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Estimating the
Environmental Effects of
Green Roofs
A Case Study in Kansas City, Missouri
United States
JbpMil Environmental Protection
^1 M * Agency
EPA 430-S-18-001
August 2018
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Suggested Citation
U.S. Environmental Protection Agency. (2018). Estimating the environmental effects of green roofs: A
case study in Kansas City, Missouri. EPA 430-S-18-001. www.epa.gov/heat-islands/usinq-qreen-
roofs-reduce-heat-islands.
Cover photo credit: Pendulum Studios
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Contents
Introduction 1
The Science: How Green Roofs Benefit the Environment and Public Health 2
Stormwater Runoff 2
Temperatures and the Heat Island Effect 3
Building Efficiency 3
Air Quality 4
Weil-Being 5
Green Roofs in Kansas City 6
How Kansas City Is Using Green Roofs 6
Why Kansas City Is Using Green Roofs 7
Water Quality and Stormwater Management 7
Urban Heat Islands 8
Air Quality 8
Methods 11
Analytical Process 11
Tools Used 12
Step 1. Obtain Local Data 13
Step 2. Project Green Roof Growth 14
Step 3. Calculate Water, Heat, and Energy Impacts 15
Step 4. Calculate Emissions Reductions 15
Step 5. Monetize Public Health Benefits to Society 15
Results 17
Water Balance: Runoff from Roofs 17
Heat Exchange 18
Energy Savings 18
Estimated Health Benefits 19
Uncertainty of Results 19
Conclusions 21
References 22
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Introduction
A green roof—also called a vegetated roof or
eco-roof—is a roof with soil and plants placed on
top of a conventional roof. Green roofs are
growing in popularity, as they have proven to be
a cost-effective strategy for creating more livable
and sustainable cities.1
Integrating nature-based solutions like green
roofs into the urban landscape can benefit the
environment, public health, and society by:
How a Green Roof Captures Rainwater
A typical green roof system has a waterproof
membrane, a drainage layer, and a lightweight
soil populated with plants that absorb and
temporarily store rainwater. This moisture
returns to the atmosphere through
evapotranspiration—the process by which water
evaporates from the soil surface or transpires
from plant stomata.
Reducing stormwater runoff.
Lowering ambient air and surface temperatures and reducing the urban heat island effect.2 3
Increasing building efficiency and reducing energy use for heating and cooling.4
Reducing air pollution associated with heating, electric power generation, and temperature-
dependent formation of ground-level ozone.5
Achieving health benefits associated with reducing fine particulate matter (PM2.5) air
pollution.
Improving psychological well-being through access to nature.6
This case study uses the Kansas City metropolitan area, and specifically the city of Kansas City,
Missouri (KCMO), to demonstrate the environmental and health benefits of green roofs.
Companies and municipalities are increasingly turning to nature-based approaches like green
infrastructure to help protect people and infrastructure from extreme temperatures, severe storms,
and chronic droughts. For example, city planners and stormwater managers are implementing green
roofs and other green infrastructure practices as a cost-effective way to manage stormwater where it
falls, reducing polluted runoff and keeping excess stormwater out of the sewer system while also
creating a community amenity. By 2020, green roofs in KCMO could retain 29 inches of annual
stormwater runoff if building developers and parking garage owners continue to install green roofs at
the current growth rate.
The intended audiences of this case study are city planners, regional planning organizations, non-
profits, environmental staff in governors' offices, and other state or local officials who want to learn
about and be able to demonstrate that green roofs have multiple environmental benefits: providing
stormwater management during wet weather events, lowering ambient air temperatures on hot
summer days, and cleaning the air. This information may also be useful for stormwater management
plans, for meeting National Pollutant Discharge Elimination System permitting requirements, or for
Air Quality Management Plans, such as those that may be developed under EPA's Ozone and
Particulate Matter Advance Programs.
1
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The Science: How Green Roofs Benefit the
Environment and Public Health
Stormwater Runoff
Green roofs retain rainwater long enough for the collected moisture to evaporate from the soil and
rooftop vegetation (see Figure 1). During wet weather events, this helps prevent runoff from
overwhelming sewers (and causing sewage to overflow into local streams and lakes), reduce
basement backups, and lower treatment costs and energy usage for treating rainwater that enters
KCMO's combined sewer systems.3 Some green roofs are equipped to harvest rainwater as an
alternative water supply for later use. Rainwater captured from green roofs is usually used for
irrigation, flushing toilets, and for other non-potable purposes.
Heavy rain event
Latent
^ v >-axen
heat
Sunlight
Heavy rain event
Sensible
heat
Heat transfer
into building
Stormw
Reflected
// light
J*
Sunlight
Reflected
light
Sensible
heat
Heat transfer
into building
Stormw
GREEN ROOF
TRADITIONAL ROOF
Figure 1. Heat exchange and water runoff of a green roof versus a traditional roof
3 Stormwater retention is a function of size of storm events and length of preceding dry periods. Over a simulation
year, the net water inflow may not balance outflow due to changes in soil moisture and saturation.
2
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Temperatures and the Heat Island Effect
Temperature management matters in cities, because buildings, roads, and other types of typical
urban infrastructure absorb heat and can make cities much hotter than surrounding rural areas. This
creates an "island" of higher temperatures in the region, a phenomenon known as the urban heat
island effect.2 Air temperatures in urban areas can be 1,8-5.4°F warmer than their surroundings
during the day. In the evening, this difference can be much greater because the built environment
retains heat absorbed during the day.
A large body of evidence shows that green roofs help to reduce local ambient air and surface
temperatures in cities.2 Green roof vegetation can shade buildings and increase evapotranspiration,
, x x , ., , , x which shifts a roofs energy balance (or "budget"). The net
Latent and sensible heat are types „ , ,, , , r „ r , . ,.
, , effect reduces the temperature of the roof and air directly
of energy released or absorbed in
* , .xx, x ¦ r ,x above it during the day and at night. Factors that influence
the atmosphere. Latent heat is felt X1 , , x ,
. „ ., , , , ¦ r the energy budget of a roof (or the balance of incoming
as humidity. Sensible heat is felt as x „ x. , , , ^ ,
and outgoing energy flows) include latent and sensible
chanqes in temperature
\ , x, . heat exchange, shortwave and longwave radiation
Evapotranspiration cools the air. , , ® , x.
exchange, heat conduction, and thermal storage.
Reducing temperatures and the heat island effect can lower people's risk of becoming ill or dying
during an extreme heat event (e.g., a heatwave). Each year, hundreds of Americans die from
extreme heat, and thousands more require medical treatment for critical illnesses such as heat
exhaustion and heat stroke.6
Switching to a green roof decreases heat transmitted into buildings and re-emitted into the
atmosphere. Lowering air and surface temperatures can also reduce the amount of energy needed
to cool buildings, which in turn reduces demand for electricity and cuts the associated waste heat
produced by air conditioning units as well as air pollution produced by power plants. In addition,
lower ambient temperatures reduce the formation of ground-level ozone, as discussed below.
Building Efficiency
A green roof can increase building efficiency and help reduce electricity costs. The soil (growing
medium) provides insulation and the vegetation shades the roof from solar heat, thereby lowering
the temperature of the roof and the air directly above it. This in turn reduces the electricity demand
for air conditioning in summer months. Studies have shown the insulating properties of green roofs
can reduce the transfer of heat from a building's exterior to its interior through the roof (i.e., heat
flux). Heat flux reduction depends on the building and roof insulation and moisture in a green roof's
soil medium. Typically, it can lower the need for air conditioning load to cool a building7 by 10 to 30
percent.
During winter, a green roof acts as an insulator and can reduce demand for heating. However, the
insulating benefits are less significant when the growing medium is moist—typically the case in
winter months.
Electricity savings depends on the local climate, building characteristics, and the design and
maintenance of the green roof. By reducing demand for electricity within a building, a green roof can
also reduce total demand on the regional electric power grid.
3
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Air Quality
By lowering temperatures and reducing energy use, green roofs can help reduce concentrations of
several pollutants that affect air quality, climate, and health.
Criteria air pollutants—such as particle pollution (often referred to as particulate matter or PM),
ground-level ozone (O3), carbon monoxide (CO), sulfur dioxide (SO2), nitrogen oxides (NOx), and
lead (Pb)—lower air quality and can be harmful to human health.b Using fossil fuels to generate
electricity increases levels of these pollutants in the atmosphere. Once emitted, some criteria air
pollutants circulate widely, potentially for long distances.
Some "primary" air pollutants (e.g., PM, CO, SO2, and
NOx), are directly harmful to people and the environment.
Other "secondary" air pollutants form in the air when
primary air pollutants and other precursor air pollutants,
such as volatile organic compounds (VOCs), react or
interact. For example, primary air pollutants such as NOx
and VOCs react under certain weather conditions to form
ozone, a secondary air pollutant. Ozone is a principal
component of photochemical smog that can cause
coughing, throat irritation, difficulty breathing, and lung
damage, and can aggravate asthma.c Another secondary
air pollutant, PM2.5, is of concern because of its
prevalence and links with many respiratory and
cardiovascular illnesses and death.d
Greenhouse gases, orGHGs—such as carbon dioxide
(CO2), methane (CH4), nitrous oxide (N2O),
hydrofluorocarbons (HFCs), and sulfur hexafluoride
(SF6)—trap heat in the atmosphere that would otherwise escape to space, and contribute to climate
change. GHGs from natural sources help keep the Earth habitable, as the planet would be much
colder without them.
Increasing GHG emissions changes the climate system in ways that affect our health, environment,
and economy. For example, climate change can influence crop yields, lead to more frequent
extreme heatwaves, and make air quality problems worse. Methane, a potent GHG, also contributes
to the formation of ground-level ozone, which is a harmful air pollutant and component of smog.
GHGs accumulate and can remain in the atmosphere for decades to centuries, affecting the global
climate system for the long term.
Green roofs can clean the air in three ways: by lowering temperatures, removing pollutants from the
air directly, and preventing additional air pollution. When air temperatures decrease, the rate of
b The Clean Air Act requires EPA to set National Ambient Air Quality Standards for these air pollutants. EPA calls
these pollutants "criteria" air pollutants because it regulates them by developing human health-based and/or
environmentally based criteria (i.e., science-based guidelines) for setting permissible levels.
c Tropospheric ozone also acts as a strong GHG.9
d Different components of PM2.5 have both cooling (e.g., sulfates) and warming (e.g., black carbon) effects on the
climate system.10
A recent study by Fallman et al.8
modeled the ozone reduction effects
of green and cool (light-colored) roofs
in Stuttgart, Germany.
Their 10-day study attributed a 5 to 8
percent decrease in ozone
concentrations during an August heat
wave to green roofs. A simulated
green roof reduced ozone more
effectively than a simulated cool roof
due to an increase of shortwave
reflection emitted from the higher-
albedo cool roof. However, the current
literature is limited, and few studies
consider scenarios of green roofs and
other green infrastructure changes in
different regional climates.
4
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photochemical ozone formation goes down, lowering ozone production. Plant matter on a green roof
can also absorb existing ozone near the rooftop through plants' stomata. By moderating building
temperatures, green roofs help to reduce criteria air pollution and greenhouse gases associated with
heating and cooling buildings, including pollution from electricity generation. Because of this, green
roofs help society avoid and reduce a wide range of air pollutants, creating short-term and long-
lasting benefits for the atmosphere and human health.
Well-Being
Access to nature, both directly and indirectly, can also help improve people's quality of life.11 For
instance, stress contributes to many chronic diseases, and studies show that direct access to nature
can alleviate stress. Adding green design elements such as green roofs to the workplace can result
in lower stress and irritability, higher productivity, and fewer employee absences.12
5
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I
1
Green Roofs in Kansas City
How Kansas City Is Using Green Roofs
Kansas City is continually adding more green roofs to its city's skylines. According to the public
Greenroof and Greenwall Projects Database13 and EPA's conversations with local architecture firms,
Kansas City has installed over 450,000 square feet of green rooftop from 1999 to 2015. KCMO has
at least 16 existing green roof installations and at least three green roof projects under
construction—a total of 19 green roof projects existing or in progress. The city government is
integrating green roofs into some of its own capital improvement projects. If green roof annual
growth continues at the existing rate of 10 percent, KCMO will top 700,000 square feet by 2020.
Kauffman Center for the Performing Arts14'15
Since 2011, the Kauffman Center for the Performing Arts, located in downtown KCMO, has been
harnessing the benefits of green roof technology. At 4.4 acres, the center's green roof is one of the
largest in the country, covering part of the building complex along with a parking garage. It is also the
first permitted green roof stormwater detention facility in Missouri, which allows it to serve as a case
study for the role green roof technology can play in public stormwater permitting. With three
independent drainage systems, the green roof's surface is designed to retain water for its own needs,
and its slope channels excess water into an underground cistern for reuse and recycling. The amount
of water saved through this process is estimated to be equivalent to 84 percent of the city's annual
irrigation demand and saves $56,000 a year in municipal water costs.
The Kauffman Center green roof also promotes a healthy local urban ecosystem. Ninety-five percent
of the roof's landscape materials come from surrounding areas, and certain ground cover plants, such
as switchgrass, provide food for local bird species. Moreover, the ground-level green roof is publicly
accessible as an urban green space for city residents to enjoy. In 2013, Green Roofs for Healthy
Cities awarded this project the Award of Excellence for its category.
Photo credit: Jeffrey L, Bruce 6 Company
Figure 2. Kauffman Center for the Performing Arts
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Kansas City Central Library16
The award-winning green roof at the Kansas City Central Library, installed in 2004 as a retrofit, is as
an example of how green roofs can simultaneously provide functional and recreational benefits. The
installation is home to multiple landscape types that support native species, such as upland grasses,
wetland, and Midwestern prairie. Meanwhile, the green roofs design elements enhance public life, as
skylights and walk-on glass panels channel daylight to indoor patrons, and recreational elements like a
giant chess set invite patrons to enjoy the green roofs outdoor setting.
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Photo credit: Hex FX Aerials
Figure 3. Green roof at the Kansas City Central Library
Why Kansas City Is Using Green Roofs
Given city leaders' commitment to green infrastructure and their desire to improve local water and air
quality, EPA worked with the Mid-America Regional Council (MARC)—the metropolitan planning
organization for the Kansas City metro area—to create this case study to quantify the multiple
benefits of green roofs that address environmental challenges.
In November 2016, MARC partnered with the architecture firm BNIM, Biohabitats, and BikeWalkKC
to host a Green Infrastructure Charrette. More than 60 professionals and community members
participated in an interactive workshop to prioritize green infrastructure goals, build local
partnerships, and commit to implementing key strategies that connect citizens of KCMO with the
surrounding natural environment. This group of environmental professionals, landscape architects,
business developers, and city planners highlighted the need to preserve and protect drinking water,
air quality, and ecosystems.
Water Quality and Stormwater Management
Since 2002, the city has discharged approximately 6.4 billion gallons of untreated sewage each year
into local streams and rivers, including the Missouri River, Fishing River, Blue River, Wilkerson
Creek, Rocky Branch Creek, Todd Creek, Brush Creek, Penn Valley Lake, and their tributaries.17
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As part of a 2010 settlement with EPA, the City of KCMO agreed to make improvements to reduce
its 5.4 billion gallons of annual combined sewer overflow discharges to comply with the Clean Water
Act. These infrastructure improvements include a commitment to use green infrastructure to reduce
stormwater runoff into the city's combined sewer systems.17 Sewer overflows can pose risks to
public health and sanitation, as well as damage city and private property. City planners began to
incorporate green roofs to help control and prevent stormwater runoff that contributes to these
overflows along with other mitigation measures. For example, the Kauffman Center for the
Performing Arts green roof (see Figure 2) functions as a permitted stormwater detention facility.
Urban Heat Islands
In 2014, Kansas City was ranked one of the top 10 U.S. metro areas that experienced intense
summer urban heat islands—measured as the greatest difference between average temperatures in
rural and urban areas over an entire summer.18 The Kansas City metro area was 4.6 degrees
Fahrenheit warmer on average than the surrounding rural area during summer months—ranking it
as the seventh largest differential in the United States. Green roofs can help alleviate the urban heat
island effect.
Air Quality
Missouri and Kansas operate air quality monitors across the Kansas City metro area to ensure that
businesses, states, and localities are doing their part to keep the air clean. While the monitors
indicate that the KCMO area is successfully maintaining air quality below the National Ambient Air
Quality Standards (NAAQS) for ozone and PM2.5, as shown in Figure 4, community leaders are
looking to measures like green roofs to reduce exposure to smog and keep the air clean.
Platte
Leavenworth
Johnson
O Fine particulate matter (PM2 s)
O Nitrogen dioxide (N02)
O Ozone
Landmarks
I I Kansas City metropolitan
area counties
Urban areas
Major highways
KANSAS
Figure 4. Air quality monitoring stations in the Kansas City metro area
8
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Reducing ground-level-ozone (smog)e is an important public health objective for KCMO. KCMO's 8-
hour ozone values are trending downward, and the current 3-year design value (68 parts per billion)
is below the 2015 ozone NAAQS of 70 parts per billion, as Figure 5 shows.'
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Averaging period
—3-year, 8-hour ozone design value 8-hour ozone NAAQS
ppbv: parts per billion by volume
The dotted line indicates the NAAQS, which was lowered to 70 parts per billion in 2015.
Figure 5. Ozone concentrations in the Kansas City metro area
Keeping fine PM levels below the NAAQS is another important public health priority for KCMO
leaders. The Kansas City metro area is currently maintaining PM2.5 concentrations below the
national standard. Air quality monitoring data show that the metro area is in attainment of both the
annual PM2.5 NAAQS (with a design value of 9.4 micrograms per cubic meter) and the 24-hour
PM2.5 NAAQS (with a design value of 21 micrograms per cubic meter) for the most recent 3-year
period, 2013-2015 (Figure 6). Green roofs can help KCMO stay in attainment and continue to meet
these important air quality standards.
e "Smog" and "ground-level ozone" refer to the results of chemical reactions in the atmosphere caused by NOx and
VOCs in the presence of strong sunlight.
f NAAQS require the 8-hour ozone standard, annual PM2.5 standard, and 24-hour PM2.5 standard to use a 3-year
design value to determine whether an area is in attainment.
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2004-2006 2005-2007 2006-2008 2007-2009 2008-2010 2009-2011 2010-2012 2011-2013 2012-2014 2013-2015
Averaging period
3-year PM25
24-hour design value
3-year annual PM2 s Annual PM; s
design value NAAQS
(jg/m3: micrograms per cubic meter
The dotted lines indicate the NAAQS, which are currently 12 (Jg/m3 (annual) and 35 (Jg/m3 (24-hour).
Figure 6. PM2.5 concentrations in the Kansas City metro area
¦ 24-hour PM2
NAAQS
10
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Methods
In collaboration with KCMO staff, a local green
roof architect, and MARC, and in consultation with
the Missouri Department of Natural Resources
and the Kansas Department of Health and
Environment, EPA developed a case study to
demonstrate the environmental and health impacts
of green roofs using credible, free, and easy-to-
use tools for estimating multi-media effects.
Specifically, EPA estimated green roof impacts
related to:
• Stormwater retention.
• Heat exchange, evapotranspiration, and
corresponding heat island reduction.
• Building electricity demand and cost
savings.
• Changes in emissions from the electric
power sector.
• Monetized health benefits from improved
air quality.
The goal of this illustrative case study is to lay out
an analytical framework that a state or municipal
government can use when assessing the effects of
green roofs. Rather than focusing on one green
roof installed on a particular building, EPA
estimated the magnitude of impacts from the total
coverage of green roofs in KCMO for a future
year, 2020. EPA used historical growth rates and
existing green roof data to ascertain the area of
rooftop that could plausibly have green roofs
installed by 2020.
Analytical Process
EPA began by defining the purpose of the
analysis, assessing available tools, and
developing a methodology that can be replicated
in other U.S. locations where data are available.
Figure 7 provides an overview of this
methodology, which consists of five main steps:
1. Obtain local data,
2. Project green roof growth (in square feet,
or ft2)—in this case, through the year 2020.
Step 1: Obtain Local Data
• Building types and numbers
• Existing green roof installations
• Policies that could influence the green roof growth rate
Step 2: Project Green Roof Growth
Start with existing green roof installations (ft2)
Estimate compound growth rate (1999-2015, %/yr)
Apply historical growth rate to future years
Project total installations by 2020 (ft2)
Step 3: Calculate Water, Heat,
and Energy Impacts
Inputs:
• Total surface area covered by green roof in 2020
• Building type
• Growing media depth (2 to 11.5 ft.)
• Leaf Area Index (LAI)
• Presence of irrigation
• Percent roof coverage
• Albedo of existing roof
Green Roof Energy Calculator
Outputs:
• Roof water balance
• Energy balance and heat transfer effects
• Electricity savings
Step 4: Calculate Emissions
Reductions
lnput:Annual electricity savings
(kWh)
Outputs: Avoided PM25, S02,
NOx, and C02 emissions by
power plants within region
Step 5: Monetize Public Health
Benefits to Society
Inputs: Avoided emissions
IUse COBRA to estimate health benefits and apply
valuation functions
Outputs: Potential range of monetized health benefits
Figure 7. Analytical framework for estimating
environmental effects of green roofs
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3. Calculate water, heat, and energy impacts using the Green Roof Energy Calculator.
Calculate emissions reductions, based on energy savings, using EPA's AVoided Emissions
and geneRation Tool (AVERT).
5. Monetize public health benefits to society, using EPA's Co-Benefits Risk Assessment
(COBRA) Health Impacts Screening and Mapping Tool.
Many factors influenced the chosen analysis and results, including the intended audience, the
available tools, and financial resources. Because the intended audience for this technical resource is
broad—policymakers interested in reducing stormwater overflow events, advocates for urban heat
island reduction, state environment departments, municipalities, and metropolitan planning
organizations—EPA chose an analysis that could offer value to a variety of audiences and used a
set of tools that are readily available, peer-reviewed, and free. These tools determined the types of
input datasets and assumptions EPA needed to complete the analysis—in this case, a set of local
input data and reasonable assumptions about green roof characteristics and future green roof
installations. The next section discusses the tools EPA used for this analysis.
Tools Used
In assessing potential tools for this analysis, EPA looked for free, credible, already available tools
that could estimate the multi-media effects of green roofs in a city like KCMO. EPA chose to use
three tools for this analysis: the Green Roof Energy Calculator^ EPA's AVERT,h and EPA's
COBRA.1
The national Green Roof Energy Calculator, co-developed by the University of Toronto and Portland
State University with Green Roofs for Healthy Cities, has annual building energy performance
datasets for more than 100 North American cities. This free online tool compares the estimated
annual energy performance of a commercial or residential building with a green roof against the
estimated performance of the same building with a conventional roof. These comparisons allow non-
experts to obtain quick estimates of how green roof design decisions might affect building energy
use. The built-in assumptions of the online calculator originate from a more complex whole-building
energy simulation model, the Department of Energy's EnergyPlus model, and actual measurements
of roof surface data, soil moisture, and other variables from specific green roofs that have been
studied. This combination of direct measurements and modeling data drives the tool's estimates of
heating, ventilation, and air-conditioning energy use.
EPA used the Green Roof Energy Calculator to compare the electricity savings, heat flux,
evapotranspiration, and net stormwater runoff of a building with a green roof against existing office
buildings and apartment buildings with conventional roofs.>
g The Green Roof Energy Calculator can be found at the following link: https://sustainabilitv.asu.edu/urban-
climate/qreen-roof-calculator/
h AVERT can be found at the following link: https://www.epa.gov/avert
' COBRA can be found at the following link: https://www.epa.qov/statelocalenerqy/co-benefits-risk-assessment-cobra-
health-impacts-screeninq-and-mappinq-tool
1 Medium-sized office buildings are generally those that have three to five floors and are 53,630 ft2. Medium-sized
apartment buildings have four to six floors and are 33,600 ft2.
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EPA then took the electricity demand savings from the Green Roof Energy Calculator and entered
the kilowatt-hour savings into AVERT.k AVERT can estimate the avoided NOx, SO2, PIVh.sand CO2
emissions at power plants due to lower demand on the electricity grid. AVERT divides the country
into 10 regions (KCMO is in the Lower Midwest region) and produces county, state, and regional
results in pounds or tons, per month or per year. In this case study, EPA calculated annual
emissions avoided at power plants throughout Kansas and Missouri due to a 2020 projected green
roof installation scenario in KCMO.
Next, EPA used COBRA to estimate the monetized health benefits likely to result from the emissions
reductions from the green roof scenario. COBRA includes a reduced-form air quality model (i.e., a
relatively simple air quality model) to estimate how changes in emissions in a given county can affect
ambient air quality in the surrounding region. It also includes functions to estimate how changes in
ambient air quality impact health outcomes, such as premature mortality, hospitalizations, nonfatal
heart attacks, asthma exacerbations, and lost work and school days.
Step 1. Obtain Local Data
The first step in the process is to ask local green roof architects and municipal, state, and regional
planners for locally based information on 1) the types and number of buildings in the area with
existing green roofs, 2) any buildings undergoing green roof construction, and 3) policies in place
that provide incentives for green roofs that could affect the future growth rate of green roof
installations.
To complete the analysis for Kansas City, EPA obtained data on building types and numbers from
MARC, which maintains GIS datasets and maps of existing buildings in the nine-county Kansas City
metro area. MARC supplied EPA with the number of existing buildings in eight of the nine counties
and aggregated the total rooftop area (ft2) for six distinct building types.' This information helped EPA
determine the number of rooftops that could potentially be converted to green roofs. EPA gathered
information on existing green roof installations from city government officials and local green roof
architects. Based on information EPA collected from the Greenroof and Greenwall Project
Database13 and conversations with local architecture firms, EPA found that KCMO has at least 16
existing green roof installations with vegetation covering 450,000 ft2 of rooftop. The average
vegetative coverage per rooftop for these projects is 60 percent. The City of Kansas City also has
three green roof projects under construction, making a grand total of 19 green roof projects existing
or in progress within the metro area.
While KCMO does not have a green roof policy or direct incentives on the books, it does have
policies that can indirectly support future green roof installations. The KCMO 2008 Climate
Protection Plan19 recommends promoting green roofs. In January 2017, plans for a $75 million
development featuring apartments, a boutique hotel, and greenspace on top of a parking garage in
Westport received strong support from the City Plan Commission, a Kansas City citizens advisory
group.20
k AVERT uses gigawatt-hours for energy savings impacts. EPA rounded its inputs up to 1.0 gigawatt-hour of savings
and assumed savings affected 100% of all hours for this case study.
' The six building types within MARC's GIS dataset for this project are commercial, condo, industrial/business park,
multi-family, office, and public/semi-public.
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In addition, recent energy and water use benchmarking requirements, under the City Council's
Energy Empowerment Ordinance (June 2015) will be helpful in assessing building electricity
consumption data, both before and after a green roof installation. The ordinance requires owners of
large buildings to benchmark and report their energy and water usage by May 1st of 2016, 2017, or
2018, depending on their building type.21 These data, combined with green rooftop direct
measurements (such as heat flux and evapotranspiration estimates) and simulated estimates from
the national Green Roof Energy Calculator, are expected to provide a more comprehensive dataset
for future study.m
Table 1. Green roof calculator inputs
Input
KCMO Value
Total surface area of green roofs in 2020
734,826 ft2
Building type
Existing office buildings
Growing media depth (2-11.5 inches)
4 (typical for the type of vegetation in the Kansas City area)
Leaf area index (LAI)
5 (typical for extensive green roofs)
Whether there is irrigation
No irrigation
Percent roof coverage
100%*
Albedo of existing roof
Dark (0.15)
* The user may choose to enter either total roof coverage or total green roof coverage. EPA entered 100 percent as the total
known amount of green roof coverage. If EPA had used total roof area and estimated what percentage of that area was
"green," the average coverage for Kansas City's green roofs would have been 60 percent of total roof area.
Step 2. Project Green Roof Growth
After collecting local data, the next step is to establish a 2020 green roof projection scenario. For
Kansas City, EPA analyzed green roof installation data from 1999 to 2015 and calculated a historical
compound annual growth rate of 10.3 percent. EPA then applied this growth rate over a 5-year
period, starting with the total amount of green roof area installed in 2015. Figure 8 shows actual
green roof installations and projected growth of KCMO's green roofs from 1999 to 2020.
m Note that attributing the energy savings to one measure can be difficult if other changes in energy efficiency,
behavior, or occupancy are occurring at the same time. Using a model such as the Green Roof Energy Calculator in
conjunction with measuring green roof heat flux, evapotranspiration, and actual energy consumption offers a way to
cross-reference the energy impacts associated with green roofs.
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800,000
700,000
600,000
% 500,000
C5
B
lm
<
400,000
s
o
CJ
u
o
| 300,000
£
200,000
100,000
1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020
Installation Year
Figure 8. Green roof installations and projected growth in KCMO, 1999-2020
Step 3. Calculate Water, Heat, and Energy Impacts
After estimating the total square footage of green roof installation in 2020, the next step is to enter
the information into the Green Roof Energy Calculator. Typical green roof characteristics are also
needed to run the calculator. EPA consulted with the developer of this tool and a related journal
article to determine what green roof characteristics to enter into the calculator for Kansas City.4 In
other cases, more relevant local data may be readily available.
Table 1 presents key inputs that EPA gathered to run the Green Roof Energy Calculator.
Step 4. Calculate Emissions Reductions
The next step is to take the energy savings from Step 3 and input them into AVERT to determine
avoided emissions of air pollutants from power plants. Kansas City is in AVERT's Lower Midwest
region, which includes Kansas; western Missouri; Oklahoma; and parts of Arkansas, Louisiana, New
Mexico, and Texas. Table 6 (under "Results," below) shows annual avoided emissions for the entire
Lower Midwest region as a result of green roofs in KCMO.
Step 5. Monetize Public Health Benefits to Society
The final step is to quantify the dollar value of the avoided health effects due to the avoided
emissions from power plants. The county-level emissions reductions of PM2.5, NOx, and SO2
estimated within AVERT's Lower Midwest region were entered into COBRA to estimate the public
health benefits. The emissions reductions from AVERT were entered into COBRA at the county level
for the Fuel Combustion from Electric Utilities emissions tier one, using the 2017 emissions
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baseline." COBRA includes valuation functions to estimate the monetary value of the benefits of
reducing emissions. The default health impacts and valuation functions in COBRA are consistent
with the ones used in EPA Regulatory Impact Analyses.22
" Note that COBRA does not include a 2020 emissions baseline, but this analysis assumes that the 2017 baseline is
representative for 2020.
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Results
This section provides results from the Green Roof Energy Calculator, AVERT, and COBRA.
The Green Roof Energy Calculator estimates the following metrics:
Annual roof water balance.
Average latent heat exchange to urban environment.
Average sensible heat exchange to urban environment.
Building electricity savings and electricity cost savings.
AVERT estimates the following information:
Annual and monthly PM2.5, NOx, SO2, and CO2 emissions impacts.
Annual electric power generation impacts.
Regional, state, and county-level estimates.
COBRA estimates the following changes between baseline and control scenarios:
Changes in air quality (i.e., PM concentration).
Corresponding health effects (incidence and monetized values).
Estimates of the economic value in the number of cases for each health effect.
Water Balance: Runoff from Roofs
The Green Roof Energy Calculator shows that green roofs typically retain stormwater runoff better
than conventional roofs during wet weather (Table 2). For this Kansas City scenario, green roof
systems could retain up to 29 inches of stormwater per year on average.0 Instead of running off into
storm drains, this water is absorbed by soil and plants on the roof and eventually returned to the air
through evapotranspiration directly above the roofs surface.
Less runoff helps prevent stormwater from overwhelming sewers and causing overflows of sewage
into local waterbodies, reduces basement backups, and lowers treatment costs by reducing energy
usage needed to treat rainwater that enters KCMO's combined sewer system. Because water
balance dynamics are sensitive to growing media composition, compaction, and soil saturation, net
water runoff results should be considered an order-of-magnitude estimate.
Table 2. Annual roof water balance for KCMO
Conventional Roof Balance (Inches)
Green Roof System Balance (Inches)
Precipitation
32.3
32.3
Evapotranspiration
N/A
31.4
Net runoff
32.3
3.3
° If the total green roof area is only a fraction of the total surface area of the city, then the effective runoff reduction at
the city scale would be smaller.
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Heat Exchange
Latent heat is what we feel as humidity. Table 3 shows latent heat exchange from green roofs,
measured in watts per square meter of surface area (W/m2). Because latent heat exchange does not
occur on a conventional roof, the results of the green roof calculator show "not applicable" (N/A) for
conventional roofs.
Table 3. Average latent heat exchange to the urban environment for KCMO roofs
Conventional Roof (W/m2)
Green Roof System (W/m2)
Annual average
N/A
57.4
Summer average
N/A
66.9
Summer daily peak average
N/A
214.8
Sensible heat is the temperature difference between the rooftop surface and the surrounding air.
The Green Roof Energy Calculator estimates lower sensible heat exchange values (W/m2) for the
green roof versus the dark conventional roof because the green roof produces higher levels of latent
heat (Table 4). In other words, green roofs create a cooling effect because sensible heat exchange
decreases as latent heat exchange increases, shifting the rooftop's energy budget.
Table 4. Average sensible heat exchange to the urban environment for KCMO roofs
Conventional Roof (W/m2)
Green Roof System (W/m2)
Annual average
51.8
27.2
Summer average
92.7
33.4
Summer daily peak average
348.5
90.3
Energy Savings
The Green Roof Energy Calculator estimates the building energy consumption savings due to the
insulating and cooling effects of a green roof. These results are based on a green roof module
developed in the Department of Energy's EnergyPlus building energy simulation software. Table 5
shows the amount of electricity savings, cost savings (lower electricity bills), and natural gas savings
for the KCMO green roof scenario, which reflects the total savings from green roofs installed across
KMCO.
Table 5. Annual building energy consumption
savings for total green roof systems in KCMO
Electricity savings
601,502 kilowatt-hours
Electricity cost savings
$41,587
Gas savings
2,930 therms
Lower Emissions
Table 6 shows annual avoided emissions for the entire Lower Midwest region as a result of green
roofs in KCMO. As a result of more green roofs installed in KCMO, Table 7 shows county-level
emissions reductions in Kansas and Missouri, where AVERT estimates that nine counties have
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electric generating units. These nine counties would experience reductions totaling 734 pounds of
SO2, 384 pounds of NOx, and 269 tons of CO2 avoided in 2020. The remaining reductions would
take place in other states in the Lower Midwest region.
Table 6. Annual avoided air pollutants across the Lower Midwest AVERT region
as a result of KCMO green roofs
Air Pollutant
Total Avoided Air Pollutant Emissions in 2020
(Annual)
SO2
2,690 lbs/year
NOx
1,800 lbs/year
in
o\i
CL
90 lbs/year
CM
O
O
1,150 tons/year
Table 7. Annual avoided air pollutants in Kansas and Missouri counties
Geographic Location
Avoided Air Pollution from Power Plants in 2020
(County, State)
S02 (lbs)
NOx (lbs)
PM2.5 (lbs)
CO2 (tons)
Pottawatomie, Kansas
120
110
10
120
Sedgwick, Kansas
—
40
—
10
Shawnee, Kansas
50
10
—
10
Wyandotte, Kansas
70
40
—
10
Greene, Missouri
60
30
—
20
Henry, Missouri
150
50
10
30
Jackson, Missouri
140
60
10
30
Platte, Missouri
N/A
20
—
20
Scott, Missouri
60
10
—
10
Estimated Health Benefits
The county-level emissions reductions from AVERT's Lower Midwest region were entered into
COBRA to estimate the range of monetized health benefits. COBRA reflects reductions in premature
mortality, hospital admissions, emergency department visits, asthma exacerbation, respiratory
symptoms, acute bronchitis, and missed days of school or work. Based on these reductions in
adverse health outcomes, COBRA estimates a range of economic benefits to society from $35,500
to $80,500 (in $2017 using a 3 percent discount rate) in 2020. Public health benefits from reducing
NOx as an ozone precursor are not included.
Uncertainty of Results
There are inherent uncertainties associated with the modeling results of this case study. Like any
modeling exercise, it involves a mixture of direct measurements, reasonable methodological
assumptions, and data probabilities to arrive at the estimates. Nonetheless, EPA used these models
because they are freely accessible, provide credible estimates, have been extensively cited in peer-
reviewed literature, and/or were benchmarked against empirical data and/or more sophisticated
models.
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The analysis also involves simplifying assumptions that affect the case study's results. First, green
roof projections of future green roof installations in KCMO assume a continuation of historical growth
trends. Second, due to the interconnectedness of the electricity grid, not all of the avoided emissions
within the Lower Midwest region would necessarily affect the Kansas City area. In addition, because
PM2.5 and precursors are regional pollutants, not all of the health benefits from avoided emissions
would accrue to residents of KCMO or neighboring communities.
These results should be considered a first-order approximation intended to provide a ballpark
estimate of the benefits of green roofs in KCMO. They are not meant to be used for regulatory
purposes to comply with the U.S. EPA's Clean Water Act combined sewer overflow regulations or
NAAQS established under the Clean Air Act.
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Conclusions
Green roofs can contribute to KCMO's environmental and livability goals—to mitigate the urban heat
island effect, maintain clean air and water, and lower energy costs in buildings—while greening the
urban landscape. As this methodology demonstrates, city planners, environmental regulators, and
other practitioners can estimate the environmental and public health benefits of green roofs using
free, credible, accessible tools. Because of the multiple benefits green roofs provide, they are
gaining traction from a diverse set of stakeholders and businesses.
Interested parties nationwide can apply these methods and point to other evidence-based studies to
estimate the value of green roofs and other green design practices in their areas. Using this
methodology to quantitatively demonstrate the benefits of green roofs provides tangible data to
decision-makers who have the power to implement green roofs as a strategy for achieving local
environmental and public health goals.
Aside from quantifying the benefits of green roofs, cities are pursuing ways to encourage green roof
adoption, including voluntary incentives and regulatory mandates. According to Green Roofs for
Healthy Cities, the North American green roof industry experience an estimated 10.3% growth in
2016 over 2015. Many cities have enacted policies that encourage green roof development through
rebate programs, tax incentives, or fast-track permitting programs.23 Cities that have implemented
these policies—including Washington, D.C.; Toronto, Ontario; Philadelphia, Pennsylvania; Seattle,
Washington; and Chicago, Illinois—also reported the largest square footage of green roof
installations in 2016.24
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References
1. U.S. General Services Administration. (2011). The benefits and challenges of green roofs on
public and commercial buildings: A report of the General Services Administration.
https://www.qsa.qov/portal/qetMediaData?mediald=158783.
2. U.S. Environmental Protection Agency. (2008). Reducing urban heat islands: Compendium
of strategies, https://www.epa.gov/sites/production/files/2014-
06/documents/qreenroofscompendium.pdf.
3. Sailor, D.J. (2008). A green roof model for building energy simulation programs. Energy and
Buildings, 40(8), 1466-1478.
Sailor, D.J., and Bass, B. (2014). Development and features of the Green Roof Energy
Calculator. Journal of Living Architecture, 1(3), 36-58.
5. U.S. Environmental Protection Agency. (2016). Heat island effect, http://www.epa.gov/heat-
islands.
6. U.S. Environmental Protection Agency and Centers for Disease Control and Prevention.
(2016). Climate change and extreme heat: What you can do to prepare. EPA 430-R-16-061.
https://www.epa.gov/climatechanqe/extreme-heat-quidebook.
Becker, D., and Wang, D. (2011). Green roof heat transfer and thermal performance
analysis. Carnegie Mellon University.
Fallmann, J., Forkel, R., and Emeis, S. (2016). Secondary effects of urban heat island
mitigation measures on air quality. Atmospheric Environment, 125(A), 199-211.
9. U.S. Environmental Protection Agency. (2016). Health effects of ozone pollution.
https://www.epa.gov/ozone-pollution/health-effects-ozone-pollution.
10. U.S. Environmental Protection Agency. (2016). Health and environmental effects of
particulate matter (PM). https://www.epa.gov/pm-pollution/health-and-environmental-effects-
particulate-matter-pm.
11. Miller, N.G., Pogue, D., Gough, Q.D., and Davis, S.M. (2009). Green buildings and
productivity. Journal of Sustainable Real Estate, 7(1), 65-89.
12. Grahn, P., and Stigsdotter, U.K. (2010). The relation between perceived sensory dimensions
of urban green space and stress restoration. Journal of Landscape and Urban Planning, 94,
264-275.
13. greenroofs.com. (2017). The Greenroof and Greenwall Projects Database.
h ttp ://www. g re e n ro ofs. co m/p ro i e cts/.
14. Green Roofs for Healthy Cities, (n.d.). Kauffman Performing Arts Center. Details previously
available at https://greenroofs.org/awards-of-excellence/.
15. greenroofs.com. (2017). Kauffman Performing Arts Center and District Garage.
http://www.greenroofs.com/proiects/pview.php?id=1575.
16. Roofmeadow. (n.d.). Complete project list, http://www.roofmeadow.com/case-
studies/complete-proiect-list/.
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17. U.S. Environmental Protection Agency. (2010). Kansas City, Missouri Clean Water Act
settlement, https://www.epa.gov/enforcement/kansas-citv-missouri-clean-water-act-
settlement.
18. Kenward, A., Yawitz, D., Sanford, T., and Wang, R. (2014). Summer in the city: Hot and
getting hotter Climate Central. http://assets.climatecentral.orq/pdfs/UrbanHeatlsland.pdf.
19. City of Kansas City, Missouri. (2008). Climate protection plan.
httpV/kcmo.qov/citvmanaqersoffice/wp-content/uploads/sites/l 1/2013/11/Citv-Climate-
Protection-Plan.pdf.
20. Horsley, L. (2017, June 20). Plan advances for apartments, hotel, green roof on garage in
Westport. The Kansas City Star, https://www.kansascitv.com/news/politics-
qovernment/articlel 57169374.html.
21. City of Kansas City, Missouri. (2017). Energy Empowerment Ordinance (benchmarking).
http://kcmo.oov/kcoreen/benchmarkinq/.
22. U.S. Environmental Protection Agency. (2018). User's manual for the Co-Benefits Risk
Assessment (COBRA) screening model, https://www.epa.gov/statelocalenergy/users-
manual-co-benefits-risk-assessment-cobra-screening-model.
23. Green Roofs for Healthy Cities. (2015). 2014 annual Green Roof Industry Survey.
24. Green Roofs for Healthy Cities. (2017, July 13). 13th Annual Green Roof Industry Survey
shows double-digit growth in 2016. Toronto pushes Washington, DC out of top spot for most
green roofs installed.
https://static1.sguarespace.eom/static/58e3eecf2994ca997dd56381/t/5967890d099c012687
ae59d0/1499957518010/GreenRoofSurvev Results Release Julv13 FINAL.pdf.
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