Reducing Stormwater Costs through Low Impact
Development (LID) Strategies and Practices
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Reducing Stormwater Costs through Low Impact
Development (LID) Strategies and Practices
December 2007
EPA841-F-07-006
Prepared under Contract No. 68-C-02-108
United States Environmental Protection Agency
Nonpoint Source Control Branch (4503T)
1200 Pennsylvania Ave., NW
Washington, DC 20460
Available for download at www.epa.gov/nps/lid
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CONTENTS
Contents i
Tables ii
Foreword iii
Executive Summary iv
Introduction 1
Background 1
Low Impact Development 2
Evaluations of Benefits and Costs 6
Overview of Benefits 6
Environmental Benefits 7
Land Value and Quality of Life Benefits 8
Compliance Incentives 9
Cost Considerations 9
Case Studies 11
2nd Avenue SEA Street, Seattle, Washington 12
Auburn Hills Subdivision, Southwestern Wisconsin 13
Bellingham, Washington, Parking Lot Retrofits 14
Central Park Commercial Redesigns, Fredericksburg, VA (A Modeling Study) 15
Crown Street, Vancouver, British Columbia 15
Gap Creek Subdivision, Sherwood, Arkansas 17
Garden Valley, Pierce County, Washington (A Modeling Study) 17
Kensington Estates, Pierce County, Washington (A Modeling Study) 18
Laurel Springs Subdivision, Jackson, Wisconsin 19
Mill Creek Subdivision, Kane County, Illinois 20
Poplar Street Apartments, Aberdeen, North Carolina 21
Portland Downspout Disconnection Program, Portland, Oregon 21
Prairie Crossing Subdivision, Grayslake, Illinois 22
Prairie Glen Subdivision, Germantown, Wisconsin 23
Somerset Subdivision, Prince George's County, Maryland 24
Tellabs Corporate Campus, Naperville, Illinois 25
Toronto Green Roofs, Toronto, Ontario (A Modeling Study) 26
Conclusion 27
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TABLES
Table 1. Summary of LID Practices Employed in the Case Studies 11
Table 2. Summary of Cost Comparisons Between Conventional and LID Approaches 12
Table 3. Cost Comparison for 2nd Avenue SEA Street 13
Table 4. Cost Comparison for Auburn Hills Subdivision 14
Table 5. Cost Comparison for Bellingham's Parking Lot Rain Garden Retrofits 14
Table 6. Site Information and Cost Additions/Reductions Using LID Versus Traditional Designs 15
Table 7. Cost Comparison for Gap Creek Subdivision 17
Table 8. Cost Comparison for Garden Valley Subdivision 18
Table 9. Cost Comparison for Kensington Estates Subdivision 18
Table 10. Cost Comparison for Laurel Springs Subdivision 19
Table 11. Cost Comparison for Mill Creek Subdivision 20
Table 12. Cost Comparison for Prairie Crossing Subdivision 22
Table 13. Cost Comparison for Prairie Glen Subdivision 23
Table 14. Cost Comparison for Somerset Subdivision 24
Table 15. Cost Comparison for Tellabs Corporate Campus 25
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FOREWORD
One of the most exciting new trends in water quality management today is the movement
by many cities, counties, states, and private-sector developers toward the increased use of
Low Impact Development (LID) to help protect and restore water quality. LID comprises
a set of approaches and practices that are designed to reduce runoff of water and
pollutants from the site at which they are generated. By means of infiltration,
evapotranspiration, and reuse of rainwater, LID techniques manage water and water
pollutants at the source and thereby prevent or reduce the impact of development on
rivers, streams, lakes, coastal waters, and ground water.
Although the increase in application of these practices is growing rapidly, data regarding
both the effectiveness of these practices and their costs remain limited. This document is
focused on the latter issue, and the news is good. In the vast majority of cases, the U.S.
Environmental Protection Agency (EPA) has found that implementing well-chosen LID
practices saves money for developers, property owners, and communities while
protecting and restoring water quality.
While this study focuses on the cost reductions and cost savings that are achievable
through the use of LID practices, it is also the case that communities can experience
many amenities and associated economic benefits that go beyond cost savings. These
include enhanced property values, improved habitat, aesthetic amenities, and improved
quality of life. This study does not monetize and consider these values in performing the
cost calculations, but these economic benefits are real and significant. For that reason,
EPA has included a discussion of these economic benefits in this document and provided
references for interested readers to learn more about them.
Readers interested in increasing their knowledge about LID and Green Infrastructure,
which encompasses LID along with other aspects of green development, should see
www.epa.gov/npdes/greeninfrastructure and www.epa.gov/nps/lid. It is EPA's hope that
as professionals and citizens continue to become more knowledgeable about the
effectiveness and costs of LID, the use of LID practices will continue to increase at a
rapid pace.
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EXECUTIVE SUMMARY
This report summarizes 17 case studies of developments that include Low Impact Development
(LID) practices and concludes that applying LID techniques can reduce project costs and improve
environmental performance. In most cases, LID practices were shown to be both fiscally and
environmentally beneficial to communities. In a few cases, LID project costs were higher than
those for conventional stormwater management practices. However, in the vast majority of cases,
significant savings were realized due to reduced costs for site grading and preparation,
stormwater infrastructure, site paving, and landscaping. Total capital cost savings ranged from 15
to 80 percent when LID methods were used, with a few exceptions in which LID project costs
were higher than conventional stormwater management costs.
EPA has identified several additional areas that will require further study. First, in all cases, there
were benefits that this study did not monetize and did not factor into the project's bottom line.
These benefits include improved aesthetics, expanded recreational opportunities, increased
property values due to the desirability of the lots and their proximity to open space, increased
total number of units developed, increased marketing potential, and faster sales. Second, more
research is also needed to quantify the environmental benefits that can be achieved through the
use of LID techniques and the costs that can be avoided. Examples of environmental benefits
include reduced runoff volumes and pollutant loadings to downstream waters, and reduced
incidences of combined sewer overflows. Finally, more research is needed to monetize the cost
reductions that can be achieved through improved environmental performance, reductions in
long-term operation and maintenance costs, and/or reductions in the life cycle costs of replacing
or rehabilitating infrastructure.
IV
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INTRODUCTION
BACKGROUND
Most storm water runoff is the result of the man-made hydrologic modifications that
normally accompany development. The addition of impervious surfaces, soil
compaction, and tree and vegetation removal result in alterations to the movement of
water through the environment. As interception, evapotranspiration, and infiltration are
reduced and precipitation is converted to overland flow, these modifications affect not
only the characteristics of the developed site but also the watershed in which the
development is located. Storm water has been identified as one of the leading sources of
pollution for all waterbody types in the United States. Furthermore, the impacts of
stormwater pollution are not static; they usually increase with more development and
urbanization.
Extensive development in the United States is a relatively recent phenomenon. For the
past two decades, the rate of land development across the country has been twice the rate
of population growth. Approximately 25 million acres were developed between 1982 and
1997, resulting in a 34 percent increase in the amount of developed land with only a 15
percent increase in population.1'2 The 25 million acres developed during this 15-year
period represent nearly 25 percent of the total amount of developed land in the
contiguous states. The U.S. population is expected to increase by 22 percent from 2000 to
2025. If recent development trends continue, an additional 68 million acres of land will
be developed during this 25-year period.3
Water quality protection strategies are often implemented at three scales: the region or
large watershed area, the community or neighborhood, and the site or block. Different
stormwater approaches are used at different scales to afford the greatest degree of
protection to waterbodies because the influences of pollution are often found at all three
scales. For example, decisions about where and how to grow are the first and perhaps
most important decisions related to water quality. Growth and development can give a
community the resources needed to revitalize a downtown, refurbish a main street, build
new schools, and develop vibrant places to live, work, shop, and play. The environmental
impacts of development, however, can pose challenges for communities striving to
protect their natural resources. Development that uses land efficiently and protects
undisturbed natural lands allows a community to grow and still protect its water
resources.
Strategies related to these broad growth and development issues are often implemented at
the regional or watershed scale. Once municipalities have determined where to grow and
where to preserve, various stormwater management techniques are applied at the
neighborhood or community level. These measures, such as road width requirements,
often transcend specific development sites and can be applied throughout a
neighborhood. Finally, site-specific stormwater strategies, such as rain gardens and
infiltration areas, are incorporated within a particular development. Of course, some
stormwater management strategies can be applied at several scales. For example,
opportunities to maximize infiltration can occur at the neighborhood and site levels.
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Many smart growth approaches can decrease the overall amount of impervious cover
associated with a development's footprint. These approaches include directing
development to already degraded land; using narrower roads; designing smaller parking
lots; integrating retail, commercial, and residential uses; and designing more compact
residential lots. These development approaches, combined with other techniques aimed at
reducing the impact of development, can offer communities superior stormwater
management.
Stormwater management programs have struggled to provide adequate abatement and
treatment of stormwater at the current levels of development. Future development will
create even greater challenges for maintaining and improving water quality in the
nation's waterbodies. The past few decades of stormwater management have resulted in
the current convention of control-and-treatment strategies. They are largely engineered,
end-of-pipe practices that have been focused on controlling peak flow rate and suspended
solids concentrations. Conventional practices, however, fail to address the widespread
and cumulative hydrologic modifications within the watershed that increase stormwater
volumes and runoff rates and cause excessive erosion and stream channel degradation.
Existing practices also fail to adequately treat for other pollutants of concern, such as
nutrients, pathogens, and metals.
Low IMPACT DEVELOPMENT
Low Impact Development (LID)4 is a stormwater management strategy that has been
adopted in many localities across the country in the past several years. It is a stormwater
management approach and set of practices that can be used to reduce runoff and pollutant
loadings by managing the runoff as close to its source(s) as possible. A set or system of
small-scale practices, linked together on the site, is often used. LID approaches can be
used to reduce the impacts of development and redevelopment activities on water
resources. In the case of new development, LID is typically used to achieve or pursue the
goal of maintaining or closely replicating the predevelopment hydrology of the site. In
areas where development has already occurred, LID can be used as a retrofit practice to
reduce runoff volumes, pollutant loadings, and the overall impacts of existing
development on the affected receiving waters.
In general, implementing integrated LID practices can result in enhanced environmental
performance while at the same time reducing development costs when compared to
traditional stormwater management approaches. LID techniques promote the use of
natural systems, which can effectively remove nutrients, pathogens, and metals from
stormwater. Cost savings are typically seen in reduced infrastructure because the total
volume of runoff to be managed is minimized through infiltration and evapotranspiration.
By working to mimic the natural water cycle, LID practices protect downstream
resources from adverse pollutant and hydrologic impacts that can degrade stream
channels and harm aquatic life.
It is important to note that typical, real-world LID designs usually incorporate more than
one type of practice or technique to provide integrated treatment of runoff from a site. For
example, in lieu of a treatment pond serving a new subdivision, planners might
incorporate a bioretention area in each yard, disconnect downspouts from driveway
surfaces, remove curbs, and install grassed swales in common areas. Integrating small
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practices throughout a site instead of using extended detention wet ponds to control
runoff from a subdivision is the basis of the LID approach.
When conducting cost analyses of these practices, examples of projects where actual
practice-by-practice costs were considered separately were found to be rare because
material and labor costs are typically calculated for an entire site rather than for each
element within a larger system. Similarly, it is difficult to calculate the economic benefits
of individual LID practices on the basis of their effectiveness in reducing runoff volume
and rates or in treating pollutants targeted for best management practice (BMP)
performance monitoring.
The following is a summary of the different categories of LID practices, including a brief
description and examples of each type of practice.
Examples of Conservation
Design
Cluster development
Open space preservation
Reduced pavement widths
(streets, sidewalks)
Shared driveways
Reduced setbacks (shorter
driveways)
Site fingerprinting during
construction
Conservation designs can be used to minimize the
generation of runoff by preserving open space. Such
designs can reduce the amount of impervious surface,
which can cause increased runoff volumes. Open
space can also be used to treat the increased runoff
from the built environment through infiltration or
evapotranspiration. For example, developers can use
conservation designs to preserve important features
on the site such as wetland and riparian areas,
forested tracts, and areas of porous soils.
Development plans that outline the smallest site
disturbance area can minimize the stripping of topsoil
and compaction of subsoil that result from grading
and equipment use. By preserving natural areas and
not clearing and grading the entire site for housing lots, less total runoff is generated on
the development parcel. Such simplistic, nonstructural methods can reduce the need to
build large structural runoff controls like retention ponds and storm water conveyance
systems and thereby decrease the overall infrastructure costs of the project. Reducing the
total area of impervious surface by limiting road widths, parking area, and sidewalks can
also reduce the volume of runoff that must be treated. Residential developments that
incorporate conservation design principles also can benefit residents and their quality of
life due to increased access and proximity to communal open space, a greater sense of
community, and expanded recreational opportunities.
Infiltration practices are engineered structures or
landscape features designed to capture and infiltrate
runoff. They can be used to reduce both the volume
of runoff discharged from the site and the
infrastructure needed to convey, treat, or control
runoff. Infiltration practices can also be used to
recharge ground water. This benefit is especially
important in areas where maintaining drinking water
supplies and stream baseflow is of special concern
because of limited precipitation or a high ratio of
withdrawal to recharge rates. Infiltration of runoff can also help to maintain stream
temperatures because the infiltrated water that moves laterally to replenish stream
baseflow typically has a lower temperature than overland flows, which might be subject
Examples of Infiltration
Practices
Infiltration basins and trenches
Porous pavement
Disconnected downspouts
Rain gardens and other
vegetated treatment systems
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to solar radiation. Another advantage of infiltration practices is that they can be integrated
into landscape features in a site-dispersed manner. This feature can result in aesthetic
benefits and, in some cases, recreational opportunities; for example, some infiltration
areas can be used as playing fields during dry periods.
Examples of Runoff Storage
Practices
Parking lot, street, and sidewalk
storage
Rain barrels and cisterns
Depressional storage in
landscape islands and in tree,
shrub, or turf depressions
Green roofs
Runoff storage practices. Impervious surfaces are a
central part of the built environment, but runoff from
such surfaces can be captured and stored for reuse or
gradually infiltrated, evaporated, or used to irrigate
plants. Using runoff storage practices has several
benefits. They can reduce the volume of runoff
discharged to surface waters, lower the peak flow
hydrograph to protect streams from the erosive forces
of high flows, irrigate landscaping, and provide
aesthetic benefits such as landscape islands, tree
boxes, and rain gardens. Designers can take
advantage of the void space beneath paved areas like parking lots and sidewalks to
provide additional storage. For example, underground vaults can be used to store runoff
in both urban and rural areas.
Runoff conveyance practices. Large storm events
can make it difficult to retain all the runoff generated
on-site by using infiltration and storage practices. In
these situations, conveyance systems are typically
used to route excess runoff through and off the site.
In LID designs, conveyance systems can be used to
slow flow velocities, lengthen the runoff time of
concentration, and delay peak flows that are
discharged off-site. LID conveyance practices can be
used as an alternative to curb-and-gutter systems, and
from a water quality perspective they have
advantages over conventional approaches designed to
rapidly convey runoff off-site and alleviate on-site
flooding. LID conveyance practices often have rough
surfaces, which slow runoff and increase evaporation and settling of solids. They are
typically permeable and vegetated, which promotes infiltration, filtration, and some
biological uptake of pollutants. LID conveyance practices also can perform functions
similar to those of conventional curbs, channels, and gutters. For example, they can be
used to reduce flooding around structures by routing runoff to landscaped areas for
treatment, infiltration, and evapotranspiration.
Examples of Runoff
Conveyance Practices
Eliminating curbs and gutters
Creating grassed swales and
grass-lined channels
Roughening surfaces
Creating long flow paths over
landscaped areas
Installing smaller culverts,
pipes, and inlets
Creating terraces and check
dams
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Examples of Filtration
Practices
Bioretention/rain gardens
Vegetated swales
Vegetated filter strips/buffers
Filtration practices are used to treat runoff by
filtering it through media that are designed to
capture pollutants through the processes of physical
filtration of solids and/or cation exchange of
dissolved pollutants. Filtration practices offer many
of the same benefits as infiltration, such as
reductions in the volume of runoff transported off-
site, ground water recharge, increased stream
baseflow, and reductions in thermal impacts to receiving waters. Filtration practices also
have the added advantage of providing increased pollutant removal benefits. Although
pollutant build-up and removal may be of concern, pollutants are typically captured in the
upper soil horizon and can be removed by replacing the topsoil.
Low impact landscaping. Selection and distribution
of plants must be carefully planned when designing a
functional landscape. Aesthetics are a primary
concern, but it is also important to consider long-term
maintenance goals to reduce inputs of labor, water,
and chemicals. Properly preparing soils and selecting
species adapted to the microclimates of a site greatly
increases the success of plant establishment and
growth, thereby stabilizing soils and allowing for
biological uptake of pollutants. Dense, healthy plant
growth offers such benefits as pest resistance
(reducing the need for pesticides) and improved soil
infiltration from root growth. Low impact
landscaping can thus reduce impervious surfaces,
improve infiltration potential, and improve the
aesthetic quality of the site.
Examples of Low Impact
Landscaping
Planting native, drought-
tolerant plants
Converting turf areas to shrubs
and trees
Reforestation
Encouraging longer grass
length
Planting wildflower meadows
rather than turf along medians
and in open space
Amending soil to improve
infiltration
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EVALUATIONS OF BENEFITS AND COSTS
To date, the focus of traditional stormwater management programs has been concentrated
largely on structural engineering solutions to manage the hydraulic consequences of the
increased runoff that results from development. Because of this emphasis, stormwater
management has been considered primarily an engineering endeavor. Economic analyses
regarding the selection of solutions that are not entirely based on pipes and ponds have
not been a significant factor in management decisions. Where costs have been
considered, the focus has been primarily on determining capital costs for conventional
infrastructure, as well as operation and maintenance costs in dollars per square foot or
dollars per pound of pollutant removed.
Little attention has been given to the benefits that can be achieved through implementing
LID practices. For example, communities rarely attempt to quantify and monetize the
pollution prevention benefits and avoided treatment costs that might accrue from the use
of conservation designs or LID techniques. To be more specific, the benefits of using LID
practices to decrease the need for combined sewer overflow (CSO) storage and
conveyance systems should be factored into the economic analyses. One of the major
factors preventing LID practices from receiving equal consideration in the design or
selection process is the difficulty of monetizing the environmental benefits of these
practices. Without good data and relative certainty that these alternatives will work and
not increase risk or cost, current standards of practice are difficult to change.
This report is an effort to compare the projected or known costs of LID practices with
those of conventional development approaches. At this point, monetizing the economic
and environmental benefits of LID strategies is much more difficult than monetizing
traditional infrastructure costs or changes in property values due to improvements in
existing utilities or transportation systems. Systems of practices must be analyzed to
determine net performance and monetary benefits based on the capacity of the systems to
both treat for pollutants and reduce impacts through pollution prevention. For example,
benefits might come in the form of reduced stream channel degradation, avoided stream
restoration costs, or reduced drinking water treatment costs.
One of the chief impediments to getting useful economic data to promote more
widespread use of LID techniques is the lack of a uniform baseline with which to
compare the costs and benefits of LID practices against the costs of conventional
stormwater treatment and control. Analyzing benefits is further complicated in cases
where the environmental performance of the conservation design or LID system exceeds
that of the conventional runoff management system, because such benefits are not easily
monetized. The discussion below is intended to provide a general discussion of the range
of economic benefits that may be provided by LID practices in a range of appropriate
circumstances.
OVERVIEW OF BENEFITS
The following is a brief discussion of some of the actual and assumed benefits of LID
practices. Note that environmental and ancillary benefits typically are not measured as
part of development projects, nor are they measured as part of pilot or demonstration
projects, because they can be difficult to isolate and quantify. Many of the benefits
described below are assumed on the basis of limited studies and anecdotal evidence.
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The following discussion is organized into three categories: (1) environmental benefits,
which include reductions in pollutants, protection of downstream water resources, ground
water recharge, reductions in pollutant treatment costs, reductions in the frequency and
severity of CSOs, and habitat improvements; (2) land value benefits, which include
reductions in downstream flooding and property damage, increases in real estate value,
increased parcel lot yield, increased aesthetic value, and improvement of quality of life
by providing open space for recreation; and (3) compliance incentives.
Environmental Benefits
Pollution abatement. LID practices can reduce both the volume of runoff and the
pollutant loadings discharged into receiving waters. LID practices result in pollutant
removal through settling, filtration, adsorption, and biological uptake. Reductions in
pollutant loadings to receiving waters, in turn, can improve habitat for aquatic and
terrestrial wildlife and enhance recreational uses. Reducing pollutant loadings can also
decrease storm water and drinking water treatment costs by decreasing the need for
regional stormwater management systems and expansions in drinking water treatment
systems.
Protection of downstream water resources. The use of LID practices can help to prevent
or reduce hydrologic impacts on receiving waters, reduce stream channel degradation
from erosion and sedimentation, improve water quality, increase water supply, and
enhance the recreational and aesthetic value of our natural resources. LID practices can
be used to protect water resources that are downstream in the watershed. Other potential
benefits include reduced incidence of illness from contact recreation activities such as
swimming and wading, more robust and safer seafood supplies, and reduced medical
treatment costs.
Ground water recharge. LID practices also can be used to infiltrate runoff to recharge
ground water. Growing water shortages nationwide increasingly indicate the need for
water resource management strategies designed to integrate stormwater, drinking water,
and wastewater programs to maximize benefits and minimize costs. Development
pressures typically result in increases in the amount of impervious surface and volume of
runoff. Infiltration practices can be used to replenish ground water and increase stream
baseflow. Adequate baseflow to streams during dry weather is important because low
ground water levels can lead to greater fluctuations in stream depth, flows, and
temperatures, all of which can be detrimental to aquatic life.
Water quality improvements/reduced treatment costs. It is almost always less expensive
to keep water clean than it is to clean it up. The Trust for Public Land5 noted Atlanta's
tree cover has saved more than $883 million by preventing the need for stormwater
retention facilities. A study of 27 water suppliers conducted by the Trust for Public Land
and the American Water Works Association6 found a direct relationship between forest
cover in a watershed and water supply treatment costs. In other words, communities with
higher percentages of forest cover had lower treatment costs. According to the study,
approximately 50 to 55 percent of the variation in treatment costs can be explained by the
percentage of forest cover in the source area. The researchers also found that for every 10
percent increase in forest cover in the source area, treatment and chemical costs
decreased approximately 20 percent, up to about 60 percent forest cover.
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Reduced incidence ofCSOs. Many municipalities have problems with CSOs, especially
in areas with aging infrastructure. Combined sewer systems discharge sanitary
wastewater during storm events. LID techniques, by retaining and infiltrating runoff,
reduce the frequency and amount of CSO discharges to receiving waters. Past
management efforts typically have been concentrated on hard engineering approaches
focused on treating the total volume of sanitary waste together with the runoff that is
discharged to the combined system. Recently, communities like Portland (Oregon),
Chicago, and Detroit have been experimenting with watershed approaches aimed at
reducing the total volume of runoff generated that must be handled by the combined
system. LID techniques have been the primary method with which they have
experimented to reduce runoff. A Hudson Riverkeeper report concluded, based on a
detailed technical analysis, that New York City could reduce its CSO's more cost-
effectively with LID practices than with conventional, hard infrastructure CSO storage
practices.7
Habitat improvements. Innovative storm water management techniques like LID or
conservation design can be used to improve natural resources and wildlife habitat,
maintain or increase land value, or avoid expensive mitigation costs.
Land Value and Quality of Life Benefits
Reduced downstream flooding and property damage. LID practices can be used to
reduce downstream flooding through the reduction of peak flows and the total amount or
volume of runoff. Flood prevention reduces property damage and can reduce the initial
capital costs and the operation and maintenance costs of storm water infrastructure.
Strategies designed to manage runoff on-site or as close as possible to its point of
generation can reduce erosion and sediment transport as well as reduce flooding and
downstream erosion. As a result, the costs for cleanups and streambank restoration can be
reduced or avoided altogether. The use of LID techniques also can help protect or restore
floodplains, which can be used as park space or wildlife habitat.8
Real estate value/property tax revenue. Homeowners and property owners are willing to
pay a premium to be located next to or near aesthetically pleasing amenities like water
features, open space, and trails. Some storm water treatment systems can be beneficial to
developers because they can serve as a "water" feature or other visual or recreational
amenity that can be used to market the property. These designs should be visually
attractive and safe for the residents and should be considered an integral part of planning
the development. Various LID projects and smart growth studies have shown that people
are willing to pay more for clustered homes than conventionally designed subdivisions.
Clustered housing with open space appreciated at a higher rate than conventionally
designed subdivisions. EPA's Economic Benefits of Runoff Controls9 describes numerous
examples where developers and subsequent homeowners have received premiums for
proximity to attractive stormwater management practices.
Lot yield. LID practices typically do not require the large, contiguous areas of land that
are usually necessary when traditional stormwater controls like ponds are used. In cases
where LID practices are incorporated on individual house lots and along roadsides as part
of the landscaping, land that would normally be dedicated for a stormwater pond or other
large structural control can be developed with additional housing lots.
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Aesthetic value. LID techniques are usually attractive features because landscaping is an
integral part of the designs. Designs that enhance a property's aesthetics using trees,
shrubs, and flowering plants that complement other landscaping features can be selected.
The use of these designs may increase property values or result in faster sale of the
property due to the perceived value of the "extra" landscaping.
Public spaces/quality of life/public participation. Placing water quality practices on
individual lots provides opportunities to involve homeowners in stormwater management
and enhances public awareness of water quality issues. An American Lives, Inc., real
estate study found that 77.7 percent of potential homeowners rated natural open space as
"essential" or "very important" in planned communities.10
Compliance Incentives
Regulatory compliance credits. Many states recognize the positive benefits LID
techniques offer, such as reduced wetland impacts. As a result, they might offer
regulatory compliance credits, streamlined or simpler permit processes, and other
incentives similar to those offered for other green practices. For example, in Maryland
the volume required for the permanent pool of a wet pond can be reduced if rooftop
runoff is infiltrated on-site using LID practices. This procedure allows rooftop area to be
subtracted from the total impervious area, thereby reducing the required size of the
permanent pool. In addition, a LID project can have less of an environmental impact than
a conventional project, thus requiring smaller impact fees.
COST CONSIDERATIONS
Traditional approaches to stormwater management involve conveying runoff off-site to
receiving waters, to a combined sewer system, or to a regional facility that treats runoff
from multiple sites. These designs typically include hard infrastructure, such as curbs,
gutters, and piping. LID-based designs, in contrast, are designed to use natural drainage
features or engineered swales and vegetated contours for runoff conveyance and
treatment. In terms of costs, LID techniques like conservation design can reduce the
amount of materials needed for paving roads and driveways and for installing curbs and
gutters. Conservation designs can be used to reduce the total amount of impervious
surface, which results in reduced road and driveway lengths and reduced costs. Other
LID techniques, such as grassed swales, can be used to infiltrate roadway runoff and
eliminate or reduce the need for curbs and gutters, thereby reducing infrastructure costs.
Also, by infiltrating or evaporating runoff, LID techniques can reduce the size and cost of
flood-control structures. Note that more research is needed to determine the optimal
combination of LID techniques and detention practices for flood control.
It must be stated that the use of LID techniques might not always result in lower project
costs. The costs might be higher because of the costs of plant material, site preparation,
soil amendments, underdrains and connections to municipal stormwater systems, and
increased project management.
Another factor to consider when comparing costs between traditional and LID designs is
the amount of land required to implement a management practice. Land must be set aside
for both traditional stormwater management practices and LID practices, but the former
require the use of land in addition to individual lots and other community areas, whereas
bioretention areas and swales can be incorporated into the landscaping of yards, in rights-
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of-way along roadsides, and in or adjacent to parking lots. The land that would have been
set aside for ponds or wetlands can in many cases be used for additional housing units,
yielding greater profits.
Differences in maintenance requirements should also be considered when comparing
costs. According to a 1999 EPA report, maintenance costs for retention basins and
constructed wetlands were estimated at 3 to 6 percent of construction costs, whereas
maintenance costs for swales and bioretention practices were estimated to be 5 to 7
percent of construction costs.11 However, much of the maintenance for bioretention areas
and swales can be accomplished as part of routine landscape maintenance and does not
require specialized equipment. Wetland and pond maintenance, on the other hand,
involves heavy equipment to remove accumulated sediment, oils, trash, and vegetation in
forebays and open ponds.
Finally, in some circumstances LID practices can offset the costs associated with
regulatory requirements for storm water control. In urban redevelopment projects where
land is not likely to be available for large stormwater management practices, developers
can employ site-dispersed BMPs in sidewalk areas, in courtyards, on rooftops, in parking
lots, and in other small outdoor spaces, thereby avoiding the fees that some municipalities
charge when stormwater mitigation requirements cannot otherwise be met. In addition,
stormwater utilities often provide credits for installing runoff management practices such
as LID practices.12
10
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CASE STUDIES
The case studies presented below are not an exhaustive list of LID projects nationwide.
These examples were selected on the basis of the quantity and quality of economic data,
quantifiable impacts, and types of LID practices used. Economic data are available for
many other LID installations, but those installations often cannot be compared with
conventional designs because of the unique nature of the design or the pilot status of the
project. Table 1 presents a summary of the LID practices employed in each case study.
Table 1. Summary of LID Practices Employed in the Case Studies
Name
2nd Avenue SEA
Street
Auburn Hills
Bellingham
Parking Lot
Retrofits
Central Park
Commercial
Redesigns
Crown Street
Gap Creek
Garden Valley
Kensington
Estates
Laurel Springs
Mill Creek
Poplar Street
Apartments
Portland
Downspout
Disconnection*
Prairie Crossing
Prairie Glen
Somerset
Tel labs
Corporate
Campus
Toronto Green
Roofs
LID Techniques
Biore-
tention
^
^
S
S
s
s
s
s
s
s
s
s
Cluster
Building
^
^
^
^
^
Reduced
Impervious
Area
^
^
^
^
^
^
^
^
^
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LID cost comparison and therefore are not included in Table 2 (as noted). Conventional
development cost refers to costs incurred or estimated for a traditional stormwater
management approach, whereas LID cost refers to costs incurred or estimated for using
LID practices. Cost difference is the difference between the conventional development
cost and the LID cost. Percent difference is the cost savings relative to the conventional
development cost.
Table 2. Summary of Cost Comparisons Between Conventional and LID Approaches8
Project
2nd Avenue SEA Street
Auburn Hills
Bellingham City Hall
Bellingham Bloedel Donovan Park
Gap Creek
Garden Valley
Kensington Estates
Laurel Springs
Mill Creekc
Prairie Glen
Somerset
Tellabs Corporate Campus
Conventional
Development
Cost
$868,803
$2,360,385
$27,600
$52,800
$4,620,600
$324,400
$765,700
$1,654,021
$12,510
$1,004,848
$2,456,843
$3,162,160
LID Cost
$651,548
$1,598,989
$5,600
$12,800
$3,942,100
$260,700
$1,502,900
$1,149,552
$9,099
$599,536
$1,671,461
$2,700,650
Cost
Difference1"
$217,255
$761,396
$22,000
$40,000
$678,500
$63,700
-$737,200
$504,469
$3,411
$405,312
$785,382
$461,510
Percent
Difference1"
25%
32%
80%
76%
15%
20%
-96%
30%
27%
40%
32%
15%
The Central Park Commercial Redesigns, Crown Street, Poplar Street Apartments, Prairie Crossing, Portland Downspout
Disconnection, and Toronto Green Roofs study results do not lend themselves to display in the format of this table.
b Negative values denote increased cost for the LID design over conventional development costs.
0 Mill Creek costs are reported on a per-lot basis.
2ND AVENUE SEA STREET, SEATTLE, WASHINGTON
The 2nd Avenue Street Edge Alternative (SEA)
Street project was a pilot project undertaken by
Seattle Public Utilities to redesign an entire 660-foot
block with a number of LID techniques. The goals
were to reduce stormwater runoff and to provide a
more "livable" community. Throughout the design
and construction process, Seattle Public Utilities worked collaboratively with street
residents to develop the final street design.13
The design reduced imperviousness, included retrofits of bioswales to treat and manage
stormwater, and added 100 evergreen trees and 1,100 shrubs.14 Conventional curbs and
gutters were replaced with bioswales in the rights-of-way on both sides of the street, and
the street width was reduced from 25 feet to 14 feet. The final constructed design reduced
imperviousness by more than 18 percent. An estimate for the final total project cost was
$651,548. A significant amount of community outreach was involved, which raised the
level of community acceptance. Community input is important for any project, but
because this was a pilot study, much more was spent on communication and redesign
than what would be spent for a typical project.
12
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The costs for the LID retrofit were compared with the estimated costs of a conventional
street retrofit (Table 3). Managing stormwater with LID techniques resulted in a cost
savings of 29 percent. Also, the reduction in street width and sidewalks reduced paving
costs by 49 percent.
Table 3. Cost Comparison for 2" Avenue SEA Street
Item
Site preparation
Stormwater management
Site paving and sidewalks
Landscaping
Misc. (mobilization, etc.)
Total
Conventional
Development
Cost
$65,084
$372,988
$287,646
$78,729
$64,356
$868,803
SEA Street Cost
$88,173
$264,212
$147,368
$113,034
$38,761
$651,548
Cost Savings*
-$23,089
$108,776
$140,278
-$34,305
$25,595
$217,255
Percent
Savings*
-35%
29%
49%
-44%
40%
Percent of
Total
Savings*
-11%
50%
65%
-16%
12%
! Negative values denote increased cost for the LID design over conventional development costs.
The avoided cost for stormwater infrastructure and reduced cost for site paving accounted
for much of the overall cost savings. The nature of the design, which included extensive
use of bioswales and vegetation, contributed to the increased cost for site preparation and
landscaping. Several other SEA Street projects have been completed or are under way,
and cost evaluations are expected to be favorable.
For this site, the environmental performance has been even more significant than the cost
savings. Hydrologic monitoring of the project indicates a 99 percent reduction in total
potential surface runoff, and runoff has not been recorded at the site since December
2002, a period that included the highest-ever 24-hour recorded rainfall at Seattle-Tacoma
Airport.16 The site is retaining more than the original design estimate of 0.75 inch of rain.
A modeling analysis indicates that if a conventional curb-and-gutter system had been
installed along 2nd Avenue instead of the SEA Street design, 98 times more stormwater
would have been discharged from the site.17
AUBURN HILLS SUBDIVISION, SOUTHWESTERN
WISCONSIN
Auburn Hills in southwestern Wisconsin is a
residential subdivision developed with conservation
design principles. Forty percent of the site is
preserved as open space; this open space includes
wetlands, green space and natural plantings, and
walking trails. The subdivision was designed to
include open swales and bioretention for stormwater management. To determine potential
savings from using conservation design, the site construction costs were compared with
the estimated cost of building the site as a conventional subdivision.18 Reduced
stormwater management costs accounted for approximately 56 percent of the total cost
savings. A cost comparison is provided in Table 4. Other savings not shown in Table 4
were realized as a result of reduced sanitary sewer, water distribution, and utility
construction costs.
13
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Table 4. Cost Comparison for Auburn Hills Subdivision
Item
Site preparation
Stormwater management
Site paving and sidewalks
Landscaping
Total
Conventional
Development
Cost
$699,250
$664,276
$771,859
$225,000
$2,360,385
Auburn Hills LID
Cost
$533,250
$241,497
$584,242
$240,000
$1,598,989
Cost
Savings*
$166,000
$422,779
$187,617
-$15,000
$761,396
Percent
Savings*
24%
64%
24%
-7%
Percent of
Total
Savings*
22%
56%
25%
-2%
! Negative values denote increased cost for the LID design over conventional development costs.
The clustered design used in the development protected open space and reduced clearing
and grading costs. Costs for paving and sidewalks were also decreased because the
cluster design reduced street length and width. Stormwater savings were realized
primarily through the use of vegetated swales and bioswales. These LID practices
provided Stormwater conveyance and treatment and also lowered the cost of conventional
Stormwater infrastructure. The increase in landscaping costs resulted from additional
open space present on-site compared to a conventional design, as well as increased street
sweeping. Overall, the subdivision's conservation design retained more natural open
space for the benefit and use of the homeowners and aided Stormwater management by
preserving some of the site's natural hydrology.20
BELLINGHAM, WASHINGTON, PARKING LOT RETROFITS
The City of Bellingham, Washington, retrofitted two
parking lotsone at City Hall and the other at Bloedel
Donovan Parkwith rain gardens in lieu of installing
underground vaults to manage Stormwater.21 At City
Hall, 3 parking spaces out of a total of 60 were used for
the rain garden installation. The Bloedel Donovan Park
retrofit involved converting to a rain garden a 550-
square-foot area near a catch basin. Both installations
required excavation, geotextile fabric, drain rock, soil amendments, and native plants.
Flows were directed to the rain gardens by curbs. An overflow system was installed to
accommodate higher flows during heavy rains.
The City compared actual rain garden costs to estimates for conventional underground
vaults based on construction costs for similar projects in the area ($12.00 per cubic foot
of storage). Rain garden costs included labor, vehicle use/rental, and materials. Table 5
shows that the City Hall rain garden saved the City $22,000, or 80 percent, over the
underground vault option; the Bloedel Donovan Park installation saved $40,000, or
76 percent.
Table 5. Cost Comparison for Bellingham's Parking Lot Rain Garden Retrofits
,22
Project
City Hall
Bloedel Donovan Park
Conventional Vault
Cost
$27,600
$52,800
Rain Garden Cost
$5,600
$12,800
Cost Savings
$22,000
$40,000
Percent Savings
80%
76%
14
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CENTRAL PARK COMMERCIAL REDESIGNS,
FREDERICKSBURG, VA (A MODELING STUDY)
The Friends of the Rappahannock undertook a cost
analysis involving the redesign of site plans for
several stores in a large commercial development
in the Fredericksburg, Virginia, area called Central
Park.23'24 Table 6 contains a side-by-side analysis
of the cost additions and reductions for each site
for scenarios where LID practices (bioretention
areas and swales) were incorporated into the existing, traditional site designs. In five of
the six examples, the costs for the LID redesigns were higher than those for the original
designs, although they never exceeded $10,000, or 10 percent of the project. One
example yielded a $5,694 savings. The fact that these projected costs for LID were
comparable to the costs for traditional designs convinced the developer to begin
incorporating LID practices into future design projects.25
Table 6. Site Information and Cost Additions/Reductions Using LID Versus Traditional Designs
Name
Breezewood Station
Alternative 1
Breezewood Station
Alternative 2
Olive Garden
Kohl's, Best Buy, &
Office Depot
First Virginia Bank
Chick-Fil-Ac
Total BMP
Area (ft')
4,800
3,500
1,780
14,400
1,310
1,326
Total
Impervious
Area Treated
(ft2)
64,165
38,775
31,900
354,238
20,994
28,908
Percent of
Impervious
Area Treated
98.4%
59.5%
59.1%
56.3%
97.7%
82.2%
Cost
Additions3
$36,696
$24,449
$14,885
$89,433
$6,777
$6,846
Cost
Reductions11
$34,785
$21,060
$11,065
$80,380
$1,148
$12,540
Change in
Cost After
Redesign
+ $1,911
+ $3,389
+ $3,790
+ $9,053
+ $5,629
-$5,694
a Additional costs for curb, curb blocks, storm piping, inlets, underdrains, soil, mulch, and vegetation as a result of the redesign.
b Reduced cost for curb, storm piping, roof drain piping, and inlets as a result of the redesign.
0 Cost reduction value includes the cost of a Stormceptor unit that is not needed as part of the redesign.
CROWN STREET, VANCOUVER, BRITISH COLUMBIA
In 1995 the Vancouver City Council adopted a
Greenways program that is focused on introducing
pedestrian-friendly green space into the City to
connect trails, environmental areas, and urban space.
As a part of this program, the City has adopted
strategies to manage stormwater runoff from
roadways. Two initiatives are discussed here.
The Crown Street redevelopment project, completed
in 2005, retrofitted a 1,100-foot block of traditional
curb-and-gutter street with a naturalized streetscape modeled after the Seattle SEA Street
design. Several LID features were incorporated into the design. The total imperviousness
of the street was decreased by reducing the street width from 28 feet to 21 feet with one-
15
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way sections of the road narrowed to 10 feet. Roadside swales that use vegetation and
structural grass (grass supported by a grid and soil structure that prevents soil compaction
and root damage) were installed to collect and treat stormwater through infiltration.26
Modeling predicts that the redesigned street will retain 90 percent of the annual rainfall
volume on-site; the remaining 10 percent of runoff will be treated by the system of
vegetated swales before discharging.27'28 The City chose to use the LID design because
stormwater runoff from Crown Street flows into the last two salmon-bearing creeks in
Vancouver.29 Monitoring until 2010 will assess the quality of stormwater runoff and
compare it with both the modeling projections and the runoff from a nearby curb-and-
gutter street.
The cost of construction for the Crown Street redevelopment was $707,000. Of this,
$311,000 was attributed to the cost of consultant fees and aesthetic design features, which
were included in the project because it was the first of its kind in Vancouver. These
added costs would not be a part of future projects. Discounting the extra costs, the
$396,000 construction cost is 9 percent higher than the estimated $364,000 conventional
curb-and-gutter design cost.30 The City has concluded that retrofitting streets that have an
existing conventional stormwater system with naturalized designs will cost marginally
more than making curb-and-gutter improvements, but installing naturalized street designs
in new developments will be less expensive than installing conventional drainage
systems.31'32
One goal of Vancouver's Greenways program is to make transportation corridors more
pedestrian-friendly. A method used to achieve this goal is to extend curbs at intersections
out into the street to lessen the crossing distance and improve the line of sight for
pedestrians. When this initiative began, the City relocated stormwater catch basins that
would have been enclosed within the extended curb. Now, at certain intersections, the
City uses the new space behind the curb to install "infiltration bulges" to collect and
infiltrate roadway runoff. The infiltration bulges are constructed of permeable soils and
vegetation. (The City of Portland, Oregon, has installed similar systems, which they call
"vegetated curb extensions.") The catch basins are left in place, and any stormwater that
does not infiltrate into the soil overflows into the storm drain system.33
The infiltration bulges have resulted in savings for the City. Because the stormwater
infiltration bulges are installed in conjunction with planned roadway improvements, the
only additional costs associated with the stormwater project are the costs of a steel curb
insert to allow stormwater to enter the bulge and additional soil excavation costs. These
additional costs are more than offset by the $2,400 to $4,000 cost that would have been
required to relocate the catch basins. To date, the City has installed nine infiltration
bulges, three of which are maintained by local volunteers as part of a Green Streets
program in which local residents adopt city green space.34
16
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GAP CREEK SUBDIVISION, SHERWOOD, ARKANSAS
Gap Creek's original subdivision plan was revised
to include LID concepts. The revised design
increased open space from the originally planned
1.5 acres to 23.5 acres. Natural drainage areas
were preserved and buffered by greenbelts.
Traffic-calming circles were used, allowing the
developer to reduce street widths from 36 to 27
feet. In addition, trees were kept close to the curb
line. These design techniques allowed the development of 17 additional lots.
The lots sold for $3,000 more and cost $4,800 less to develop than comparable
conventional lots. A cost comparison is provided in Table 7. For the entire development,
the combination of cost savings and lot premiums resulted in an additional profit to the
developer of $2.2 million.35'36
Table 7. Cost Comparison for Gap Creek Subdivision3
Total Cost of
Conventional Design
$4,620,600
Gap Creek
LID Cost
$3,942,100
Cost Savings
$678,500
Percent Savings
15%
Savings per Lot
$4,800
GARDEN VALLEY, PIERCE COUNTY, WASHINGTON
(A MODELING STUDY)
The Garden Valley subdivision is a 9.7-acre site in
Pierce County, Washington. A large wetland on the
eastern portion of the site and a 100-foot buffer
account for 43 percent of the site area. Designers
evaluated a scenario in which roadway widths were
reduced and conventional stormwater management
practices were replaced with swales, bioretention, and soil amendments. The use of these
LID elements would have allowed the cost for stormwater management on the site to be
reduced by 72 percent. A cost comparison is provided in Table 8.38 Other costs expected
with the LID design were a $900 initial cost for homeowner education with $170 required
annually thereafter. Annual maintenance costs for the LID design (not included above)
were expected to be $600 more than those for the conventional design, but a $3,000
annual savings in the stormwater utility bill was expected to more than offset higher
maintenance costs.
17
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Table 8. Cost Comparison for Garden Valley Subdivision
39
Item
Stormwater management
Site paving
Total
Conventional
Development Cost
$214,000
$110,400
$324,400
Garden Valley LID
Cost
$59,800
$200,900
$260,700
Cost Savings*
$154,200
-$90,500
$63,700
Percent Savings*
72%
-82%
! Negative values denote increased cost for the LID design over conventional development costs.
The design incorporated the use of narrower roadways coupled with Grasscrete parking
along the roadside, which increased the overall site paving costs. However, this added
cost was more than offset by the savings realized by employing LID for stormwater
management. The LID practices were expected to increase infiltration and reduce
stormwater discharge rates, which can improve the health and quality of receiving
streams.
KENSINGTON ESTATES, PIERCE COUNTY,
WASHINGTON (A MODELING STUDY)
A study was undertaken to evaluate the use of LID
techniques at the Kensington Estates subdivision,
a proposed 24-acre development consisting of
single-family homes on 103 lots. The study
assumed that conventional stormwater
management practices would be replaced entirely
by LID techniques, including reduced imperviousness, soil amendments, and bioretention
areas. The design dictated that directly connected impervious areas on-site were to be
minimized. Three wetlands and an open space tract would treat stormwater discharging
from LID installations. Open space buffers were included in the design. The LID
proposal also included rooftop rainwater collection systems on each house.40'41
The proposed LID design reduced effective impervious area from 30 percent in the
conventional design to approximately 7 percent, and it was approximately twice as
expensive as the traditional design. A cost comparison is provided in Table 9.
Table 9. Cost Comparison for Kensington Estates Subdivision42
Item
Stormwater management
Site paving
Total
Conventional
Development Cost
$243,400
$522,300
$765,700
Kensington Estate
LID Cost
$925,400
$577,500
$1,502,900
Additional Cost
$ 682,000
$55,200
$737,200
Although the study assumed that roadways in the LID design would be narrower than
those in the conventional design, site paving costs increased because the LID design
assumed that Grasscrete parking would be included along the roadside to allow
infiltration. The use of Grasscrete increased the overall site paving costs.
18
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The avoidance of conventional stormwater infrastructure with the use of LID afforded
significant cost savings. The LID measures eliminated the need for a detention pond and
made more lots available for development. The significant cost for the rooftop rainwater
collection systems was assumed to be offset somewhat by savings on stormwater utility
bills.43
The study also anticipated that the use of LID would reduce stormwater peak flow
discharge rates and soil erosion. Furthermore, greater on-site infiltration increases ground
water recharge, resulting in increased natural baseflows in streams and a reduction in dry
channels. Proposed clustering of buildings would allow wetlands and open space to be
preserved and create a more walkable community. The reduced road widths were
anticipated to decrease traffic speeds and accident rates.
LAUREL SPRINGS SUBDIVISION, JACKSON,
WISCONSIN
The Laurel Springs subdivision in Jackson,
Wisconsin, is a residential subdivision that was
developed as a conservation design community.
The use of cluster design helped to preserve open
space and minimize grading and paving. The use
of bioretention and vegetated swales lowered the
costs for stormwater management.
The costs of using conservation design to develop the subdivision were compared with
the estimated cost of developing the site with conventional practices (Table 10).44 The
total savings realized with conservation design were just over $504,469, or approximately
30 percent of the estimated conventional construction cost. Savings from stormwater
management accounted for 60 percent of the total cost savings. Other project savings
were realized with reduced sanitary sewer, water distribution, and utility construction
costs.
Table 10. Cost Comparison for Laurel Springs Subdivision
45
Item
Site preparation
Stormwater management
Site paving and sidewalks
Landscaping
Total
Conventional
Development
Cost
$441,600
$439,956
$607,465
$165,000
$1,654,021
Laurel Springs
LID Cost
$342,000
$136,797
$515,755
$155,000
$1,149,552
Cost Savings
$99,600
$303,159
$91,710
$10,000
$504,469
Percent
Savings
23%
69%
15%
6%
Percent of
Total
Savings
20%
60%
18%
2%
In addition to preserving open space and reducing the overall amount of clearing and
grading, the cluster design also reduced street lengths and widths, thereby lowering costs
for paving and sidewalks. Vegetated swales and bioswales largely were used to replace
conventional stormwater infrastructure and led to significant savings. Each of these
factors helped to contribute to a more hydrologically functional site that reduced the total
amount of stormwater volume and managed stormwater through natural processes.
19
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MILL CREEK SUBDIVISION, KANE COUNTY, ILLINOIS
The Mill Creek subdivision is a 1,500-acre, mixed-
use community built as a conservation design
development. Approximately 40 percent of the site
is identified as open space; adjacent land use is
mostly agricultural. The subdivision was built
using cluster development. It uses open swales for
stormwater conveyance and treatment, and it has a
lower percentage of impervious surface than
conventional developments. An economic analysis compared the development cost for 40
acres of Mill Creek with the development costs of 30 acres of a conventional
development with similar building density and location.46
When compared with the conventional development, the conservation site design
techniques used at Mill Creek saved approximately $3,411 per lot. Nearly 70 percent of
these savings resulted from reduced costs for stormwater management, and 28 percent of
the savings were found in reduced costs for site preparation. A cost comparison is
provided in Table 11. Other savings not included in the table were realized with reduced
construction costs for sanitary sewers and water distribution.
Table 11. Cost Comparison for Mill Creek Subdivision4
Item
Site preparation
Stormwater management
Site paving and sidewalks
Total
Conventional
Development
Cost per Lot
$2,045
$4,535
$5,930
$12,510
Mill Creek
LID Cost per Lot
$1,086
$2,204
$5,809
$9,099
Cost Savings
per Lot
$959
$2,331
$121
$3,411
Percent
Savings
per Lot
47%
51%
2%
Percent of
Total
Savings
28%
68%
4%
The use of cluster development and open space preservation on the site decreased site
preparation costs. The majority of the cost savings were achieved by avoiding the
removal and stockpiling of topsoil. In addition to cost savings from avoided soil
disturbance, leaving soils intact also retains the hydrologic function of the soils and aids
site stormwater management by reducing runoff volumes and improving water quality.
The site's clustered design was also responsible for a decrease in costs for paving and
sidewalks because the designers intentionally aimed to decrease total road length and
width.
The designers used open swales as the primary means for stormwater conveyance.
Coupled with other site techniques to reduce runoff volumes and discharge rates,
significant savings in stormwater construction were avoided because of reduced storm
sewer installation; sump pump connections; trench backfill; and catch basin, inlet, and
cleanout installation.
In addition to the cost savings, the conservation design at Mill Creek had a positive effect
on property values: lots adjacent to walking/biking trails include a $3,000 premium, and
lots adjacent to or with views of open space include a $10,000 to $17,500 premium. The
20
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600 acres of open space on the site include 127 acres of forest preserve with quality
wetlands, 195 acres of public parks, and 15 miles of walking/biking trails.48
POPLAR STREET APARTMENTS, ABERDEEN, NORTH
CAROLINA
The use of bioretention, topographical depressions,
grass channels, swales, and stormwater basins at the
270-unit Poplar Street Apartment complex improved
stormwater treatment and lowered construction
costs. The design allowed almost all conventional
underground storm drains to be eliminated from the
design. The design features created longer flow paths, reduced runoff volume, and
filtered pollutants from runoff. According to the U.S. Department of Housing and Urban
Development, use of LID techniques resulted in a $175,000 savings (72 percent).49
Portland
Downspout
Disconnection
PORTLAND DOWNSPOUT DISCONNECTION PROGRAM,
PORTLAND, OREGON
The City of Portland, Oregon, implemented a
Downspout Disconnection Program as part of its
CSO elimination program. Every year, billions of
gallons of stormwater mixed with sewage pour into
the Willamette River and Columbia Slough through
CSOs. When roof runoff flows into Portland's
combined sewer system, it contributes to CSOs. The City has reduced the frequency of
CSOs to the Columbia Slough and hopes to eliminate 94 percent of the overflows to the
Willamette River by 2011.50
The Downspout Disconnection Program gives homeowners, neighborhood associations,
and community groups the chance to work as partners with the Bureau of Environmental
Services and the Office of Neighborhood Involvement to help reduce CSOs. Residents of
selected neighborhoods disconnect their downspouts from the combined sewer system
and allow their roof water to drain to gardens and lawns. Residents can do the work
themselves and earn $53 per downspout, or they can have community groups and local
contractors disconnect for them. Community groups earn $13 for each downspout they
disconnect. (Materials are provided by the City.)
More than 44,000 homeowners have disconnected their downspouts, removing more than
1 billion gallons of stormwater per year from the combined sewer system. The City
estimates that removing the 1 billion gallons will result in a $250 million reduction in
construction costs for an underground pipe to store CSOs by reducing the capacity
needed to handle the flows. The City has spent $8.5 million so far to implement this
program and will continue to encourage more homeowners and businesses to disconnect
their downspouts to achieve additional CSO and water quality benefits.
21
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PRAIRIE CROSSING SUBDIVISION, GRAYSLAKE,
ILLINOIS
The Prairie Crossing subdivision is a conservation
development on 678 acres, of which 470 acres is
open space. The site was developed as a mixed-use
community with 362 residential units and 73 acres
of commercial property, along with schools, a
community center, biking trails, a lakefront beach,
and a farm. The site uses bioretention cells and vegetated swales to manage stormwater.
A cost analysis was performed to compare the actual construction costs of Prairie
Crossing with the estimated costs of a conventional design on the site with the same
layout. Cost savings with conservation design were realized primarily in four areas:
stormwater management, curb and gutter installation, site paving, and sidewalk
installation. The total savings were estimated to be almost $1.4 million, or nearly $4,000
per lot (Table 12). Savings from stormwater management accounted for approximately 15
percent of the total savings. The cost savings shown are relative to the estimated
construction cost for the items in a conventional site design based on local codes and
standards.
Table 12. Cost Comparison for Prairie Crossing Subdivision5
Item
Reduced Road Width
Stormwater Management
Decreased Sidewalks
Reduced Curb and Gutter
Total
Cost Savings
$178,000
$210,000
$648,000
$339,000
$1,375,000
Percent Savings
13%
15%
47%
25%
Reduced costs for sidewalks accounted for nearly half of the total cost savings. This
savings is attributed in part to the use of alternative materials rather than concrete for
walkways in some locations. In addition, the design and layout of the site, which retained
a very high percentage of open space, contributed to the cost savings realized from
reducing paving, the length and number of sidewalks, and curbs and gutters. The use of
alternative street edges, vegetated swales, and bioretention and the preservation of natural
areas all reduced the need for and cost of conventional stormwater infrastructure.53
Benefits are associated with the mixed-use aspect of the development as well: residents
can easily access schools, commercial areas, recreation, and other amenities with minimal
travel. Proximity to these resources can reduce traffic congestion and transportation costs.
Also, mixed-use developments can foster a greater sense of community and belonging
than other types of development. All of these factors tend to improve quality of life.
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PRAIRIE GLEN SUBDIVISION, GERMANTOWN,
WISCONSIN
The Prairie Glen subdivision is nationally
recognized for its conservation design approach. A
significant portion of the site (59 percent) was
preserved as open space. Wetlands were constructed
to manage stormwater runoff, and the open space
allowed the reintroduction of native plants and
wildlife habitat. The site layout incorporated hiking trails, which were designed to allow
the residents to have easy access to natural areas.54
To evaluate the cost benefits of Prairie Glen's design, the actual construction costs were
compared with the estimated costs of developing the site conventionally. When compared
with conventional design, the conservation design at Prairie Glen resulted in a savings of
nearly $600,000. Savings for stormwater management accounted for 25 percent of the
total savings. Table 13 provides a cost comparison. Other savings not included in the
table were realized with reduced sanitary sewer, water distribution, and utility
construction costs.
Table 13. Cost Comparison for Prairie Glen Subdivision55
Item
Site preparation
Stormwater management
Site paving and sidewalks
Landscaping
Total
Conventional
Development
Cost
$277,043
$215,158
$462,547
$50,100
$1,004,848
Prairie Glen
LID Cost
$188,785
$114,364
$242,707
$53,680
$599,536
Cost
Savings*
$88,258
$100,794
$219,840
-$3,580
$405,312
Percent
Savings*
32%
47%
48%
-7%
Percent of
Total
Savings*
22%
25%
54%
-1%
! Negative values denote increased cost for the LID design over conventional development costs.
The cluster design and preservation of a high percentage of open space resulted in a
significant reduction in costs for paving and sidewalks. These reduced costs accounted
for 54 percent of the cost savings for the overall site. Reduced costs for soil excavation
and stockpiling were also realized. The use of open-channel drainage and bioretention
minimized the need for conventional stormwater infrastructure and accounted for the
bulk of the savings in stormwater management. Landscaping costs increased due to the
added amount of open space on the site.
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SOMERSET SUBDIVISION, PRINCE GEORGE'S COUNTY,
MARYLAND
The Somerset subdivision, outside Washington,
B.C., is an 80-acre site consisting of nearly 200
homes. Approximately half of the development was
built using LID techniques; the other half was
conventionally built using curb-and-gutter design
with detention ponds for stormwater management.
Bioretention cells and vegetated swales were used in the LID portion of the site to replace
conventional stormwater infrastructure. Sidewalks were also eliminated from the design.
To address parking concerns, some compromises were made: because of local
transportation department concern that roadside parking would damage the swales, roads
were widened by 10 feet.56 (Note that there are alternative strategies to avoid increasing
impervious surface to accommodate parking, such as installing porous pavement parking
lanes next to travel lanes.)
Most of the 0.25-acre lots have a 300- to 400-square-foot bioretention cell, also called a
rain garden. The cost to install each cell was approximately $500$150 for excavation
and $350 for plants. The total cost of bioretention cell installation in the LID portion of
the site was $100,000 (swale construction was an additional cost). The construction cost
for the detention pond in the conventionally designed portion of the site was $400,000,
excluding curbs, gutters, and sidewalks.57'58 By eliminating the need for a stormwater
pond, six additional lots could be included in the LID design. A comparison of the overall
costs for the traditional and LID portions of the site is shown in Table 14.
Table 14. Cost Comparison for Somerset Subdivision
Conventional Development
Cost
$2,456,843
Somerset
LID Cost
$1,671,461
Cost Savings
$785,382
Percent Savings
32%
Savings per Lot
$4,000
In terms of environmental performance, the LID portion of the subdivision performed
better than the conventional portion.59 A paired watershed study compared the runoff
between the two portions of the site, and monitoring indicated that the average annual
runoff volume from the LID watershed was approximately 20 percent less than that from
the conventional watershed. The number of runoff-producing rain events in the LID
watershed also decreased by 20 percent. Concentrations of copper were 36 percent lower;
lead, 21 percent lower; and zinc, 37 percent lower in LID watershed runoff than in
conventional watershed runoff. The homeowners' response to the bioretention cells was
positive; many perceived the management practices as a free landscaped area.
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TELLABS CORPORATE CAMPUS, NAPERVILLE,
ILLINOIS
The Tellabs corporate campus is a 5 5-acre site with
more than 330,000 square feet of office space. After
reviewing preliminary planning materials that
compared the costs of conventional and conservation
design, the company chose to develop the site with
conservation design approaches. Because the
planning process included estimating costs for the two development approaches, this
particular site provides good information on commercial/industrial use of LID.60
Development of the site included preserving trees and some of the site's natural features
and topography. For stormwater management, the site uses bioswales, as well as other
infiltration techniques, in parking lots and other locations. The use of LID techniques for
stormwater management accounted for 14 percent of the total cost savings for the project.
A cost comparison is provided in Table 15. Other cost savings not shown in Table 15
were realized with reduced construction contingency costs, although design contingency
costs were higher.
Table 15. Cost Comparison for Tellabs Corporate Campus61
Item
Site preparation
Stormwater management
Landscape development
Total
Conventional
Development
Cost
$2,178,500
$480,910
$502,750
$3,162,160
Tellabs
LID Cost
$1,966,000
$418,000
$316,650
$2,700,650
Cost Savings
$212,500
$62,910
$186,100
$461,510
Percent
Savings
10%
13%
37%
Percent of
Total
Savings
46%
14%
40%
Savings in site preparation and landscaping had the greatest impact on costs. Because
natural drainage pathways and topography were maintained to the greatest extent
possible, grading and earthwork were minimized; 6 fewer acres were disturbed using the
conservation design approach. Landscaping at the site maximized natural areas and
restored native prairies and wetland areas. The naturalized landscape eliminated the need
for irrigation systems and lowered maintenance costs when compared to turf grass, which
requires mowing and regular care. In the end, the conservation approach preserved trees
and open space and provided a half acre of wetland mitigation. The bioswales used for
stormwater management complemented the naturalized areas and allowed the site to
function as a whole; engineered stormwater techniques augmented the benefits of the
native areas and wetlands.62
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TORONTO GREEN ROOFS, TORONTO, ONTARIO
(A MODELING STUDY)
Toronto is home to more than 100 green roofs. To
evaluate the benefits of greatly expanded use of
green roofs in the city, a study was conducted using
a geographic information system to model the
effects of installing green roofs on all flat roofs
larger than 3,750 square feet. (The model assumed
that each green roof would cover at least 75 percent
of the roof area.) If the modeling scenario were
implemented, 12,000 acres of green roofs (8 percent
of the City's land area) would be installed.63 The study quantified five primary benefits
from introducing the green roofs: (1) reduced storm water flows into the separate storm
sewer system, (2) reduced stormwater flows into the combined sewer system,
(3) improved air quality, (4) mitigation of urban heat island effects, and (5) reduced
energy consumption.64
The study predicted economic benefits of nearly $270 million in municipal capital cost
savings and more than $30 million in annual savings. Of the total savings, more than
$100 million was attributed to stormwater capital cost savings, $40 million to CSO
capital cost savings, and nearly $650,000 to CSO annual cost savings. The cost of
installing the green roofs would be largely borne by private building owners and
developers; the cost to Toronto would consist of the cost of promoting and overseeing the
program and would be minimal. Costs for green roof installations in Canada have
averaged $6 to $7 per square foot. The smallest green roof included in the study, at 3,750
square feet, would cost between $22,000 and $27,000. The total cost to install 12,000
acres of green roofs would be $3 billion to $3.7 billion.65'66 Although the modeled total
costs exceed the monetized benefits, the costs would be spread across numerous private
entities.
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CONCLUSION
The 17 case studies presented in this report show that LID practices can reduce project
costs and improve environmental performance. In most cases, the case studies indicate
that the use of LID practices can be both fiscally and environmentally beneficial to
communities. As with almost all such projects, site-specific factors influence project
outcomes, but in general, for projects where open space was preserved and cluster
development designs were employed, infrastructure costs were lower. In some cases,
initial costs might be higher because of the cost of green roofs, increased site preparation
costs, or more expensive landscaping practices and plant species. However, in the vast
majority of cases, significant savings were realized during the development and
construction phases of the projects due to reduced costs for site grading and preparation,
stormwater infrastructure, site paving, and landscaping. Total capital cost savings ranged
from 15 to 80 percent when LID methods were used, with a few exceptions in which LID
project costs were higher than conventional stormwater management costs.
EPA has identified several additional areas that will require further study. First, in all the
cases, there were benefits that this study did not monetize and factor into the project's
bottom line. These benefits include improved aesthetics, expanded recreational
opportunities, increased property values due to the desirability of the lots and their
proximity to open space, increased number of total units developed, the value of
increased marketing potential, and faster sales.
Second, more research is also needed to quantify the environmental benefits that can be
achieved through the use of LID techniques and the costs that can be avoided by using
these practices. For example, substantial downstream benefits can be realized through
the reduction of the peak flows, discharge volumes, and pollutant loadings discharged
from the site. Downstream benefits also might include reductions in flooding and
channel degradation, costs for water quality improvements, costs of habitat restoration,
costs of providing CSO abatement, property damage, drinking water treatment costs,
costs of maintaining/dredging navigable waterways, and administrative costs for public
outreach and involvement.
Finally, additional research is needed monetize the cost reductions that can be achieved
through improved environmental performance, reductions in long-term operation and
maintenance costs and/or reductions in the life cycle costs of replacing or rehabilitating
infrastructure.
1 D. Beach, Coastal Sprawl: The Effects of Urban Design on Aquatic Ecosystems in the
United States (Arlington, VA: Pew Ocean Commission, 2002).
2 USD A, Summary Report: 1997 National Resources Inventory (Washington, DC: U.S.
Department of Agriculture, Natural Resources Conservation Service, 1999 [revised 2000]).
3 Beach, 2002.
4 The term LID is one of many used to describe the practices and techniques employed to
provide advanced stormwater management; green infrastructure, conservation design, and
sustainable stormwater management are other common terms. However labeled, each of the
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identified practices seeks to maintain and use vegetation and open space, optimize natural
hydrologic processes to reduce stormwater volumes and discharge rates, and use multiple
treatment mechanisms to remove a large range of pollutants. In the context of this report, case
studies ascribing to one of the above, or similar, labels were evaluated, and these terms are used
interchangeably throughout the report.
5 Trust for Public Land, The Economic Benefits of Open Space (Trust for Public Land, 1999),
http://www.tpl.org/tier3_cd.cfm?content_item_id=1195&folder_id=727 (accessed March 29,
2006).
6 Trust for Public Land and American Water Works Association. Protecting the Source (San
Francisco, CA: Trust for Public Land, 2004).
7 Riverkeeper, Sustainable Raindrops: Cleaning New York Harbor by Greening The Urban
Landscape (accessed Nov. 30, 2007).
8 Trust for Public Land, 1999.
9 USEPA, Economic Benefits of Runoff Controls (Washington, DC: U.S. Environmental
Protection Agency, Office of Water, 1995).
10 National Park Service, Economic Impacts of Protecting Rivers, Trails, and Greenway
Corridors: A Resource Book (National Park Service, 1995),
http://www.nps.gov/pwro/rtca/econindx.htm (accessed June 1, 2006).
11 USEPA, Preliminary Data Summary of Urban Stormwater Best Management Practices,
EPA-821-R-99-012 (Washington, DC: U.S. Environmental Protection Agency, 1999),
http://www.epa.gov/OST/stormwater (accessed March 1, 2006).
12 Water Environment Federation, Credits Bring Economic Incentives for Onsite Stormwater
Management, Watershed & Wet Weather Technical Bulletin (January 1999).
13 C. Kloss and C. Calarusse, GIReport (New York, NY:, Natural Resources Defense
Council, April 2006).
14 R.R. Horner, H. Lim, and S.J. Burges, Hydrologic Monitoring of the Seattle Ultra-Urban
Stormwater Management Projects: Summary of the 2000-2003 Water Years, Water Resources
Series: Technical Report No. 181 (Seattle, WA: University of Washington, Department of Civil
and Environmental Engineering, 2004),
http://www.ci. seattle.wa.us/util/stellent/groups/public/@,spu/@,esb/documents/webcontent/hydrolo
gic 200406180904017.pdf. (accessed November 19, 2007).
15 J. Haugland, Changing Cost Perceptions: An Analysis of Conservation Development
(Elmhurst, IL: Conservation Research Institute, 2005),
http://www.nipc.org/environment/sustainable/conservationdesign/cost analysis (accessed
March 1, 2006).
16 Horner etal., 2004.
17 Horner etal., 2004.
18 Haugland, 2005.
19 Haugland, 2005.
20 Haugland, 2005.
21 Puget Sound Action Team, Reining in the Rain: A Case Study of the City ofBellingham 's
Use of Rain Gardens to Manage Stormwater (Puget Sound Action Team, 2004),
www.psat.wa.gov/Publications/Rain Garden book.pdf (accessed September 11, 2007).
28
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22 Puget Sound Action Team, 2004.
23 Friends of the Rappahannock, Example LID Commercial Re-designs and Costs
Spreadsheets for Re-designs (Friends of the Rappahannock, 2006),
http://www.riverfriends.org/Publications/LowImpactDevelopment/tabid/86/Default.aspx.
(accessed November 19, 2007).
24 C.S. Ingles, Stafford County Helps Pioneer Low Impact Design Movement, Virginia Town
& City 39, no. 8 (2004).
25 Ingles, 2004.
26 Kloss and Calarusse, 2006.
27 A. Steed, Naturalized Streetscapes: A Case Study of Crown Street, Vancouver (City of
Vancouver Greenways, Vancouver, BC: City of Vancouver Greenways, no date),
http://www.sustainabilitv.ca/Docs/Naturalized%20Streetscapes-
AS.pdf?CFID=19075623&CFTOKEN=60214114 (accessed March 31, 2006).
28 Personal communication with Otto Kauffmann, Engineering Project Coordinator, City of
Vancouver Streets Division, April 2005.
29 Scott Deveau, Street in for Crowning Touch, The Vancouver Courier (September 22, 2004)
http://spec.bc.ca/article/article.php?articleID=340 (accessed March 9, 2005).
30 American dollars converted from Canadian equivalent based on April 25, 2005, exchange
rate.
31 City of Vancouver, British Columbia, Crown Street: Vancouver's First Environmentally
Sustainable Street (City of Vancouver, BC, 2005), prepared for TAC's Environmental Council,
Vancouver, BC, http://www.transportationassociation.ca/english/pdf/conf2005/s5/kauffman.pdf
(accessed November 19, 2007).
32 Personal communication with Otto Kauffmann, Engineering Project Coordinator, City of
Vancouver Streets Division, November 2005.
33 Kloss and Calarusse, 2006.
34 Personal communication with David Yurkovich, Greenways Landscape Designer, City of
Vancouver Greenways, April 2005.
35 Haugland, 2005.
36 HUD, The Practice of Low Impact Development (LID) (Washington, DC: U.S. Department
of Housing and Urban Development, Office of Policy Development and Research, 2003),
http://www.huduser.org/Publications/PDF/practLowImpctDevel.pdf (accessed March 1, 2006).
37 Haugland, 2005.
38 CH2MHill, Pierce County Low Impact Development StudyFinal Report (Belleview, WA:
CH2MHill, 2001), http://www.co.pierce.wa.us/xml/services/home/environ/water/CIP/LID/final-
lid-report.pdf (accessed March 1, 2006).
39CH2MHill, 2001.
40 USEPA, Low-Impact Development Pays Off, Nonpoint Source News-Notes 75 (May 2005):
7-10, http://www.epa.gov/owow/info/NewsNotes/issue75/75issue.pdf (accessed March 1, 2006).
41 CH2MHill, 2001.
42CH2MHill, 2001.
43 CH2MHill, 2001.
29
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44 Haugland, 2005.
45
46
Haugland, 2005.
Haugland, 2005.
47 Haugland, 2005.
48 Haugland, 2005.
49 HUD, 2003.
50 Portland Bureau of Environmental Services, Downspout Disconnection Program (Portland,
OR: Portland Bureau of Environmental Services, 2006),
http://www.portlandonline.com/bes/index.cfm?c=31246 (accessed March 31, 2006).
51 Haugland, 2005.
52 Haugland, 2005.
53 Haugland, 2005.
54 Haugland, 2005.
55 Haugland, 2005.
56 USEPA, Maryland Developer Grows "Rain Gardens" to Control Residential Runoff,
Nonpoint Source News-Notes 42 (August/September 1995),
http://www.epa.gov/owow/info/NewsNotes/pdf/42issue.pdf (accessed March 1, 2006).
57 USEPA, 2005.
58 HUD, 2003.
59 USEPA, 2005.
60 Haugland, 2005.
61 Haugland, 2005.
62 Haugland, 2005.
63 D. Banting, H. Doshi, J. Li, P. Missios, A. Au, B.A. Currie, and M. Verrati, Report on the
Environmental Benefits and Costs of Green Roof Technology for the City of Toronto (Toronto,
ON: City of Toronto and Ontario Centres of ExcellenceEarth and Environmental Technologies,
2005), http://www.toronto.ca/greenroofs/pdf/fullreportl03105.pdf (accessed December 16, 2005).
64 Kloss and Calarusse, 2006.
65 American dollars converted from Canadian equivalent based on December 19, 2005,
exchange rate.
66 Banting et al., 2005.
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