGBC engages hundreds of thousands of
individuals. The mission of USGBC is “to transform the way buildings and communities are designed, built
and operated, enabling an environmentally and socially responsible, healthy, and prosperous environment
that improves the quality of life.”8 USGBC supports achievement of this mission through education
programs, advocacy, research, an extensive network of local chapters, and the LEED green building program.

Soon after it was formed, USGBC began developing LEED for rating and certifying sustainability in the
building industry. Experts identified characteristics and performance levels that contributed to a definition
of a green building. The first LEED green
building rating system was launched in
2000. In the decade that followed, LEED
expanded to include systems to address the
entire life-cycle of the built environment
from land-use planning to operations. It now
provides rating systems for a wide array of
building types, such as offices, schools, retail
establishments, homes, and neighborhoods.

The trend toward green building practices in
the United States has quickened in the past The Chesapeake Bay Foundation, an environmental advocacy,
restoration, and education organization, is headquartered in
decade, contributing to a transformation
Annapolis, Maryland. Photo credit: Robb Williamson
in the market of building products and
services, as well as the demand for skilled professionals. As more green products and technologies
become available, green building will become more mainstream.

Federal, state, and local governments are among those adopting sustainable building practices and
policies. For example, the largest federal property owners, the Department of Defense and General
Services Administration have policies in place to pursue LEED certification in the new construction and
major renovation rating system. Government agencies, utility companies, and manufacturers increasingly
offer financial incentives for developers and owners to enhance the environmental performance of their
buildings. The goal of LEED is market transformation—to fundamentally change how we design, build, and
S ECT IO N 1

operate buildings and communities—through certification that honors levels of achievement in areas such

8 U.S Green Building Council, Strategic Plan 2013 - 2015 (USGBC, 2012).

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 as energy savings, water efficiency, CO2 emissions reduction, improved indoor environmental quality, and
stewardship of resources.

More information on USGBC and LEED is provided in Section 5.

GREEN BUILDING AND CLIMATE CHANGE

Although many environmental impacts are associated with buildings and addressed by rating systems such
as LEED, climate change deserves special consideration because buildings and land-use are responsible for
a large proportion of greenhouse gas emissions. To be effective, the policies that are emerging at the local,
state, and federal levels to regulate greenhouse gas emissions must reflect a clear understanding of the
connection between climate change and the built environment. Unfortunately, it is not enough for green
building to lessen the effects that humans have on our climate. It must also prepare us for the inevitable
consequences of climate change on our homes, communities, and society as a whole. A lower-carbon future
will not only have higher-performing buildings but also require higher-performing communities.

The built environment, including buildings and transportation systems, accounts for more than two-thirds
of all greenhouse gas emissions.9 Greenhouse gas emissions come from many components of the built
environment, including building systems and energy use, transportation, water use and treatment, land-
cover change, materials, and construction. By improving the efficiency of buildings and communities, we
can significantly reduce greenhouse gas emissions.

However, focusing on building design and construction alone will not achieve the emissions reduction
that scientists believe is required to mitigate climate change. Building location is equally important. For
example, a typical code-compliant 135,000-square-foot office building in a car-oriented suburban location
will be responsible for approximately 8,375 tons (T) of carbon, or 11.8 T per person. Because this building is
in the suburbs, emissions from transportation—people driving to and from work—make up half the total
emissions associated with the project.
L EED CORE CON CEPTS G UIDE — TH IR D E DIT I ON

9 Energy Information Administration, Annual Energy Outlook 2008 (EIA, 2008), eia.doe.gov/oiaf/aeo/pdf/0383(2008).pdf.

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 Common Sources of Federal Greenhouse Gas Emissions

CH4 N2O
HFCs
SF6
PFCs
CO2

SCOPE

SCOPE
2 SCOPE

1 Greenhouse gas
emissions resulting
from the generation
3
Greenhouse gas Greenhouse gas
emissions from of electricity, heat, or emissions from sources
sources that are owned steam purchased by a not owned or directly
or controlled by a Federal agency. controlled by a Federal
Federal agency. agency but related to
agency activities.
Purchased electricity
Purchased heating/cooling Transmission and distribution
Vehicles and equipment losses from purchased electricity
Purchased steam
Stationary sources Business travel
On-site landfills & Employee commuting
wastewater treatment Contracted solid waste disposal
Fugitive emissions Contracted wastewater
treatment

Figure 1.3. Common Sources of Greenhouse Gas Emissions from Federal Facilities as Called Out by Executive Order 13514.

When that same building is moved to a location that is accessible via public transportation, bicycling, or
walking, its total emissions decrease. The emissions from transportation are much less, and the relative
amount from the building systems increases.

When the building is designed and maintained as a green building with improved energy and water
performance, the total emissions fall to 3,233 T, or 4.6 T per person. This example demonstrates the
important link between buildings and land use and the need to address both to achieve meaningful
reductions in greenhouse gas emissions.
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 Figure 1.4. Building Location without Supporting Figure 1.5. Building Location with Infrastructure
Infrastructure and Services and Services

Carbon emissions provide a useful metric for many aspects of green buildings and communities, including
energy, water, solid waste, materials, and transportation, but green building involves more than reducing
greenhouse gas emissions. It is important to set goals for other issues as well, such as indoor air quality,
human health, and habitat protection. This comprehensive goal-setting process encourages programs and
policies that will lead to sustainable communities. The goal-setting process will be discussed in Section 3.

ENERGY CONSUMPTION: BUILDING-ASSOCIATED
TRANSPORTATION VERSUS OPERATIONS
For an average office building in the United States, 30 percent more energy is expended
by office workers commuting to and from the building than is consumed by the building
itself for heating, cooling, lighting, and other energy uses. Even for an office building built
to modern energy codes (ASHRAE 90.1–2010), more than twice as much energy is used
by commuters than by the building.10

Flexibility and adaptability are increasingly important attributes of green projects. Although the long-
term effects of climate change are uncertain, we know that sea levels will be higher, temperatures higher,
droughts longer and more widespread, and flooding more intense. How different regions will experience
L EED CORE CON CEPTS G UIDE — TH IR D E DIT I ON

these changes will vary considerably, and building professionals will have to assess the likely threats to their
communities and respond accordingly.

GREEN BUILDING OVER TIME

Green projects must be prepared to adapt to future change and be designed and operated to stand the test
of time. Continuous monitoring is required to identify needed improvements and users’ changing needs.
Project teams must look far ahead to determine what stressors a project is likely to encounter and then build
resilience into the system.

10 H. Levin. Driving to Green Buildings: The Transportation Energy Intensity of Buildings. Environmental Building News, 16:9 (2007).
buildinggreen.com

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For example, where water supply depends on local snowpack, planning and design efforts might focus on
water conservation, water storage, and alternative sources of water in anticipation that the snowpack will
shrink. Where summer heat is already high, green builders will have to consider what will happen with even
hotter temperatures and ensure that the cooling strategies of buildings can handle higher degree-days and
still maintain air quality, which will be exacerbated at higher temperatures. These strategies and others will
be discussed in Section 4.

The performance of most systems degrades with time, and thus a building’s total emissions footprint
incrementally increases over time unless care is taken to maintain the systems properly. Figure 1.6 illustrates
building performance by looking at the total amount of carbon emissions over a building’s life-cycle.

Building commissioning helps project teams ensure that systems are designed efficiently, are installed
appropriately, and operate as intended. Commissioning is the process of verifying and documenting
that a building and all its systems and assemblies are planned, designed, installed, tested, operated, and
maintained to meet the owner’s project requirements. However, even if initial performance is optimal,
emissions will rise as performance falls over time. This trend can be periodically reversed through
retrocommissioning, a tune-up that identifies inefficiencies and restores high levels of performance.
Commissioning and retrocommissioning will be reviewed in further detail in Section 4.

Today’s typical building
GHG emissions

Today’s efficient building

Green, high-performance building

Years

Figure 1.6. Carbon Emissions Related to Building Performance Over Time

Green building professionals strive to follow a path of continuous improvement. Because projects must be
designed for the future, their operators need to participate in the design process and obtain the information
they will need to monitor and maintain the building’s performance. Operators also benefit from monitoring
and verification systems, which enable facilities personnel to identify and resolve issues that arise over time
and even enhance a building’s performance throughout the life of the project.
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 A chief goal of green building practitioners is to find new uses for existing structures. Adaptive reuse is
the practice of redesigning and using a structure for a use that is significantly different from the building’s
original use. Buildings can also be designed to prevent future obsolescence; for example, a flexible floor plan
can accommodate offices today and apartments tomorrow. This avoids the environmental consequences
of extracting materials for a new building and disposing of demolition waste. The adapted building reuses a
site that is already served by infrastructure and avoids the conversion of farmland or forest to development.
Designing a project to meet both current and evolving needs is one key to sustainability.

Adaptability is also critical for land use and municipal infrastructure, such as roads. Once road networks
are established, they can remain fixed for centuries. In Rome, for example, the roadways that existed in
ancient times have become today’s automobile roads. This issue is particularly important as we move
toward a lower-carbon future. Alternative transportation, including availability of public transportation,
is essential for reducing carbon emissions. However, options for alternative and public transit, including
bicycling and walking, depend on the proximity of destinations, connectivity of the community, and design
of surroundings. Roads that are designed for only motor vehicles do not provide the flexibility or adaptability
of a transportation network designed for diverse travel modes.

Buildings that protect the history and character of a place also promote sustainability. A project team can
take advantage of the community’s past by reusing materials with historic value. Linking the present with
the past reinforces a sense of place and helps create attractive communities with viable commercial centers.
Sustainable design ensures that buildings and communities will survive and thrive for generations, no matter
what the future holds.

GREEN BUILDING AND LOCATION

A place for everything,
everything in its place.
Benjamin Franklin
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Location is a critical element of green building: it can define appropriate strategies, yet it can also limit how
green a project can actually be. Depending on the environmental issues that are most critical in a particular
area, location can influence a project team’s priorities. Location includes these factors:
NATURAL CONTEXT. Climate, sun, wind, orientation, soils, precipitation, local flora and fauna.
INFRASTRUCTURAL CONTEXT. Available resources, materials, skills, and connections to utilities,
roads and transit.
SOCIAL CONTEXT. Connections to the community and other destinations, local priorities, cultural
history and traditions, local regulations and incentives.

12
PROJECT CASE STUDY

NORTHWEST GARDENS
LEED GOLD

Northwest Gardens (NWG) is a transit-rich affordable housing development adjacent to downtown Fort
Lauderdale, FL. The location of the NWG neighborhood on an urban infill site is ideal for the LEED for
Neighborhood Development (LEED ND) program. The community boasts sufficient density to support nearby
mass transit, accessible via a gridded street network of compact blocks. The project contains 394 dwelling units
located in 44 multi-family buildings in addition to several retail and office buildings. The Housing Authority for
the City of Fort Lauderdale (HACFL) welcomed the idea of using LEED ND and engaged their development
partner Carlisle Development Group to further improve the community. Together, they expanded programs
to install energy efficient street lighting and added pocket parks, community gardens, fruit trees, bioswales
and additional walking paths throughout the community. Each of the homes is pursuing LEED for Homes
Certification for improvements in energy use, water consumption and indoor air quality. To learn more about
Northwest Gardens visit usgbc.org/projects/northwest-gardens
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Courtesy of The Housing Authority of the City of Fort Lauderdale
13
 Selecting a location is one of the earliest decisions made in a project, and this decision defines many of the
opportunities and constraints that the project team will encounter. It can determine whether a project can
take advantage of sunlight, have access to public transportation and other services, and protect habitats. As
discussed earlier in this section, a building whose occupants must drive long distances may contribute to
greenhouse gas emissions, as well as destruction of natural habitat for infrastructure development.

To design sustainably for place, a team can start with a project site and determine what uses are most
appropriate there. Alternatively, the team can start with a function and find the best place to put it. In either
case, the goals of the project must be clear and the needs and resources must be clearly identified so that the
building can be carefully integrated into its context and support a thriving and sustainable local community.

Project teams with a goal of sustainability develop a deep understanding of the place and context in which
their projects are built. They go beyond a cursory site assessment and study the land and its history. They
look for ways to make connections to the immediate site, the surrounding watershed, or ecological features
and promote their healthy evolution. They also engage the community’s traditions, strengths, and needs in
order to ascertain how the project can contribute to social and economic well-being and growth.

GREEN BUILDING COSTS AND SAVINGS

At first glance, the additional work and alternative materials needed to build green may seem like a
burdensome cost, but closer attention reveals this perception to be misleading. If sustainability is viewed
as an expensive add-on to a building, we would mistake efforts to reduce energy costs or improve indoor
environmental quality as comparable to specifying a better grade of countertop or a more impressive front
door. Under this approach, any improvement beyond a minimally code-compliant baseline looks like an
added cost.

If, however, we consider energy improvements part of an overall process, we often find that the added
costs are balanced by long-term savings. The initial expenditures continue to pay back over time, like a
good investment. The best returns on these investments are realized when green building is integrated
into the process at the earliest stages rather than as a last-minute effort. For instance, specification of more
costly, high-performance windows may allow for the use of a smaller, lower-cost heating, ventilation,
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and air-conditioning (HVAC) system. More fundamentally, if we view sustainable design as part of the
necessary functional requirements for building an energy-efficient structure and providing a safe, healthful
environment, we can compare the cost of the green building with that of other buildings in the same class,
rather than against an artificially low baseline.

A landmark study by the firm Davis Langdon found no significant difference between the average cost
of a LEED-certified building and other new construction in the same category: there are expensive green
buildings, and there are expensive conventional buildings. Certification as a green building was not a
significant indicator of construction cost.11

11 L.F. Matthiessen and P. Morris, “Cost of Green Revisited: Reexamining the Feasibility and Cost Impact of Sustainable Design in
the Light of Increased Market Adoption” (Davis Langdon, 2007), davislangdon.com.

14
Interestingly, the public dramatically overestimates the marginal cost of green building. A 2007 public opinion
survey conducted by the World Business Council for Sustainable Development found that respondents believed,
on average, that green features added 17% to the cost of a building, whereas a study of 146 green buildings found an
actual average marginal cost of less than 2%.12

Green building is, however, a significant predictor of tangible improvements in building performance, and those
improvements have considerable value. Studies have shown that certified green buildings command significantly
higher rents. A University of California–Berkeley study analyzed 694 certified green buildings and compared
them with 7,489 other office buildings, each located within a quarter-mile of a green building in the sample.
The researchers found that, on average, certified green office buildings rented for 2% more than comparable
nearby buildings. After adjusting for occupancy levels, they identified a 6% premium for certified buildings. The
researchers calculated that at prevailing capitalization rates, this adds more than $5 million to the market value of
each property.13

BEYOND GREEN

Initially, green buildings were intended to reduce damage to the environment and human health caused by
creating and maintaining buildings and neighborhoods. As the concept of sustainability was applied to the built
environment, it has become clear that doing less damage is not enough.

Leaders in the field now speak about buildings and communities that are regenerative, meaning that these
sustainable environments evolve with living systems and contribute to the long-term renewal of resources and
life. Some practitioners have begun to explore what it would mean to move beyond “sustainable” and participate
as a positive developmental force in our ecosystems and communities. The focus is on building a comprehensive
understanding of the place in which the project is located, recognizing the site’s patterns and flow of life.
Accordingly, such projects contribute to the healthy coevolution of humans and all life in that place. They thrive
on diversity, for example, and clean the air rather than pollute it. Regenerative projects and communities involve
stakeholders and require interactivity.

Figure 1.7. Regenerative Design
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12 G. Kats et al., Green Buildings and Communities: Costs and Benefits (Good Energies, 2008).
13 P. Eichholtz, N. Kok, and J.M. Quigley, “Doing Well by Doing Good? Green Office Buildings” (Institute of Business and Economic
Research, University of California–Berkeley, 2008), mistra.org/download/18.39aa239f11a8dd8de6b800026477/IBER+Green+Office+Buil
dings+NKok+et+al.pdf.

15
 Regenerative projects support the health of the local community and regional ecosystems, generate
electricity and send the excess to the grid, return water to the hydrologic system cleaner than it was before
use, serve as locations for food production and community networking, regenerate biodiversity, and
promote many other relationships that link the projects to the whole system of life around them.

Regenerative projects strive toward “net-zero”—using no more resources than they can produce. For
example, net-zero energy projects use no more energy from the grid than they generate on site. These
projects may be connected to the grid, drawing electricity from it at night and contributing energy from on-
site renewable energy systems during the day, such that their total energy cost is zero. Other projects strive
for carbon neutrality, emitting no more carbon emissions than they can either sequester or offset. Still other
projects are designed to achieve a more even water balance: they use no more water than that which falls on
site as precipitation, or they produce zero waste by recycling, reusing, or composting all materials.

Not all projects can achieve those levels of performance. Nevertheless, on average, green buildings
save energy, use less water, generate less waste, and provide more healthful, more comfortable indoor
environments. Specific strategies will be discussed in Section 4 of this guide.

Getting to green and beyond requires more than learning about new technologies and strategies. It requires
more than learning to apply LEED checklists. Achieving true sustainability requires a new approach to
creating and caring for the built environment.

GREEN BUILDING EXPERTISE

Green building requires new skills and new knowledge, as well as new attitudes and new mindsets. In a linear
and hierarchical practice, each participant does his or her part and passes the job on to the next in line. There
is little interaction, and people are compartmentalized by discipline or profession. By contrast, the green
building process is interdisciplinary, iterative, and collaborative. Teamwork and critical thinking are valued.
Everyone needs to learn to ask the right questions and to participate in developing the solutions. Feedback
loops are built into the entire process.

The new skills required for a green building practice are not just knowledge of new strategies, materials, or
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equipment, although these are necessary. Green building practitioners need to learn how teams work, how
to facilitate or participate in a productive discussion, how to work with people with different backgrounds
and skills, and how to think outside their normal comfort zones when developing ideas. They need to
be able to understand an ecologist’s report on the proposed site, or better still, participate in walking
the site and contributing to the assessment. They need to be able to question one another—Why should
something be done the way it always has been done it in the past?—and then consider, what if…?

These are not skills and knowledge that most practitioners traditionally receive during their professional
education and training. Most architects, engineers, landscape architects, planners, and business managers
learn skills on the job and through trial and error, such as by facilitating meetings with team members and
stakeholders. These opportunities will be explored in greater depth in Section 3. Additionally, training
programs can help build these skills by combining experience with more formal classes, workshops, and
online education. University curricula are beginning to incorporate these skills, but it may be several years
before green expertise becomes the norm.

16
This guide is intended to set the foundation needed to develop green building expertise. A fresh perspective
will change the way you look at the buildings we all live and work in, the ones we walk past, and the ones we
revere as beacons of innovation in our communities. It will challenge you to imagine the next green building
project to which you’ll contribute.
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L EED CORE
L EED CON CEPTS GU ID E G—UIDE
T HIRD EDIR
ITD
I ON

Thinking
Sustainable
Section 2
Green building will change the way you think. Buildings that seem
to be individual, static objects will reveal themselves as fluid parts
of an environmental system that changes over time. Professionals
who appeared only distantly related will become partners in a
dynamic process that incoporates perspectives from different fields.

No problem can be solved from the same
level of consciousness that created it.
Albert Einstein

This section reviews three major concepts that are integral to green building and sustainability: systems
thinking, life-cycle thinking, and integrative processes. In systems thinking, the built environment is
understood as a series of relationships in which each part affects many other parts. Systems include
materials, resources, energy, people, and information, as well as the complex interactions and flows between
these elements across space and through time. Green building also requires taking a life-cycle approach,
looking at all stages of a project, product, or service. It requires asking, where do building materials and
resources come from? Where will they go once their useful life ends? What effects do they have on the world
along the way? Questions such as these encourage practitioners to ensure that buildings are adaptable and
resilient and perform as expected while minimizing harmful consequences. Finally, to achieve results that
are based on whole systems across their entire life-cycle, building professionals must adopt an integrative
process. This approach emphasizes connections and communication among professionals and stakeholders
throughout the life of a project. It breaks down disciplinary boundaries and rejects linear planning and
design processes that can lead to inefficient solutions. Although the term “integrative design” is most often
applied to new construction or renovations, an integrative process is applicable to any phase in the life-cycle
of a building.

In green building, solutions are examined through different perspectives, scales, and levels of detail, and
then refined. The lens of each discipline involved in a project contributes to an overall view that leads to
more effective designs. For example, sustainable neighborhood design strategies might be analyzed by
land-use planners, traffic engineers, civil engineers, infrastructure designers, public health experts, and
developers. The more each team member understands the perspectives and strategies of the others, the more
integrated the design. The iterative pattern of an integrative process can be used throughout the project as
details come into focus. Far from being time consuming, the process can actually save time by encouraging
communication up front and bringing people together for highly productive collaborative work sessions.
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 INTEGRATIVE DESIGN MEETS THE REAL WORLD
In the article “Integrated Design Meets the Real World,” the authors note that users of
an integrated approach “… got better at the process over time, especially when they
were able to work with the same team members more than once. Once they’d gone
through the process, they found it valuable, and many couldn’t imagine doing design
any other way.”14

This section addresses problem-solving approaches that can be applied throughout the green building
process. Subsequent sections will explore how green building professionals can begin to incorporate these
ideas into projects and professional pursuits.

SYSTEMS THINKING

Sustainability involves designing and operating systems to survive and thrive over time. To understand
sustainable systems, we must further understand what we mean by systems.

A system is an assemblage of elements or parts that interact in a series of relationships to form a complex
whole that serves particular functions or purposes. The theory behind systems thinking has had a profound
effect on many fields of study, such as computer science, business, psychology, and ecology. Donella
Meadows, Jørgen Randers, and Dennis Meadows, pioneers in the study of systems and sustainability,
describe this discipline in their book The Limits to Growth.

A system can be physically small (an ant hill) or large (the entire universe), simple and self-contained
(bacteria in a Petri dish) or complex and interacting with other systems (the global trading system or a forest
ecosystem). Systems rarely exist in isolation; even the bacteria in the Petri dish are affected by the light and
temperature of the laboratory. The boundaries of a system depend on what we are looking at, and most
systems are actually systems within systems. For example, the human body is made up of many interlinking
internal systems, such as the musculoskeletal system, which interact with external systems, such as the
natural environment.
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Our training taught us to see the world as a set of unfolding behavior patterns,
such as growth, decline, oscillation, overshoot. It has taught us to focus not so
much on single pieces of a system, as on connections. We see the elements
of demography, economy, and the environment as one planetary system, with
innumerable interconnections. We see stocks and flows and feedbacks and
interconnections, all of which influence the way the system will behave in the
future and influence the actions we might take to change its behavior.15

14 A. Wendt and N. Malin, Integrated Design Meets the Real World, Environmental Building News 19(5) (2010),
buildinggreen.com/articles/IssueTOC.cfm?Volume=19&Issue=5.
15 Donella H. Meadows, Dennis L. Meadows, Jorgen Randers, and William W. Behrens III. (1972). The Limits to Growth. New York:
Universe Books.

20
Many systems in the modern world are designed as open systems, into which materials and resources are
constantly brought in from the outside, used in some way, and then released outside the system in some
form of waste. For example, in most urban American communities, water, food, energy, and materials are
imported into the city from sources outside the municipal boundaries. In fact, many of our materials and
resources are imported from around the world. After they have been used inside the city, they are released
as waste in the form of sewage, solid waste, and pollution. In nature, there are no open systems; dead and
decaying matter become food for something else, and everything goes somewhere. There is no “away.”
By slowing the passing of materials and resources through the system and linking elements to form new
relationships and functions, we can begin to mimic nature and design closed systems, which are
more sustainable.

When designing buildings and communities, we must understand both the individual elements of the
system and their relationships to each other as a whole. One decision may have a ripple effect. For example,
improvements in the building envelope, the boundary between the exterior and interior elements of a
building, can change the requirements for the mechanical system. Using better insulation or more efficient
windows might allow for a smaller heating system. At the same time, reducing air infiltration can raise
concerns about the indoor air quality. Envelope design can also be used to increase daylight into the space,
affecting lighting design, heating, and air-conditioning as well as improving the quality of the indoor space.
But envelopes designed for increased daylighting without consideration of glare and heat gain can create
uncomfortable and less productive spaces. Even the interior finishes and furnishings can change the
effectiveness of natural daylighting and ventilation strategies.

Optimizing components in isolation
tends to pessimize the whole system—
and hence the bottom line. You can
actually make a system less efficient,
simply by not properly linking up those
components … If they’re not designed
to work with one another, they’ll tend to
work against one another.
Paul Hawken, Amory Lovins, and
L. Hunter Lovins Natural Capitalism

The concept of feedback loops helps explain how systems work. Feedback loops are the information flows
within a system that allow that system to organize itself. For example, when a thermostat indicates that
the temperature in a room is too warm, it sends a signal to turn on the air-conditioning. When the room is
sufficiently cooled, the thermostat sends a signal for the air-conditioning to stop.

This type of feedback loop is called a negative feedback loop because embedded in the system’s response
to a change is a signal for the system to stop changing when that response is no longer needed. Negative
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feedback loops enable a system to self-correct and stay within a particular range of function or performance.
Thus, they keep systems stable.

21
 Sensor Which raises the
temperature and
melts more snow

Fewer surfaces
remain covered
with snow
As the earth
When snow melts, gets warmer
the darker surfaces
Stimulus Counteraction absorb more heat

Figure 2.1. Negative Feedback Loop Figure 2.2. Positive Feedback Loop

POSITIVE FEEDBACK LOOPS, on the other hand, are self-reinforcing: the stimulus causes an effect, and
the effect produces even more of that same effect. Population growth is a positive feedback loop. The more
babies who are born, the more people there will be in the population to have more babies. Therefore, the
population can be expected to rise until acted upon by another force, such as an epidemic or shortage
of resources.

In the built environment, roads and infrastructure built out to the urban fringe often result in a positive
feedback loop of increased development. This suburban growth can sprawl far from the urban core, requiring
more roads and encouraging additional growth, as well as using more resources (energy, water, sewage
systems, materials) to support that growth.

Climate change is another positive feedback loop. As the earth gets warmer, fewer surfaces remain covered
with snow, a reflective surface that bounces incoming heat from the sun back into space. When snow melts,
the darker surfaces absorb more heat, which raises the temperature and melts more snow. Similarly, in the
built environment, the dark surfaces of roofs, roads, and parking lots absorb more heat from the sun. This
heat island effect raises temperatures in urban areas several degrees above the temperature of surrounding
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areas, increasing the demand for cooling and the amount of energy that buildings use. The additional energy
use can increase carbon emissions, which contribute to global warming, further raising urban temperatures
and energy use, and the cycle continues.

22
 Figure 2.3. Induced Growth Over Time

Unchecked, positive feedback loops can create chaos in a system. For example, if urban temperatures rise
too high, local populations may suffer or abandon the area. In nature, positive feedback loops are typically
checked by stabilizing negative feedback loops, processes that shut down uncontrolled growth or other
destabilizing forces. Stability and resilience in the system return as the feedback loops begin to control the
change. To design sustainable systems, we must understand the positive and negative feedback loops already
in existence or those we set in motion, to ensure systems remain stable and habitable over time.

Feedback loops—positive or negative—depend on flows of information. When information about the
performance of the system is missing or blocked, the system cannot respond. For example, buildings without
appropriate sensors and control systems cannot adjust to changing temperatures and maintain a comfortable
indoor environment. The information must be both collected and directed. Most buildings have thermostats
to provide information and control temperature. However, there are many other parameters, measurable or
quantifiable characteristics of a system, that are relevant to sustainability but do not get measured or reported
in effective ways. For example, the amount of energy used by tenant-occupied buildings may be collected
by an electricity or gas meter and reported to the utility company but not to the occupants, who therefore
have no information about their energy consumption and no incentive to reduce it. If real-time information
on energy use is delivered to them in a convenient way, they can use energy more efficiently. Some have
called this the Prius effect, after the hybrid car that gives drivers information about fuel consumption so
that they can drive in a fuel-efficient way.16 Installing real-time energy meters where operators can act on the
information is an example of connecting elements of a system so that they can interact and respond to each
other more appropriately in the feedback loop.
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16 Brand Neutral, The Prius Effect: Learning from Toyota (2007), brandneutral.com/documents/Prius_Effect.pdf.

23
 THE PRIUS EFFECT
Delivering real-time energy information in a convenient way by installing meters
where operators can act on the information and make changes to use energy
more efficiently.

In addition to elements, their relationships, and the feedback loops among them, systems theory explores
the emergent properties of a system—patterns that emerge from the system as a whole and are more than
the sum of the parts. For example, the pattern of waves crashing along the beach is an emergent property:
the pattern is more than the water molecules that make up the ocean, more than the surface of the shore,
more than the gravitational pull of the moon or the influence of the wind. The waves emerge as a result of the
interactions and relationships among the elements.

Similarly, the culture of a company emerges from the people who work there, the buildings in which they
work, the services or products they provide, the way they receive and process information, the management
and power structure, and the financial structure. These elements and flows combine in both predictable
and unpredictable ways to form a unique and individual organization. The elements of the system
(people, buildings), the flows within the system (of materials, money, and information), the rules that
govern those flows (management and structures), and the functions of the system (providing goods or
services, generating a profit) determine whether the company is a good place to work and will be
sustainable over time.

To influence the behavior of a system, it is important to find the leverage points—places where a small
intervention can yield large changes. Providing building occupants with real-time energy information is an
example of using a leverage point to alter behavior. Rather than changing the elements of the system—the
envelope of the structure, the mechanical system, the building occupants, the electricity grid—the change
focuses merely on delivering available data to a point where it can be acted on appropriately. This minor
tweak can dramatically raise the efficiency of the system. Donella Meadows’s essay “Leverage Points: Places
to Intervene in a System” provides an excellent summary of how to find and use leverage points to make
meaningful change.17
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In Natural Capitalism, Hawkens, Lovins, and Lovins explore how capital markets can be used for—rather
than against—sustainability, not by eliminating them or adding intensive regulation, but by using leverage
points within the system. One leverage point they examine is the goals that govern the system. By valuing
not only financial capital but also natural capital and human capital, existing systems and structures can lead
to sustainability.

17 D. Meadows, Leverage Points: Places to Intervene in a System (1999), sustainer.org/pubs/Leverage_Points.pdf.

24
PROJECT CASE STUDY

CANNON DESIGN CHICAGO OFFICE RELOCATION
LEED PLATINUM

Cannon Design’s Chicago office, certified under LEED for Commercial Interiors, relocated to Michigan Plaza, two
adjacent mixed-use office towers in Chicago’s central business district. The company’s former longtime home
spread employees and operations across four different floors, so this move marked a watershed: for the first
time Chicago office employees are now able to occupy a single, contiguous 60,000 square foot floor that spans
two buildings. Ultimately, this is a workplace designed to benefit the people that work in it. Prior to relocating
to this space, the project team conducted an online survey open to all employees to estimate the percentage
of time employees dedicated to formal and informal collaboration, learning, personal head-down work time
and socialization. The space plan for the project responded to needs identified in this survey. In all, the design
incorporates twenty different workplace setting types to encourage all employees to work in the manner that
best suits each individual’s style and the task at hand. Canon Design also valued an energy-efficient space, and
used the site selection process to achieve their goals—the chosen building is certified under ENERGY STAR and
achieved Gold under the LEED O+M rating system.
An interactive sustainability reporting dashboard occupies a prominent space in the heart of the office,
immediately adjacent to the library and central gathering space. This dashboard tracks real-time energy
consumption within the office and also displays other key annual environmental measures for the office,
including waste management, water consumption and vehicle miles traveled. To learn more about the Cannon
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Design Chicago office visit usgbc.org/projects/cannon-design-chicago-office-relocation

Photo by Christopher Barrett 25
 LEVERAGE POINTS
Places to Intervene in a System (in increasing order of effectiveness):
12. Constant, parameters, numbers (such as subsidies, taxes, standards)
11. The sizes of buffers and other stabilizing stocks, relative to their flows
10. The structure of material stocks and flows (such as transport networks, population
age structures)
9. The lengths of delays, relative to the rate of system change
8. The strength of negative feedback loops, relative to the impacts they are trying to
correct against
7. The gain around driving positive feedback loops
6. The structure of information flows (who does and does not have access to what kinds
of information)
5. The rules of the system (such as incentives, punishments, constraints)
4. The power to add, change, evolve, or self-organize system structure
3. The goals of the system
2. The mindset or paradigm out of which the system—its goals, structure, rules, delays,
parameters—arises
1. The power to transcend paradigms

For instance, when carpet manufacturer Interface Flooring switched from being a producer of carpet to a
provider of the service of floor coverings, it created a shift in the company’s mission. Instead of buying carpet,
customers could buy the service of the carpet, which would be owned by Interface. The company would be
responsible for maintaining the carpet over time, replacing worn areas, and disposing of any “waste.” This
shift served as a leverage point to enable the company system to change radically toward sustainability,
reducing waste, and improving performance
of the product while maintaining profit.
In other words, Interface Flooring moved Building Envelope
System
from an open system to a closed system.
The new mental model resulted not just
in more efficient processes, but also in a Dehumidification
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System
radical restructuring of the company and
all its operations.
HVAC
System
Buildings are part of a world of nested systems
that affect and are affected by one another.
Once the project team understands the
Electrical
network of systems that affect a given project, System
the energy and matter that flow through
the systems, and the relationships and
interdependencies that exist, the deeper
Figure 2.4. Nested Systems
and more effectively integration can occur.

26
When designing aspects of the built environment, consider the systems in which the project will be located
and the systems the project will create. Learn about the relationships between the elements, the flows of
resources and information, and the leverage points that can lead to dramatic changes. Before starting any
project, the team can explore these systems by asking questions. Whether working in the planning, design,
construction, or operations phase, these questions may provide insight into the systems context and ways to
move more fully toward sustainability in an integrated way.

QUESTIONS A PROJECT TEAM NEEDS TO EXPLORE AS
MEMBERS BEGIN WORKING TOGETHER, INCLUDE:
Where is the project located, and who are its neighbors—locally, regionally, and
beyond? What is the local watershed? The bioregion? What are the characteristics of
these systems?
How do resources, such as energy, water, and materials, flow into the project? Where
do they come from, and from how far away? What other purposes or projects do
those flows serve?
What natural processes are at work on the site? How do resources, such as rainwater,
wastewater, and solid waste, flow out of the system? Where do they go? Are there
places on site where these flows can be captured, stored, or reused?
What are the goals of the owner? What is the function or purpose of the project?
How will the project meet those goals?
What is the community within the project? Who are the people who come here, and
where do they come from? Where do they go? What brings them together, and what
might keep them apart? How will the project change their interactions?
How does the project community interact with other, overlapping communities?
What are the interrelationships? Are there sources of conflicts? What is the
economic system within the project? How does it fit into larger or overlapping
economic systems?
What are the leverage points within the system? Are there places where small
changes can produce big results?

In a linear design process, the solutions to one problem may cause other problems elsewhere in the system.
When problems are solved through a systems-based approach, multiple problems can often be solved at the
same time. This synergy is possible when we take the time to explore the interconnections and approach a
project in a holistic manner. In the context of the built environment, systems thinking allows us to explore
and support the rich i