September 2003 
     
     The Energy Coordinating Agency (ECA) in Philadelphia initiated the Cool Homes
     Program to help elderly residents escape extreme summertime heat. ECA installs
     cool roofs and uses other measures to reduce indoor temperatures to promote comfort
     and minimize health risks. As of April 2003, the Cool Homes Program had installed
     over 450 roofs.
     
     Cool Roofs in Action 
     For millions of Americans living in and around cities, elevated summertime
     temperatures are of growing concern.
     Commonly referred to as urban heat islands, this phenomenon can impact
     communities by increasing peak energy demand, 
     air conditioning costs, air pollution levels, and heat-related illness and mortality.
     Fortunately, there are common-sense measures that communities can take to reduce
     the negative effects of heat islands. 
     
     What Is a Heat Island?
     Heat islands are characterized by urban air and surface temperatures that are higher
     than nearby rural areas. Many U.S. cities and suburbs have air temperatures up to
     10̊ F (5.6̊ C) warmer than surrounding natural land cover. The heat island sketch
     below shows a city's heat island profile. It demonstrates how temperatures typically
     rise from the urban-rural border, and that the warmest temperatures are in dense
     downtown areas. (Image of temperature increase over a typical city landscape.)
     
     What Causes Heat Islands?
     Heat islands form as cities replace natural land cover with pavement, buildings, and
     other infrastructure. These changes contribute to higher urban temperatures in the
     following ways:
     
     • Displacing trees and vegetation minimizes the natural cooling effects of shading
     and evaporation of water from soil and leaves (evapotranspiration).
     
     • Tall buildings and narrow streets can heat air that is trapped between them and
     reduce wind flow. 
     
     • Waste heat from vehicles, factories, and air conditioners may add warmth to the air,
     further increasing temperatures.
     
     Heat islands are also influenced by a city’s geography and prevailing weather
     conditions. For example, strong winds and rain can flush out hot, stagnant air from
     city centers, while sunny, windless conditions can exacerbate heat islands.
     
     When Do Heat Islands Form? 
     Heat islands can occur year-round during the day or night. Urban-rural temperature
     differences are often largest during calm, clear evenings. This is because rural areas
     cool off faster at night than cities, which retain much of the heat stored in roads,
     buildings, and other structures. 
     
     How Do Heat Islands Affect Us? 
     Increased urban temperatures can affect public health, the environment, and the
     amount of energy that consumers use for summertime cooling. 
     
     Public Health: Heat islands can amplify extreme hot weather events, which can
     cause heat stroke and may lead to physiological disruption, organ damage, and even
     death – especially in vulnerable populations such as the elderly. 
     
     The Environment: Summertime heat islands increase energy demand for air
     conditioning, raising power plant emissions of harmful pollutants.  Higher
     temperatures also accelerate the chemical reaction that produces ground-level ozone,
     or smog. This threatens public health, the environment, and, for some communities,
     may have implications for federal air quality goals.
     
     Energy Use: Because homes and buildings absorb the sun’s energy, heat islands can
     increase the demand for summertime cooling, raising energy expenditures. For every
     1̊F (0.6̊C) increase in summertime temperature, peak utility loads in medium and
     large cities increase by an estimated 1.5 – 2.0 percent.  Cities in cold climates may
     actually benefit from the wintertime warming effect of heat islands. Warmer
     temperatures can reduce heating energy needs and may help melt ice and snow on
     roads.  In the summertime, however, the same city may experience the negative
     effects of heat islands.
     
     Heat islands are often largest over dense development but may be broken up by
     vegetated sections within an urban area.
     
     Ozone forms when precursor compounds react in the presence of sunlight and high
     temperatures.
     
     Both types of green roofs can be used on residences, industrial facilities, offices, and
     other commercial property. Green roofs are widespread in Europe and Asia, and are
     becoming more common in the United States. 
     
     Cool Pavement 
     Pavements with low  solar reflectance absorb large amounts of heat and can be up to
     70̊ F (40̊ C) hotter in the sun than  cooler alternatives. Portland cement concrete –
     commonly called “concrete” and “asphalt,” respectively – are the most common
     paving materials for sidewalks and streets. Most new concrete has a solar reflectance,
     or albedo, of 35-40 percent; the solar reflectance of fresh asphalt is typically 5-10
     percent.  Over time, the albedo of these pavements change. Concrete darkens from
     the build-up of tire residue, dirt, and oil, and asphalt lightens as the asphalt binder
     wears away to expose the underlying rock aggregate. To maximize the albedo of
     both types of pavement, lighter-colored aggregate can be used in the pavement mix.
     Alternatively, asphalt pavements can be covered with high-albedo seal coats, small
     rocks set in binder, or a thin layer of concrete. For concrete applications, using
     lighter-colored sand and cement can increase reflectivity.
     
     Permeable, or porous, pavements allow water to percolate and evaporate, cooling the
     pavement surface and surrounding air. Permeable pavements can be constructed
     from a number of materials including concrete, asphalt, and plastic lattice structures
     filled with soil, gravel, and grass.  Although there is no official standard or labeling
     program to designate cool paving materials, communities interested in reducing the
     heat island effect may consider surface reflectivity and permeability – along with
     other costs and benefits – when selecting a paving product. 
     
     What is EPA Doing to Reduce Heat Islands? 
     Through its Heat Island Reduction Initiative (HIRI), EPA works with community
     groups, public officials, industry representatives, researchers, and other stakeholders
     to identify opportunities to implement heat island reduction strategies and evaluate
     their impacts on energy demand, local meteorology, air quality, health, and other
     factors.
     
     For More Information:
     The Lawrence Berkeley National Laboratory's Heat Island Group 
     http://heatisland.lbl.gov 
     
     International Council for Local Environmental Initiatives’ Hot Cities Information 
     www.hotcities.org
     
     Cool Roof Rating Council
     www.coolroofs.org 
      
     USDA Urban and Community Forestry Program
     www.fs.fed.us/ucf 
      
     Green Roofs for Healthy Cities 
     www.greenroofs.ca/grhcc 
     
     U.S. Green Building Council 
     www.usgbc.org 
     
     Center for Green Roof Research 
     http://hortweb.cas.psu.edu/research/greenroofcenter
      
     EPA’s Heat Island Reduction Initiative 
     www.epa.gov/heatisland 
     
     EPA Global Warming Information 
     www.epa.gov/globalwarming 
     
     ENERGY STAR Qualified Cool Roof Products 
     www.energystar.gov/products 
      
     NASA’s Global Hydrology and Climate Center (GHCC) 
     www.ghcc.msfc.nasa.gov 
     
     Global Warming 
     
     What Can Communities Do to Reduce the Heat Island Effect? 
     Communities interested in reducing heat islands have several options.  Strategies to
     lower urban temperatures and achieve related benefits include installing reflective
     cool roofs on residential and commercial buildings; planting trees and vegetation,
     including green roofs; and using cool paving materials for roads, sidewalks, and
     parking lots.  Additional heat mitigation options include modifying urban design and
     layout, and choosing efficient heating and cooling systems.  Widespread
     implementation across a community can reduce urban temperatures, energy use, air
     pollution, and heat-related health impacts. Heat island reduction strategies also
     benefit individual home and building owners directly.  Cool roofs and shade trees,
     for example, can save money on summertime cooling bills.  
     
     Cool Roofs
     The term “cool roof” describes roofing materials that have a high solar reflectance.
     This characteristic reduces heat transfer to the indoors and can enhance roof
     durability. Cool roofs may also have high emittance, releasing a large percentage of
     the solar energy they absorb.  On a hot, sunny, summer day, traditional roofing
     materials can reach peak temperatures of 190̊ F (88̊ C). By comparison, cool roofs
     reach maximum temperatures of 120̊ F (49̊ C).  In buildings with air conditioning
     (AC), cool roofs can save money on energy bills, lower peak energy demand, and
     reduce air pollution and greenhouse gas emissions. In buildings without AC, cool
     roofs can increase indoor occupant comfort by lowering top-floor temperatures. In
     both cases, cool roofs can help reduce urban heat islands.
     
     Types of Cool Roofs
     • Commercial (low slope): Most cool roof applications for low-slope, primarily
     commercial, buildings have a smooth, bright whitesurface to reflect solar radiation
     and achieve related benefits.
     • Residential (steep slope): Most cool roof applications for sloped, primarily
     residential, buildings come in various colors and may use special pigments to reflect
     the sun's energy. 
     
     EPA’s ENERGY STAR® program has voluntary product specifications for both
     commercial and residential roofs. Low-slope roofs must have an initial solar
     reflectance of at least 65 percent, and steep-slope roofs must have an initial solar
     reflectance of 25 percent or more.  Emittance is not a qualifying criterion for the
     ENERGY STAR label, but a high rating can further reduce energy costs.
     
     Community-Level Benefits from Cool Roofs 
     Installing cool roofs across a city can provide substantial energy savings. The figure
     on the next page illustrates this potential for 11 U.S. cities according to research
     conducted at the Department of Energy’s Lawrence Berkeley National Laboratory
     (LBNL). 
     
     
     The albedo, or solar reflectance, of a surface is the percentage of incoming solar
     radiation that is reflected by that surface.  Albedo is measured on a scale of 0 to 1,
     where a value of 0 indicates that a surface absorbs all solar radiation and a value of 1
     represents total reflectivity.  Light-colored surfaces typically have higher albedos
     than darker surfaces. While a traditional black shingle has an average albedo of
     0.05, or 5 percent, the average albedo for a white roof coating is 0.75, or 75 percent.
     
     The emittance of a material refers to its ability to release absorbed heat. Scientists
     use a number between 0 and 1 to express emittance. With the exception of metals,
     most construction materials have emittances above 0.85, or 85 percent.
     
     Factors Affecting Building-Level Energy Savings from a Cool Roof
     •Air conditioning: Cool roofs can reduce summertime energy use in air-conditioned
     buildings. In buildings without air conditioning, cool roofs can improve comfort by
     reducing top-floor temperatures. 
     
     • Local climate: Cooling energy savings are typically greatest in areas with long,
     sunny, and hot summers.
     
     • Building height: Cool roofs are generally most effective on one-or two-story
     buildings with large roof areas. They provide less energy savings for multi-story
     buildings with small roofs. 
     
     [Photo of the Utah Olympic Oval] Caption: The Utah Olympic Oval used cool roof
     technology.
     
     Trees and Vegetation in Action:
     The City of Austin, Texas’s Neighbor Woods program uses aerial photos to identify
     neighborhoods with insufficient tree coverage. Austin Energy, the city-owned utility,
     then provides residents with free saplings that will ultimately provide shade, beauty,
     and energy savings. 
     
     
     Trees and Vegetation
     Increasing a city’s vegetative cover by planting trees, shrubs, and vines is a simple
     and effective way to reduce the heat island effect. Scientists at LBNL estimate that
     planting trees and vegetation for shade can reduce a building’s cooling energy
     consumption by up to 25 percent annually.  In addition to direct shading, trees and
     vegetation cool the air through evapotranspiration. Urban vegetation also provides
     economic, environmental, and social benefits such as enhanced storm water
     management and reduced air pollution.
     
     Where to Plant 
     Strategically placed shade trees and vegetation block the sun's rays, minimizing heat
     transfer to building interiors, and reducing the need for air conditioning. In most U.S.
     cities, trees should shade the east, and especially west, walls to maximize cooling
     savings. Planting trees directly to the south may provide little shade in the
     summertime and block desired sun in the wintertime. 
     
     What to Plant 
     Deciduous trees work well as they balance energy requirements over the course of a
     year. In summer, foliage cools buildings by blocking solar radiation. In winter, after
     the leaves have fallen, the sun's energy passes through the trees and helps to warm
     buildings.
     
     Green Roofs
     Another alternative to traditional roofing materials is a rooftop garden or "green
     roof." Installed widely in a city, green roofs contribute to heat island reduction by
     replacing heat-absorbing surfaces with plants, shrubs, and small trees that cool the
     air through evapotranspiration. Planted rooftops remain significantly cooler than a
     rooftop constructed from traditional heat-absorbing materials. In addition, green
     roofs reduce summertime air conditioning demand by lowering heat gain to the
     building. 
     
     Green roofs consist of soil and vegetation planted over a water proofing layer. They
     can be intensive or extensive depending on the amount of soil and plant cover, and
     whether the roof is accessible. 
     
     • Intensive green roofs require a minimum of one foot of soil. Trees and shrubs are
     usually planted, adding 80-150 pounds per square foot of load to the building. These
     roofs need complex irrigation and drainage systems, and significant maintenance.
     Intensive roofs are often accessible to the public.
     
     • Extensive green roofs require only 1-5 inches of soil. Low lying plants and grasses
     are usually planted, and 12-50 pounds per square foot of load may be added. These
     roofs use simple irrigation and drainage systems, and require little maintenance.
     Extensive green roofs usually are not accessible to the public. 
     
     Green Roofs in Action 
     The City of Chicago installed a 20,300 square foot green roof on its City Hall. The
     city expects the roof to reduce annual air conditioning costs by $4,000. Businesses
     such as the Gap and Ford Motor Company have also installed green roofs on their
     corporate headquarters buildings.
     
     Trees provide a variety of benefits, from cooling the air to stabilizing the soil.  Green
     roofs remain significantly cooler than rooftops made of traditional heat-absorbing
     material.