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United States Government Accountability Office: 
GAO: 

Report to the Chairman, Subcommittee on Oversight, Committee on 
Environment and Public Works, U.S. Senate: 

May 2011: 

Air Quality: 

Information on Tall Smokestacks and Their Contribution to Interstate 
Transport of Air Pollution: 

GAO-11-473: 

GAO Highlights: 

Highlights of GAO-11-473, a report to the Chairman, Subcommittee on 
Oversight, Committee on Environment and Public Works, U.S. Senate. 

Why GAO Did This Study: 

Tall smokestacks-—stacks of 500 feet or higher, which are primarily 
used at coal power plants—-release air pollutants such as sulfur 
dioxide (SO2) and nitrogen oxides (NOx) high into the atmosphere to 
help limit the impact of these emissions on local air quality. Tall 
stacks can also increase the distance these pollutants travel in the 
atmosphere and harm air quality and the environment in downwind 
communities. The 1977 amendments to the Clean Air Act encourage the 
use of pollution control equipment over dispersion techniques, such as 
tall stacks, to meet national air standards. Section 123 of the Act 
does not limit stack height, but prohibits sources of emissions from 
using the dispersion effects of stack heights in excess of a stack’s 
good engineering practice (GEP) height to meet emissions limitations. 

GAO was asked to report on (1) the number and location of tall stacks 
of 500 feet or higher at coal power plants and when they began 
operating; (2) what is known about such stacks’ contribution to the 
interstate transport of air pollution and the pollution controls 
installed at plants with these stacks; and (3) the number of stacks 
that were built above GEP height since 1988 and the reasons for this. 
GAO analyzed Energy Information Administration (EIA) data on power 
plants, surveyed states with tall stacks, and interviewed experts on 
the transport of air pollution. GAO is not making recommendations in 
this report. The Environmental Protection Agency and the Department of 
Energy stated they had no comments on this report. 

What GAO Found: 

According to analysis of EIA data, which were updated with GAO’s 
survey results, a total of 284 tall smokestacks were operating at 172 
coal power plants in 34 states, as of December 31, 2010. Of these 
stacks, 207 are 500 to 699 feet tall, 63 are 700 to 999 feet tall, and 
the remaining 14 are 1,000 feet tall or higher. About one-third of 
these stacks are concentrated in 5 states along the Ohio River Valley. 
While about half of tall stacks began operating more than 30 years 
ago, there has been an increase in the number of tall stacks that 
began operating in the last 4 years, which air and utility officials 
attributed to the need for new stacks when plants installed pollution 
control equipment. 

Stack height is one of several factors that contribute to the 
interstate transport of air pollution. According to reports and 
stakeholders with expertise on this topic, tall stacks generally 
disperse pollutants over greater distances than shorter stacks and 
provide pollutants greater time to react in the atmosphere to form 
ozone and particulate matter. However, stakeholders had difficulty 
isolating the exact contribution of stack height to the transport of 
air pollution because this is a complex process that involves several 
other variables, including total emissions from a stack, the 
temperature and velocity of the emissions, and weather. The use of 
pollution controls, which are generally installed in boilers or the 
duct work that connects a boiler to a stack, has increased in recent 
years at coal power plants. However, GAO found that many boilers 
remain uncontrolled for certain pollutants, including several 
connected to tall stacks. For example, GAO found that 56 percent of 
boilers attached to tall stacks lacked scrubbers to control SO2 and 63 
percent lacked post-combustion controls to capture NOx emissions. In 
general, GAO found that boilers without these controls tended to be 
older, with in-service dates prior to 1980. 

GAO identified 48 tall stacks built since 1988-—when GEP regulations 
were largely affirmed in court-—that states reported are subject to 
the GEP provisions of the Clean Air Act and for which states could 
provide GEP height information. Of these 48 stacks, 17 exceed their 
GEP height, 19 are at their GEP height, and 12 are below their GEP 
height. Section 123 of the Clean Air Act defines GEP as the height 
needed to prevent excessive downwash, a phenomenon that occurs when 
nearby structures disrupt airflow and produce high local 
concentrations of pollutants. Officials reported that a variety of 
factors can influence stack height decisions. For example, some 
utility officials reported that stacks were built above GEP to provide 
greater protection against downwash or to help a plant’s emissions 
clear local geographic features, such as valley walls. GAO was unable 
to obtain GEP height information for an additional 25 stacks that were 
built since 1988 for two reasons: (1) some of these stacks were exempt 
from GEP regulations, and (2) states did not have GEP information 
readily available for some replacement stacks because the GEP 
calculation was sometimes made decades earlier and a recalculation was 
not required at the time the replacement stack was built. 

View [hyperlink, http://www.gao.gov/products/GAO-11-473] or key 
components. For more information, contact David Trimble at (202) 512-
3841 or trimbled@gao.gov. 

[End of section] 

Contents: 

Letter: 

Background: 

Almost 300 Tall Smokestacks Operate in 34 States, and about Half Began 
Operating before 1980: 

Stack Height Contributes to Interstate Transport of Air Pollution, and 
the Emissions from Several Tall Stacks Remain Uncontrolled for Certain 
Pollutants: 

Based on Available Information, 17 of 48 Tall Smokestacks Built Since 
1988 Exceed Their GEP Height, and A Variety of Factors Can Influence 
Height Decisions: 

Agency Comments: 

Appendix I: Scope and Methodology: 

Appendix II: Distribution of Tall Stacks by State: 

Appendix III: GAO Contact and Staff Acknowledgments: 

Tables: 

Table 1: Summary of Pollution Control Equipment Used at Coal Power 
Plants: 

Table 2: Stacks Built Since 1988 With Heights that Exceed GEP: 

Table 3: Information on Pollution Controls for Boilers Attached to 
Tall Stacks Built Since 1988 for which GEP Information was Available: 

Table 4: Number of Tall Stacks at Coal Power Plants by State and 
Associated Generating Capacity of Boilers Attached to These Stacks: 

Figures: 

Figure 1: Building Downwash: 

Figure 2: Sample Layout of Pollution Controls in a Coal Power Plant: 

Figure 3: Comparison of Tall Stacks to Well-Known Structures: 

Figure 4: Location of Coal Power Plants with Operating Tall Stacks, as 
of December 2010: 

Figure 5: Distribution of Operating Tall Stacks by Year Stack Went 
Into Service: 

Abbreviations: 

CAIR: Clean Air Interstate Rule: 

CAMx: Comprehensive Air Quality Model with Extensions: 

DOE: Department of Energy: 

EIA: Energy Information Administration: 

EPA: Environmental Protection Agency: 

ESP: electrostatic precipitator: 

FGD: flue gas desulfurization: 

GEP: good engineering practice: 

NAAQS: National Ambient Air Quality Standards: 

NESCAUM: Northeast States for Coordinated Air Use Management: 

NOx: nitrogen oxides: 

SCR: selective catalytic reduction: 

SNCR: selective non-catalytic reduction: 

SIP: State Implementation Plan: 

SO2: sulfur dioxide: 

[End of section] 

United States Government Accountability Office: 
Washington, DC 20548: 

May 11, 2011: 

The Honorable Sheldon Whitehouse: 
Chairman: 
Subcommittee on Oversight: 
Committee on Environment and Public Works: 
United States Senate: 

Dear Mr. Chairman: 

Tall smokestacks--which are used primarily at coal power plants-- 
release air pollutants such as sulfur dioxide (SO2), and nitrogen 
oxides (NOx) high into the atmosphere to help disperse them and limit 
their impact on air quality in local communities.[Footnote 1] However, 
because wind currents are generally faster at higher elevations, tall 
stacks can increase the distance that these pollutants travel, harming 
air quality in downwind communities. When these pollutants are 
airborne, they can react in the atmosphere to form particulate matter, 
acid rain, and ozone that can harm air quality, human health, and the 
environment. For example, SO2, NOx, ozone, and particulate matter can 
cause or worsen respiratory diseases such as emphysema, bronchitis, or 
asthma, while acid rain can damage vegetation and aquatic ecosystems. 

Under the Clean Air Act, the Environmental Protection Agency (EPA) is 
responsible for setting National Ambient Air Quality Standards (NAAQS) 
for certain pollutants considered harmful to public health and the 
environment. EPA has set NAAQS for six such pollutants, known as 
criteria air pollutants: SO2, NOx, particulate matter, ozone, carbon 
monoxide, and lead. These standards are expressed as concentration 
limits averaged over time, and compliance is determined through ground-
level monitoring at a local level. States are responsible for 
developing and implementing plans, known as State Implementation Plans 
(SIP), to achieve and maintain these standards. In carrying out this 
duty, states set emissions limitations for individual sources of air 
pollution, which are based, in part, on the results of air quality 
models that show the impact these sources will have on air quality. 
Since 1990, the Clean Air Act has required the incorporation of these 
emissions limitations into operating permits which collect all of the 
pollution control, recordkeeping, and reporting requirements 
applicable to individual sources of air pollution. 

In the early 1970s, power plants commonly installed tall stacks to 
reduce pollutant concentrations at ground level to help attain NAAQS. 
The 1977 amendments to the Clean Air Act encouraged the use of 
pollution control equipment and other control measures over dispersion 
techniques such as tall stacks to meet NAAQS. For example, section 123 
was added to prohibit states from counting the dispersion effects of 
stack heights in excess of a stack's good engineering practice (GEP) 
height when determining a source's emissions limitation. Section 123 
of the Clean Air Act defines GEP height as the height needed to 
disperse pollutants to prevent excessive "downwash," a phenomenon that 
occurs when nearby structures disrupt airflow and produce excessively 
high concentrations of pollutants in the immediate vicinity of the 
source. Section 123 generally applies to stacks built since December 
31, 1970, but some stacks may be exempt if they were built to replace 
stacks that were in existence on or before this date. Since the GEP 
heights for smokestacks can be determined using a calculation that 
accounts for the height and width of the largest nearby structure, GEP 
heights vary accordingly.[Footnote 2] Section 123 does not limit stack 
height; instead, it removes an incentive to build stacks higher than 
necessary. For example, if a stack's GEP height is 600 feet, but the 
stack is built to 800 feet, the source cannot count the dispersion 
effects associated with the excess 200 feet toward meeting its 
emissions limitation. EPA finalized regulations for calculating and 
using GEP height in 1985, and these regulations were largely affirmed 
by the District of Columbia Court of Appeals in 1988. 

EPA reported that measured levels of SO2 and NOx, along with ozone and 
particulate matter, decreased between 1990 and 2008. However, EPA 
noted that in 2008, about 127 million people lived in counties where 
one or more NAAQS--usually ozone or particulate matter--was exceeded. 
In developing policy to control air pollution, EPA recognizes that 
emissions from upwind states can contribute to the nonattainment--or 
exceedances--of NAAQS in downwind states. EPA has taken steps to 
reduce SO2 and NOx emissions that contribute to the interstate 
transport of air pollution through recent rule makings. 

You asked us to provide information on the use of tall smokestacks at 
coal power plants. Specifically, our objectives were to examine (1) 
the number and location of smokestacks 500 feet or higher that are 
operating at coal power plants across the United States, and when they 
began operating; (2) what is known about these smokestacks' 
contribution to the interstate transport of air pollution and the 
pollution controls that have been installed at coal power plants with 
these stacks; and (3) the number of these smokestacks that were built 
above their GEP height since 1988, and the reasons for this. 

To identify the number and location of smokestacks at coal power 
plants that were 500 feet or higher on December 31, 2010, we analyzed 
data on power plants from the Department of Energy's (DOE) Energy 
Information Administration (EIA). We also used these data to determine 
when these stacks began operating. To assess the reliability of the 
EIA data used in this report, we reviewed documentation from EIA, 
interviewed relevant officials who were involved in collecting and 
compiling the data, and conducted electronic testing of the data. We 
determined that the data were sufficiently reliable for our purposes. 
Because the EIA data were collected in 2008, we also contacted all 50 
states and the District of Columbia and sent a survey to states with 
tall stacks to determine if any changes had taken place in the number 
or operating status of stacks since that time. We updated the relevant 
EIA data with more recent data from our survey results. To determine 
what is known about tall stacks' contribution to the interstate 
transport of air pollution, we reviewed reports from EPA and academics 
and spoke with stakeholders with expertise on this topic. These 
stakeholders included EPA officials involved in modeling interstate 
transport of air pollution from power plants, officials from utilities 
and construction firms that design and build power plants, atmospheric 
scientists who conduct research on this topic, and state officials who 
are involved in permitting power plants and complying with federal 
regulations governing the interstate transport of air pollution. We 
also analyzed the EIA data to determine the pollution control 
equipment installed at coal power plants with stacks 500 feet or 
higher. To determine the number of tall stacks that have been built 
above their GEP height since 1988, we used survey responses from 22 
states in which tall stacks have been built since 1988 to obtain 
information about the GEP height for these stacks. In this survey, we 
also asked for reasons that a stack was built above GEP, when 
applicable. In those cases where state officials could not provide a 
reason for why a stack was built above its GEP height, we contacted 
several of the operators of these facilities to obtain this 
information. 

We conducted our work from July 2010 through May 2011 in accordance 
with all sections of GAO's quality assurance framework that are 
relevant to our objectives. This framework requires that we plan and 
perform the engagement to obtain sufficient, appropriate evidence to 
meet our stated objectives and to discuss any limitations in our work. 
We believe that the information and data obtained, and the analysis 
conducted, provide a reasonable basis for any findings and 
conclusions. A more detailed description of our scope and methodology 
is presented in appendix I. 

Background: 

The five principal emissions from coal power plants are carbon 
dioxide, SO2, NOx, particulate matter, and mercury. For the purposes 
of this report, we are focusing on power plants' emissions of SO2, 
NOx, and particulate matter since they, along with ozone, are the 
focus of a rule currently proposed by EPA--the Transport Rule--which 
seeks to limit the interstate transport of emissions of SO2 and NOx in 
order to abate violations of particulate matter and ozone NAAQS in 
downwind states. According to an EPA analysis, as of 2008, power 
plants emitted over 65 percent of SO2 emissions and almost 20 percent 
of NOx emissions, nationwide. These emissions impact local air 
quality, but they can also travel hundreds of miles to impact the air 
quality of downwind states. In developing the Transport Rule, EPA has 
found that emissions of SO2 and NOx from 31 eastern states and the 
District of Columbia prevent downwind states from meeting NAAQS for 
ozone and particulate matter. SO2 and NOx emissions contribute to the 
formation of fine particulate matter, and NOx emissions contribute to 
the formation of ozone, which can cause or aggravate respiratory 
illnesses.[Footnote 3] 

EPA began establishing NAAQS for criteria air pollutants in the early 
1970s. When the NAAQS began going into effect in the 1970s, tall 
stacks were built in large numbers as a dispersion technique to help 
reduce ground-level concentrations of pollutants in the immediate 
vicinity of the stack. In 1970, there were only 2 stacks higher than 
500 feet in the United States, but this number had increased to more 
than 180 by 1985. 

While constructing a tall stack is a dispersion technique that helps 
to reduce pollution concentrations in the local area, using tall 
stacks does not reduce total emissions that can potentially be 
transported to downwind states. The 1977 amendments to the Clean Air 
Act discouraged the use of dispersion techniques to help attain NAAQS. 
Specifically, section 123 prohibits states from counting the 
dispersion effects of stack heights in excess of a stack's GEP height 
when determining a source's emissions limitation. The Clean Air Act 
defines GEP as "the height necessary to insure that emissions from the 
stack do not result in excessive concentrations of any air pollutant 
in the immediate vicinity of the source as a result of atmospheric 
downwash, eddies, or wakes which may be created by the source itself, 
nearby structures, or nearby terrain obstacles."[Footnote 4] According 
to federal regulations, a stack's GEP height is the higher of: 

* 65 meters, measured from the ground-level elevation at the base of 
the stack; 

* a formula based on the height and width of nearby structure(s) 
(height plus 1.5 times the width or height, whichever is lesser); 
[Footnote 5] or: 

* the height demonstrated by a fluid model or field study that ensures 
the emissions from a stack do not result in excessive concentrations 
of any air pollutant as a result of atmospheric downwash created by 
the source itself, nearby structures, or nearby terrain features. 

Downwash occurs when large buildings or local terrain distort or 
impact wind patterns, and an area of more turbulent air forms, known 
as a wake. Emissions from a stack at a power plant can be drawn into 
this wake and brought down to the ground near the stack more quickly 
(see figure 1). 

Figure 1: Building Downwash: 

[Refer to PDF for image: illustration] 

Source: GAO analysis of EPA information. 

[End of figure] 

States issue air permits to major stationary sources of air pollution, 
such as power plants, and determine GEP for stacks when they set 
emissions limitations for these sources. Emissions limitations may be 
reset when plants undergo New Source Review. New Source Review is a 
preconstruction permitting program which requires a company that 
constructs a new facility or makes a major modification to an existing 
facility to meet new, more stringent emissions limitation based on the 
current state of pollution control technology. A stack's GEP height is 
used in air dispersion modeling that takes place when emissions 
limitations are developed for a source as part of the permitting 
process. 

Many sources contribute to levels of pollution that affect the ability 
of downwind states to attain and maintain compliance with NAAQS, and 
some of these pollutants may originate hundreds or thousands of miles 
from the areas where violations are detected. The Clean Air Act's 
"good neighbor provisions" under section 110 of the Act require states 
to prohibit emissions that significantly contribute to nonattainment 
or interfere with maintenance of NAAQS in downwind states or which 
will interfere with downwind states' ability to prevent significant 
deterioration of air quality.[Footnote 6] Section 126 of the Clean Air 
Act also allows a downwind state to petition EPA to determine that 
specific sources of air pollution in upwind states interfere with the 
downwind state's ability to protect air quality and for EPA to impose 
emissions limitations directly on these sources. As detailed in the 
timeline below, Congress granted EPA increased authority to address 
interstate transport of air pollution under the Clean Air Act, and EPA 
acted on this authority. 

* 1977 amendments to the Clean Air Act. These amendments contained two 
provisions that focused on interstate transport of air pollution, the 
predecessor to the current good neighbor provision of section 110 of 
the Act and section 126. These amendments also established the New 
Source Review program. 

* 1990 amendments to the Clean Air Act. These amendments added the 
Acid Rain Program (Title IV) to the Clean Air Act, which created a cap-
and-trade program for SO2 emissions from power plants, with a goal of 
reducing annual SO2 emissions by 10 million tons from 1980 levels and 
reducing annual NOx emissions by 2 million tons from 1980 levels by 
the year 2000. 

* 1998 NOx SIP Call. After concluding that NOx emissions from 22 
states and the District of Columbia contributed to the nonattainment 
of NAAQS for ozone in downwind states, EPA required these states to 
amend their SIPs to reduce their NOx emissions. EPA took this 
regulatory action based on section 110 of the Clean Air Act. 

* 2005 Clean Air Interstate Rule (CAIR). This regulation required SIP 
revisions in 28 states and the District of Columbia that were found to 
contribute significantly to nonattainment of NAAQS for fine 
particulate matter and ozone in downwind states. CAIR required 
reductions for SO2 and NOx emissions from 28 eastern states and the 
District of Columbia and included an option for states to meet these 
reductions through regional cap-and-trade programs. When the rule was 
finalized, EPA estimated it would annually reduce SO2 and NOx 
emissions by 3.8 million and 1.2 million tons, respectively, by 2015. 
The U.S. Court of Appeals remanded CAIR to EPA in 2008 because it 
found significant flaws in the approach EPA used to develop CAIR, but 
allowed the rule to remain in place while EPA develops a replacement 
rule. 

* 2010 Transport Rule. EPA proposed this rule to replace CAIR, which 
aims to reduce emissions of SO2 and NOx from power plants.[Footnote 7] 
If finalized as written, the rule would require emissions of SO2 to 
decrease 71 percent over 2005 levels and emissions of NOx to decrease 
by 52 percent over 2005 levels by 2014.[Footnote 8] 

As described above, EPA's efforts to address the interstate transport 
of air pollution from power plants have focused on reducing the total 
emissions of SO2 and NOx from these plants. Unlike tall stacks, 
pollution controls help to reduce the actual emissions from power 
plants by either reducing the formation of these emissions or 
capturing them after they are formed. At coal power plants, these 
controls are generally installed in either the boiler, where coal is 
burned, or the duct work that connects a boiler to the stack. A single 
power plant can use multiple boilers to generate electricity, and the 
emissions from multiple boilers can sometimes be connected to a single 
stack. Figure 2 shows some of the pollution controls that may be used 
at coal power plants: fabric filters or electrostatic precipitators 
(ESP) to control particulate matter, flue gas desulfurization (FGD) 
units--known as scrubbers--to control SO2 emissions, and selective 
catalytic reduction (SCR) or selective non-catalytic reduction (SNCR) 
units to control NOx emissions. 

Figure 2: Sample Layout of Pollution Controls in a Coal Power Plant: 

[Refer to PDF for image: illustration] 

The following are depicted on the illustration: 

Coal supply: 
Stack: 
SCR or SNCR: 
Fabric filter or ESP: 
Boiler: 
Turbine and generator: 
Electricity. 

Source: GAO analysis of information from Electric Power Research 
Institute and Tennessee Valley Authority. 

[End of figure] 

The reduction in emissions from a coal power plant by the use of 
pollution controls can be substantial, as shown in table 1. The 
installation of pollution control equipment can also be expensive. 
According to a Massachusetts Institute of Technology study of coal 
power plants, it may cost anywhere from $215,000 per megawatt to 
$330,000 per megawatt to install controls at a coal power plant for 
particulate matter, SO2, and NOx.[Footnote 9] For a typical coal power 
plant with a capacity of 500 megawatts, this means that it could cost 
from $107 million to install these controls at a newly built facility 
up to $165 million to retrofit these controls at an existing facility. 
Additionally, pollution controls can require additional energy to 
operate, known as an energy penalty. 

Table 1: Summary of Pollution Control Equipment Used at Coal Power 
Plants: 

Pollutant targeted: Particulate matter; 
Control equipment name: ESP; 
How it works: An induced electrical charge removes particles from flue 
gas; 
Removal efficiency: Capable of 99.0-99.5% removal of particulates. 

Pollutant targeted: Particulate matter; 
Control equipment name: Fabric filter (commonly referred to as a 
"baghouse"); 
How it works: Flue gas passes through a tightly woven fabric filter; 
Removal efficiency: Capable of 99.9% removal of particulates. 

Pollutant targeted: SO2[A]; 
Control equipment name: FGD unit (commonly referred to as a 
"scrubber"); 
How it works: Wet FGDs inject a liquid sorbent, such as limestone, 
into the flue gas to form a wet solid that can be disposed of or sold. 
Dry FGDs inject a dry sorbent, such as lime, into the flue gas to form 
a solid by-product that is collected; 
Removal efficiency: Wet FGDs - Capable of 80-99% removal of SO2; Dry 
FGDs - Capable of 70-95% removal of SO2. 

Pollutant targeted: NOx; 
Control equipment name: Combustion control technologies, such as low-
NOx burners[B]; 
How it works: Coal combustion conditions are adjusted so that less NOx 
formation occurs; 
Removal efficiency: Capable of 40-45% reduction in the formation of 
NOx. 

Pollutant targeted: NOx; 
Control equipment name: Post-combustion controls, such as SCR and SNCR 
units; 
How it works: SCRs inject ammonia into flue gas to form nitrogen and 
water and use a catalyst to enhance the reaction; 
SNCRs inject ammonia as well, but do not use a catalyst; 
Removal efficiency: SCRs - Capable of 70-95% removal of NOx; SNCRs - 
Capable of 30-75% removal of NOx. 

Source: GAO summary of reports by EPA, National Academies, Electric 
Power Research Institute, and industry documents. 

[A] Another approach to reducing SO2 emissions from a coal power plant 
is for a plant to switch from using coal with a higher sulfur content 
to coal with a lower sulfur content, or to blend higher sulfur coal 
with lower sulfur coal. 

[B] Low-NOx burners can be used in conjunction with post-combustion 
controls for NOx as well. 

[End of table] 

Almost 300 Tall Smokestacks Operate in 34 States, and about Half Began 
Operating before 1980: 

According to our analysis of EIA data, which we updated with our 
survey results, we found a total of 284 tall smokestacks were 
operating at 172 coal power plants in 34 states, as of December 31, 
2010. While about half of the tall stacks began operating more than 30 
years ago, there has been an increase in the number of tall stacks 
that have begun operating in the last 4 years, which several 
stakeholders attributed to the need for new stacks when retrofitting 
existing plants with pollution control equipment. 

284 Tall Stacks Were Operating at about 170 Coal Power Plants, with 
Approximately One-Third Located in the Ohio River Valley: 

As of December 31, 2010, we found a total of 284 tall stacks were 
operating at 172 coal power plants in the United States. These tall 
stacks account for about 35 percent of the 808 stacks operating at 
coal power plants in the United States, and they are generally located 
at larger power plants. Specifically, we found these stacks are 
associated with 64 percent of the coal generating capacity.[Footnote 
10] 

We found that 207 tall stacks (73 percent) are between 500 and 699 
feet tall and that 63 stacks (22 percent) are between 700 and 999 feet 
tall. The remaining 14 stacks (5 percent) are 1,000 feet tall or 
higher, with the tallest stack at a coal power plant in the United 
States having a height of 1,038 feet at the Rockport Power Plant in 
Indiana. In figure 3, we show how a tall stack compares to the heights 
of other well-known structures. 

Figure 3: Comparison of Tall Stacks to Well-Known Structures: 

[Refer to PDF for image: illustration] 

Structure: Smokestack; 
Height: 500 feet. 

Structure: Washington Monument; 
Height: 555 feet. 

Structure: Seattle Space Needle; 
Height: 605 feet. 

Structure: Golden Gate Bridge; 
Height: 746 feet. 

Structure: Rockport Power Plant Stack; 
Height: 1,038 feet. 

Structure: Eiffel Tower; 
Height: 1,063 feet. 

Source: GAO analysis of information for relevant buildings. 

[End of figure] 

Thirty-five percent of the 284 tall stacks are concentrated in 5 
states along the Ohio River Valley--Kentucky, Ohio, Indiana, Illinois, 
and Pennsylvania--at 59 coal power plants. Another 32 percent are 
located in Alabama, Missouri, West Virginia, Michigan, Georgia, 
Wyoming, Wisconsin, and Texas, while the remaining 33 percent of tall 
stacks are located across 21 other states.[Footnote 11] Figure 4 shows 
the location of coal power plants with operating tall stacks. For 
counts of all tall stacks by state, see appendix II. 

Figure 4: Location of Coal Power Plants with Operating Tall Stacks, as 
of December 2010: 

[Refer to PDF for image: illustrated map of continental U.S.] 

The map depicts the location of coal power plants with operating tall 
stacks. Alaska and Hawaii are not included because they do not have 
tall stacks. 

Sources: GAO and Map Resources (map). 

[End of figure] 

About Half of All Tall Stacks Began Operating before 1980, but an 
Increasing Number Have Gone into Service in the Last 4 Years: 

Forty-six percent of the 284 tall stacks operating at coal power 
plants in the United States as of December 31, 2010, went into service 
before 1980. Another 28 percent went into service in the 1980s, 7 
percent went into service in the 1990s, and 18 percent went into 
service since 2000. Of the stacks that went into service since 2000, a 
vast majority went into service in the last 4 years, as shown in 
figure 5. 

Figure 5: Distribution of Operating Tall Stacks by Year Stack Went 
Into Service: 

[Refer to PDF for image: vertical bar graph] 

Year: 1970; 
Number of stacks going into service: 4. 

Year: 1971; 
Number of stacks going into service: 3. 

Year: 1972; 
Number of stacks going into service: 5. 

Year: 1973; 
Number of stacks going into service: 5. 

Year: 1974; 
Number of stacks going into service: 6. 

Year: 1975; 
Number of stacks going into service: 9. 

Year: 1976; 
Number of stacks going into service: 11. 

Year: 1977; 
Number of stacks going into service: 16. 

Year: 1978; 
Number of stacks going into service: 18. 

Year: 1979; 
Number of stacks going into service: 14. 

Year: 1980; 
Number of stacks going into service: 17. 

Year: 1981; 
Number of stacks going into service: 10. 

Year: 1982; 
Number of stacks going into service: 18. 

Year: 1983; 
Number of stacks going into service: 9. 

Year: 1984; 
Number of stacks going into service: 11. 

Year: 1985; 
Number of stacks going into service: 4. 

Year: 1986; 
Number of stacks going into service: 7. 

Year: 1987; 
Number of stacks going into service: 4. 

Year: 1988; 
Number of stacks going into service: 1. 

Year: 1990; 
Number of stacks going into service: 2. 

Year: 1991; 
Number of stacks going into service: 2. 

Year: 1992; 
Number of stacks going into service: 1. 

Year: 1994; 
Number of stacks going into service: 5. 

Year: 1995; 
Number of stacks going into service: 4. 

Year: 1996; 
Number of stacks going into service: 3. 

Year: 1997; 
Number of stacks going into service: 1. 

Year: 1998; 
Number of stacks going into service: 1. 

Year: 1999; 
Number of stacks going into service: 1. 

Year: 2001; 
Number of stacks going into service: 1. 

Year: 2005; 
Number of stacks going into service: 1. 

Year: 2006; 
Number of stacks going into service: 2. 

Year: 2007; 
Number of stacks going into service: 13. 

Year: 2008; 
Number of stacks going into service: 11. 

Year: 2009; 
Number of stacks going into service: 12. 

Year: 2010; 
Number of stacks going into service: 11. 

Source: GAO analysis of EIA data and survey results. 

[End of figure] 

A large majority of the tall stacks that went into service in the past 
4 years are replacements of existing, older stacks. Several 
stakeholders told us many of these older stacks were replaced to 
accommodate changes in flue gas that resulted from the installation of 
certain types of pollution control equipment to meet emission 
reductions required by the first phase of CAIR. For example, 
stakeholders explained that a FGD unit--used to reduce SO2 emissions-- 
reduces the temperature and increases the moisture of a plant's flue 
gas. 

Stack Height Contributes to Interstate Transport of Air Pollution, and 
the Emissions from Several Tall Stacks Remain Uncontrolled for Certain 
Pollutants: 

Stack height is one of several factors that contribute to the 
interstate transport of air pollution. While the use of pollution 
controls has increased in recent years at coal power plants, several 
boilers connected to tall stacks remain uncontrolled for certain 
pollutants.[Footnote 12] 

Stack Height Is One of Several Factors that Contribute to the 
Interstate Transport of Air Pollution: 

Stack height is one of several factors that contribute to the 
interstate transport of air pollution. According to reports and 
stakeholders with expertise on this topic, tall stacks generally 
disperse pollutants over longer distances than shorter stacks and 
provide pollutants with more time to react in the atmosphere to form 
ozone or particulate matter. However, the interstate transport of air 
pollution is a complex process that involves several variables--such 
as total emissions from a stack, the temperature and velocity of the 
emissions, and weather--in addition to stack height. As a result, 
stakeholders had difficulty isolating the exact contribution of stack 
height to the interstate transport of air pollution, and we found 
limited research on this specific topic. For example, EPA staff 
involved in the modeling of interstate transport told us that it is 
difficult to determine the different impacts that stacks of varying 
heights have on the transport of air pollution. According to one 
atmospheric scientist we spoke with, the interstate transport of air 
pollution is a complex process and stack height represents just one 
variable in this process. 

Stakeholders struggled to identify the precise impact of tall stacks, 
due in part to the other factors that influence how high emissions 
from a stack will rise. The temperature and velocity of a stack's 
emissions, along with its height, contribute to what is known as an 
"effective stack height." Effective stack height takes into account 
not only the height at which emissions are released, but also how high 
the plume of emissions will rise, which is influenced by the 
temperature and velocity of these emissions. One atmospheric scientist 
told us the emissions from a shorter stack could rise higher than a 
taller stack, depending on the temperature and velocity of the 
emissions. 

Weather also plays a key role in the transport of air pollution. A 
study by the Northeast States for Coordinated Air Use Management 
(NESCAUM)--a group that represents state air agencies in the 
Northeast--described weather patterns that can contribute to high-
ozone days in the Ozone Transport Region, which includes 12 states in 
the Mid-Atlantic and New England regions and the District of Columbia. 
[Footnote 13] These high-ozone days typically occur in the summer on 
hot days, when the sun helps transform NOx and volatile organic 
compounds into ozone. Wind speeds and wind direction also help to 
determine how emissions will travel. In the Mid-Atlantic United 
States, the wind generally blows from west to east during the day, and 
wind speeds are generally faster at higher elevations. The time of day 
can also influence the transport of air pollution. According to the 
NESCAUM report and researchers we spoke with, ozone can travel 
hundreds of miles at night with the help of high-speed winds known as 
the low-level jet. This phenomenon typically occurs at night when an 
atmospheric inversion occurs due to the ground cooling quicker than 
the upper atmosphere. A boundary layer can form between these two air 
masses several hundred feet off the ground, which can allow the low-
level jet to form and transport ozone and particulate matter with its 
high winds. As the atmosphere warms the following day, this boundary 
layer can break down and allow these transported emissions to mix 
downward and affect local air quality. 

Air dispersion models typically take into account stack height along 
with these other factors when predicting the transport of emissions 
from power plants. For example, EPA used the Comprehensive Air Quality 
Model with Extensions (CAMx) to conduct the modeling to support the 
development of the Transport Rule. CAMx is a type of photochemical 
grid model, which separates areas into grids and aims to predict the 
transport of sources that lie within these grids. Key inputs into this 
model include stack height, the velocity and temperature of emissions, 
and weather data.[Footnote 14] EPA staff involved in conducting this 
modeling for the Transport Rule said they use the CAMx model to 
predict the actual impacts of air emissions, and they have not used 
this model to estimate the specific impact of stack height on 
interstate transport. They reported their modeling efforts in recent 
years have been done in support of CAIR and the Transport Rule, and 
have been focused on modeling the regional impacts of reducing total 
air emissions. 

Several stakeholders we spoke with said total emissions is a key 
contributor to interstate transport of air pollution, and the use of 
pollution controls at coal power plants is critical to reducing 
interstate transport of air pollution. Reducing the total emissions 
from a power plant influences how much pollution can react in the 
atmosphere to form ozone and particulate matter that can ultimately be 
transported. 

Use of Pollution Controls at Coal Power Plants Has Increased in Recent 
Years, but Emissions from Some Plants, Including Several with Tall 
Stacks, Remain Uncontrolled for Certain Pollutants: 

The use of pollution control equipment, particularly for SO2 and NOx 
emissions, has increased over time, largely in response to various 
changes in air regulations, according to stakeholders and reports we 
reviewed. According to EIA data, the generating capacity of power 
plants that is controlled by FGDs has increased from about 87,000 
megawatts to about 140,000 megawatts from 1997 to 2008.[Footnote 15] 
Since coal power plants had about 337,000 megawatts of generating 
capacity in 2008, this means that about 42 percent of the generating 
capacity was controlled by a FGD in 2008. Similarly, SCRs were 
installed at about 44,000 megawatts worth of capacity from 2004 
through 2009, with about one-third of these installations occurring in 
2009 alone, according to an EPA presentation on this topic. EPA and 
state officials, along with electric utility officials, told us that 
the increase in the use of these pollution controls is due to various 
air regulations, such as the Acid Rain Program and CAIR, which focused 
on reducing SO2 and NOx emissions. 

However, while we found that the use of pollution controls at coal 
power plants has increased in recent years, many boilers remain 
uncontrolled for certain pollutants, including several connected to 
tall stacks. For example, we found that 56 percent of the boilers 
attached to tall stacks at coal power plants do not have a FGD to 
control SO2 emissions. Collectively, we found that these uncontrolled 
boilers accounted for 42 percent of the total generating capacity of 
boilers attached to tall stacks.[Footnote 16] Our findings on FGDs are 
similar to EPA data on all coal power plants. In 2009, EPA estimated 
that 50 percent of the generating capacity of coal power plants did 
not have FGDs. 

For NOx controls, we found that while about 90 percent of boilers 
attached to tall stacks have combustion controls in place to reduce 
the formation of NOx emissions, a majority of these boilers lack post- 
combustion controls that can help to reduce NOx emissions to a greater 
extent. Specifically, 63 percent of boilers connected to tall stacks 
do not have post-combustion controls for NOx, such as SCRs or SNCRs, 
which help reduce NOx emissions more than combustion controls alone. 
Collectively, we found that these boilers without post-combustion 
controls accounted for 54 percent of the total generating capacity of 
boilers attached to tall stacks. EPA data on all coal power plants 
show that 53 percent of the generating capacity for coal power plants 
did not have post-combustion controls for NOx emissions in place in 
2009. 

Tall stacks that had uncontrolled SO2 and NOx emissions were generally 
attached to older boilers that went into service prior to 1980. We 
found that approximately 85 percent of boilers without FGDs that were 
attached to tall stacks went into service before 1980. Similarly, over 
70 percent of the boilers without post-combustion controls for NOx 
went into service before 1980. Overall, we found that about 82 percent 
of the boilers that lacked both a FGD and post-combustion controls for 
NOx went into service before 1980. Some stakeholders attributed the 
lack of pollution controls on older boilers to less stringent 
standards that were applied at the time the boilers were constructed. 
As discussed above, companies that construct a new facility or make a 
major modification to an existing facility must meet new emissions 
limitations based on the current state of pollution control 
technology. Because pollution control technology has advanced over 
time, the standards have become more stringent over time, meaning that 
boilers constructed before 1980 would have had higher allowable 
emissions and less need to install controls than boilers constructed 
in 2010. 

Unlike our findings on FGDs and post-combustion controls for NOx 
emissions, we found that 100 percent of boilers attached to tall 
stacks were controlled for particulate matter. However, it is 
important to note that plants with uncontrolled SO2 and NOx emissions 
contribute to the formation of additional particulate matter in the 
atmosphere. 

Based on Available Information, 17 of 48 Tall Smokestacks Built Since 
1988 Exceed Their GEP Height, and A Variety of Factors Can Influence 
Height Decisions: 

We identified 48 tall stacks built since 1988 that states reported are 
subject to the GEP provisions of the Clean Air Act and for which 
states could provide GEP height information. Of these 48 stacks, we 
found that 17 exceed their GEP height, 19 are at their GEP height, and 
12 are below their GEP height. We found that 15 of the 17 stacks built 
above GEP were replacement stacks that were built as part of the 
process of installing pollution control equipment. These stacks vary 
in the degree to which they exceed GEP height, ranging from less than 
1 percent above GEP to about 46 percent above GEP, as shown in table 
2. The other 2 stacks built above GEP exceed their GEP height by 2 
percent or less. 

Table 2: Stacks Built Since 1988 With Heights that Exceed GEP: 

Plant name and unit number: Bowen (units 3, 4); 
State: Georgia; 
In-service date: (year): 2008; 
Stack height (feet): 675; 
GEP height: (feet): 643; 
Percentage difference between actual and GEP height: 5%; 
Replacement stack?: Yes. 

Plant name and unit number: Bowen (units 1, 2); 
State: Georgia; 
In-service date: (year): 2009; 
Stack height (feet): 675; 
GEP height: (feet): 643; 
Percentage difference between actual and GEP height: 5%; 
Replacement stack?: Yes. 

Plant name and unit number: Hammond (units 1, 2, 3, 4); 
State: Georgia; 
In-service date: (year): 2008; 
Stack height (feet): 675; 
GEP height: (feet): 464; 
Percentage difference between actual and GEP height: 46%; 
Replacement stack?: Yes. 

Plant name and unit number: Wansley (units 1, 2); 
State: Georgia; 
In-service date: (year): 2008; 
Stack height (feet): 675; 
GEP height: (feet): 663; 
Percentage difference between actual and GEP height: 2%; 
Replacement stack?: Yes. 

Plant name and unit number: Duck Creek (unit 1); 
State: Illinois; 
In-service date: (year): 2008; 
Stack height (feet): 588; 
GEP height: (feet): 533; 
Percentage difference between actual and GEP height: 10%; 
Replacement stack?: Yes. 

Plant name and unit number: Paradise (unit 3); 
State: Kentucky; 
In-service date: (year): 2006; 
Stack height (feet): 600; 
GEP height: (feet): 420; 
Percentage difference between actual and GEP height: 43%; 
Replacement stack?: Yes. 

Plant name and unit number: Iatan (unit 2); 
State: Missouri; 
In-service date: (year): 2010; 
Stack height (feet): 605; 
GEP height: (feet): 604; 
Percentage difference between actual and GEP height: 0.2%; 
Replacement stack?: Yes. 

Plant name and unit number: Miami Fort (unit 7); 
State: Ohio; 
In-service date: (year): 2007; 
Stack height (feet): 800; 
GEP height: (feet): 705; 
Percentage difference between actual and GEP height: 14%; 
Replacement stack?: Yes. 

Plant name and unit number: Miami Fort (unit 8); 
State: Ohio; 
In-service date: (year): 2007; 
Stack height (feet): 800; 
GEP height: (feet): 590; 
Percentage difference between actual and GEP height: 36%; 
Replacement stack?: Yes. 

Plant name and unit number: WH Sammis (units 1, 2, 3, 4, 5, 6, 7); 
State: Ohio; 
In-service date: (year): 2010; 
Stack height (feet): 850; 
GEP height: (feet): 840; 
Percentage difference between actual and GEP height: 1%; 
Replacement stack?: Yes. 

Plant name and unit number: Homer City (unit 3); 
State: Pennsylvania; 
In-service date: (year): 2001; 
Stack height (feet): 864; 
GEP height: (feet): 853; 
Percentage difference between actual and GEP height: 1%; 
Replacement stack?: Yes. 

Plant name and unit number: Montour (units 1, 2); 
State: Pennsylvania; 
In-service date: (year): 2008; 
Stack height (feet): 700; 
GEP height: (feet): 540; 
Percentage difference between actual and GEP height: 30%; 
Replacement stack?: Yes. 

Plant name and unit number: Brunner Island (unit 3); 
State: Pennsylvania; 
In-service date: (year): 2009; 
Stack height (feet): 600; 
GEP height: (feet): 540; 
Percentage difference between actual and GEP height: 11%; 
Replacement stack?: Yes. 

Plant name and unit number: Bull Run (unit 1); 
State: Tennessee; 
In-service date: (year): 2008; 
Stack height (feet): 500; 
GEP height: (feet): 492; 
Percentage difference between actual and GEP height: 2%; 
Replacement stack?: Yes. 

Plant name and unit number: Fayette (unit 3); 
State: Texas; 
In-service date: (year): 1988; 
Stack height (feet): 535; 
GEP height: (feet): 533; 
Percentage difference between actual and GEP height: 0.4%; 
Replacement stack?: No. 

Plant name and unit number: JK Spruce (unit 2); 
State: Texas; 
In-service date: (year): 2009; 
Stack height (feet): 601; 
GEP height: (feet): 588; 
Percentage difference between actual and GEP height: 2%; 
Replacement stack?: No. 

Plant name and unit number: Mountaineer (unit 1); 
State: West Virginia; 
In-service date: (year): 2007; 
Stack height (feet): 1,000; 
GEP height: (feet): 839; 
Percentage difference between actual and GEP height: 19%; 
Replacement stack?: Yes. 

Source: GAO analysis of state survey responses. 

[End of table] 

When we followed up with utility officials regarding why these stacks 
were built above GEP, they reported that a variety of factors can 
influence stack height decisions. These factors included helping a 
plant's emissions clear local geographic features, such as valley 
walls.[Footnote 17] According to one state air protection agency, 
three stacks were built above GEP to provide further protection 
against downwash. Officials from two utilities said they built stacks 
above GEP at coal power plants to account for the impact of other 
structures, such as cooling towers, on the site.[Footnote 18] Other 
stakeholders said that utilities may be hesitant to lower stack 
heights at their facilities when replacing a stack because plant 
officials have experience with that stack height and its ability to 
help protect against downwash. An official from one company that 
builds stacks told us this practice has sometimes occurred because 
utilities do not want the moisture-rich emissions from the replacement 
stack to hasten the deterioration of the old stacks, which are usually 
left in place and must be maintained. In addition, this moisture can 
create large icicles on the older stacks, which can present a danger 
to staff working at the power plant. 

Other stakeholders highlighted factors that may play a role in making 
stack height decisions. Some federal and state officials reported that 
generally there is little incentive to build a stack above GEP because 
a facility will not receive dispersion credit for the stack's height 
above GEP. Other stakeholders acknowledged that a stack could be built 
above GEP for site-specific reasons, such as helping emissions clear 
nearby terrain features. Some of these officials also noted that cost 
was another factor considered when making stack height decisions, as 
it is generally more costly to build a higher stack. For example, one 
utility official told us that two replacement stacks that were 
recently built below their original heights could meet their emissions 
limitations with these lower stack heights because the utility was 
installing pollution control equipment and did not want to incur the 
additional cost of building a taller stack. 

We found that stacks built above GEP since 1988 generally were 
attached to boilers that had controls in place for SO2, NOx, and 
particulate matter, as shown in table 3. We found similar results for 
stacks that were built at or below their GEP heights. 

Table 3: Information on Pollution Controls for Boilers Attached to 
Tall Stacks Built Since 1988 for which GEP Information was Available: 

Stacks: Stacks built above GEP; 
Proportion of attached boilers with a FGD installed for SO2 emissions: 
100%; 
Proportion of attached boilers with combustion controls installed for 
NOx emissions: 97%; 
Proportion of attached boilers with post-combustion controls installed 
for NOx emissions: 80%; 
Proportion of attached boilers with controls installed for particulate 
matter: 100%. 

Stacks: Stacks built at GEP; 
Proportion of attached boilers with a FGD installed for SO2 emissions: 
82%; 
Proportion of attached boilers with combustion controls installed for 
NOx emissions: 93%; 
Proportion of attached boilers with post-combustion controls installed 
for NOx emissions: 75%; 
Proportion of attached boilers with controls installed for particulate 
matter: 100%. 

Stacks: Stacks built below GEP; 
Proportion of attached boilers with a FGD installed for SO2 emissions: 
100%; 
Proportion of attached boilers with combustion controls installed for 
NOx emissions: 93%; 
Proportion of attached boilers with post-combustion controls installed 
for NOx emissions: 73%; 
Proportion of attached boilers with controls installed for particulate 
matter: 100%. 

Source: GAO analysis of EIA data and survey results. 

[End of table] 

We were unable to obtain GEP height information for an additional 25 
stacks that were built since 1988 for two reasons. First, some of 
these stacks replaced stacks that were exempt from the GEP 
regulations, according to state officials. Section 123 of the Clean 
Air Act exempts stack heights that were in existence on or before 
December 31, 1970, from the GEP regulations; because the exemption 
applies to stack heights rather than to stacks themselves, it covers 
both original and replacement stacks[Footnote 19]. Second, states did 
not have GEP information readily available for some stacks. According 
to state officials, they did not set new emissions limits at the time 
these replacement stacks were built because they were part of 
pollution control projects and emissions from these plants did not 
increase. For example, one state reported that GEP could have been 
calculated decades earlier for the original stacks when emissions 
limitations were set, and they were unable to locate this information 
in response to our request.[Footnote 20] According to EPA staff we 
spoke with about this issue, states are not required to conduct a GEP 
analysis in these instances. While we were unable to obtain GEP 
information for these stacks, our analysis of the pollution controls 
installed at boilers connected to these stacks yielded similar results 
to those stacks for which we did obtain GEP information. Specifically, 
all of these boilers had controls for SO2 and particulate matter, and 
85 percent had post-combustion controls for NOx. 

Agency Comments: 

We provided a draft of this report to EPA and DOE for review and 
comment. Both EPA and DOE stated they had no comments. 

As agreed with your office, unless you publicly announce the contents 
of this report earlier, we plan no further distribution until 30 days 
from the report date. At that time, we will send copies to the 
appropriate congressional committees, Secretary of Energy, 
Administrator of EPA, and other interested parties. In addition, this 
report will be available at no charge on the GAO Web site at 
[hyperlink, http://www.gao.gov]. 

If you or your staff have any questions regarding this report, please 
contact me at (202) 512-3841 or trimbled@gao.gov. Contact points for 
our Offices of Congressional Relations and Public Affairs may be found 
on the last page of this report. GAO staff who made major 
contributions to this report are listed in appendix III. 

Sincerely yours, 

Signed by: 

David C. Trimble: 
Acting Director: 
Natural Resources and Environment: 

[End of section] 

Appendix I: Scope and Methodology: 

To identify the number and location of smokestacks at coal power 
plants that were 500 feet or higher as of December 31, 2010, we 
analyzed data on power plants from the Department of Energy's (DOE) 
Energy Information Administration (EIA). We also used these data to 
determine when these stacks began operating. To determine the 
reliability of these data, we reviewed documentation from EIA, 
interviewed relevant officials who were involved in collecting and 
compiling the data, conducted electronic testing of the data, and we 
determined that the data were sufficiently reliable for our purposes. 
Because the EIA data were collected in 2008, we contacted all 50 
states and the District of Columbia to determine if they had tall 
stacks and developed and administered a survey to those 38 states with 
tall stacks to update the relevant EIA data and determine if any 
changes had taken place in the number or operating status of stacks 
since that time.[Footnote 21] We received e-mail addresses for each 
state from the Web site of the National Association of Clean Air 
Agencies, which represents air pollution control agencies in 53 states 
and territories, and developed a survey that we sent to respondents as 
an e-mail attachment. Prior to sending out this survey, we pretested 
the survey with officials from 2 states and revised some of the survey 
questions based on their input. We received responses to our survey 
from all 38 states and we sent follow-up questions based on their 
survey responses to clarify certain responses or to ask for additional 
information. We updated the relevant EIA data with these survey 
results to include the most recent information available on tall 
stacks. 

We did not include tall stacks that were used as bypass stacks only in 
times of maintenance or emergencies in our count of tall stacks. State 
officials reported that bypass stacks are rarely used and would not be 
used at the same time as plants' fully operating stacks. Additionally, 
we defined multi-flue stacks--those with multiple flues running within 
a single casing--as one stack, as opposed to counting each flue as a 
separate stack. A state modeling official told us they consider multi- 
flue stacks as single stacks when conducting dispersion modeling. 

For the purposes of this report, we defined tall smokestacks to be 
those that were 500 feet or higher. In our interviews with 
stakeholders, several told us they considered 500 feet to be a "tall" 
stack. Some stakeholders said that a typical boiler building at a coal 
power plant is about 200 feet high. Given that the original formula 
for good engineering practice (GEP) was 2.5 times height of nearby 
structures, this would equal about 500 feet. Other stakeholders 
reported that they considered a stack built above GEP to be "tall." 

To determine what is known about tall stacks' contribution to the 
interstate transport of air pollution, we reviewed reports from the 
Environmental Protection Agency (EPA) and academics and spoke with 
stakeholders with expertise on this topic. We conducted a literature 
search of engineering and other relevant journals on the topic of 
stack height and interstate transport of air pollution, and we 
reviewed the limited amount of literature we identified. The 
stakeholders we interviewed included EPA officials involved in 
modeling interstate transport of air pollution from power plants, 
officials from utilities and construction firms that design and build 
power plants, atmospheric scientists who conduct research on this 
topic, and state officials who are involved in permitting power plants 
and complying with federal regulations governing the interstate 
transport of air pollution. We also analyzed the EIA data and our 
survey results to determine the pollution control equipment installed 
at coal power plants with stacks 500 feet or higher. Specifically, we 
identified the control equipment that was associated with boilers that 
were attached to tall stacks. Pollution control equipment is not 
installed on stacks themselves; rather it is installed in the boilers 
or the ductwork that connect the boiler to a stack. We also 
interviewed stakeholders to learn about trends in installing pollution 
control equipment and reviewed relevant reports on this topic. 

To determine the number of tall stacks that have been built above 
their GEP height since 1988, we used our survey to obtain information 
from state officials about the GEP height for these stacks. Twenty-two 
states had stacks that were over 500 feet that were built since 1988, 
and we received survey responses from all of them. In our survey, we 
also asked for reasons that a stack was built above GEP, when 
applicable. In cases where state officials could not provide specific 
reasons, we contacted the utilities that operate the plants with these 
stacks to obtain this information. Specifically, we contacted 
utilities that were involved in operating 15 of the 17 stacks that 
were built since 1988 and exceed GEP height, and we were able to 
interview utilities operating 12 of these stacks. We did not contact 
the utilities that operate the other 2 stacks, because the stacks are 
each less than 2 feet above GEP. We also interviewed companies that 
design and build power plants to ask about some of the general factors 
that are considered when deciding on stack height. We focused on 
stacks built since 1988, because that was the year that EPA's 
regulations for determining GEP height were largely affirmed by the 
District of Columbia Court of Appeals. EPA began the process of 
developing these regulations in the late 1970s, but the final 
regulations were not issued until 1985. The regulations were then 
challenged in court and were largely affirmed in 1988. 

Finally, we conducted site visits to two coal power plants in Ohio. We 
selected this state because it contained several coal power plants 
with tall stacks, including some stacks that were built in 1988 or 
later. During this visit, we interviewed utility officials that 
operated these plants, along with state and local officials involved 
in permitting these plants. 

We conducted this work from July 2010 through May 2011 in accordance 
with all sections of GAO's quality assurance framework that are 
relevant to our objectives. This framework requires that we plan and 
perform the engagement to obtain sufficient, appropriate evidence to 
meet our stated objectives and to discuss any limitations in our work. 
We believe that the information and data obtained, and the analysis 
conducted, provide a reasonable basis for any findings and conclusions. 

[End of section] 

Appendix II: Distribution of Tall Stacks by State: 

Table 4 provides counts of the number of stacks 500 feet or higher-- 
tall stacks--by state. In addition, the table provides information on 
the generating capacity of the boilers attached to these stacks. 

Table 4: Number of Tall Stacks at Coal Power Plants by State and 
Associated Generating Capacity of Boilers Attached to These Stacks: 

State: Ohio; 
Number of tall stacks: 22; 
Generating capacity (megawatts): 19,626. 

State: Kentucky; 
Number of tall stacks: 22; 
Generating capacity (megawatts): 14,491. 

State: Indiana; 
Number of tall stacks: 19; 
Generating capacity (megawatts): 14,286. 

State: Illinois; 
Number of tall stacks: 19; 
Generating capacity (megawatts): 11,824. 

State: Pennsylvania; 
Number of tall stacks: 17; 
Generating capacity (megawatts): 15,765. 

State: Alabama; 
Number of tall stacks: 14; 
Generating capacity (megawatts): 11,664. 

State: Missouri; 
Number of tall stacks: 12; 
Generating capacity (megawatts): 9,360. 

State: West Virginia; 
Number of tall stacks: 12; 
Generating capacity (megawatts): 13,920. 

State: Michigan; 
Number of tall stacks: 12; 
Generating capacity (megawatts): 8,971. 

State: Georgia; 
Number of tall stacks: 11; 
Generating capacity (megawatts): 13,793. 

State: Texas; 
Number of tall stacks: 11; 
Generating capacity (megawatts): 9,277. 

State: Wyoming; 
Number of tall stacks: 10; 
Generating capacity (megawatts): 4,486. 

State: Wisconsin; 
Number of tall stacks: 10; 
Generating capacity (megawatts): 5,264. 

State: Arizona; 
Number of tall stacks: 9; 
Generating capacity (megawatts): 4,704. 

State: Colorado; 
Number of tall stacks: 8; 
Generating capacity (megawatts): 3,820. 

State: Utah; 
Number of tall stacks: 7; 
Generating capacity (megawatts): 4,608. 

State: Oklahoma; 
Number of tall stacks: 7; 
Generating capacity (megawatts): 4,112. 

State: Florida; 
Number of tall stacks: 7; 
Generating capacity (megawatts): 5,720. 

State: Minnesota; 
Number of tall stacks: 6; 
Generating capacity (megawatts): 4,395. 

State: Tennessee; 
Number of tall stacks: 6; 
Generating capacity (megawatts): 6,292. 

State: North Dakota; 
Number of tall stacks: 6; 
Generating capacity (megawatts): 2,997. 

State: Louisiana; 
Number of tall stacks: 5; 
Generating capacity (megawatts): 3,207. 

State: Kansas; 
Number of tall stacks: 5; 
Generating capacity (megawatts): 3,738. 

State: Iowa; 
Number of tall stacks: 4; 
Generating capacity (megawatts): 3,187. 

State: Montana; 
Number of tall stacks: 4; 
Generating capacity (megawatts): 2,272. 

State: North Carolina; 
Number of tall stacks: 4; 
Generating capacity (megawatts): 3,404. 

State: Arkansas; 
Number of tall stacks: 3; 
Generating capacity (megawatts): 3,958. 

State: Nebraska; 
Number of tall stacks: 3; 
Generating capacity (megawatts): 2,014. 

State: South Carolina; 
Number of tall stacks: 3; 
Generating capacity (megawatts): 1,564. 

State: Nevada; 
Number of tall stacks: 2; 
Generating capacity (megawatts): 572. 

State: Delaware; 
Number of tall stacks: 1; 
Generating capacity (megawatts): 164. 

State: Oregon; 
Number of tall stacks: 1; 
Generating capacity (megawatts): 601. 

State: Maryland; 
Number of tall stacks: 1; 
Generating capacity (megawatts): 728. 

State: New York; 
Number of tall stacks: 1; 
Generating capacity (megawatts): 655. 

State: Total; 
Number of tall stacks: 284; 
Generating capacity (megawatts): 215,439. 

Source: GAO analysis of EIA data and survey results. 

[End of table] 

[End of section] 

Appendix III: GAO Contact and Staff Acknowledgments: 

GAO Contact: 

David C. Trimble, (202) 512-3841 or trimbled@gao.gov: 

Staff Acknowledgments: 

In addition to the individual named above, key contributors to this 
report include Barbara Patterson (Assistant Director), Scott Heacock, 
Beth Reed Fritts, and Jerome Sandau. Important assistance was also 
provided by Antoinette Capaccio, Cindy Gilbert, Alison O'Neill, Madhav 
Panwar, and Katherine Raheb. 

[End of section] 

Footnotes: 

[1] For the purposes of this report, we consider tall smokestacks to 
be those that are 500 feet or higher. 

[2] Federal regulations further define GEP as the higher of 65 meters 
(about 213 feet), the results of a calculation based on the dimensions 
of nearby structure(s), or the results of a fluid modeling 
demonstration. The calculation based on the dimensions of nearby 
structure(s) that applies to stacks built after January 12, 1979, 
states that GEP = H + 1.5 L, where H is equal to the height of nearby 
structure(s) and L is equal to the height or width of nearby 
structure(s), whichever is less. For stacks built since December 31, 
1970, and in existence on January 12, 1979, this calculation is GEP = 
2.5H, where H is equal to the height of nearby structure(s). 

[3] Ozone is formed through a series of chemical reactions between 
NOx; other chemicals in the atmosphere, known as volatile organic 
compounds; and sunlight. Cars and power plants that burn fossil fuels 
are contributors of NOx pollution. 

[4] 40 U.S.C. § 7423(c) (2006). GEP is a regulatory term used to refer 
to the minimal height necessary to avoid excessive downwash, but does 
not necessarily imply that the GEP height is optimized based on 
structural engineering principles. 

[5] For stacks in existence on January 12, 1979, and for which the 
owner or operator had obtained all applicable permits or approvals, 
the GEP height formula is 2.5 times the height of nearby structure(s). 
Structures that are next to one another are considered a single 
structure if their "distance of separation is less than their smallest 
dimension (height or width)." See EPA, Guidelines for Determination of 
Good Engineering Practice Stack Height (Research Triangle Park, N.C., 
1985). 

[6] Prevention of significant deterioration is a standard used to 
refer to areas of the country which are already in attainment with 
NAAQS. Sources that are constructed or undergo major modifications in 
such areas must install the Best Available Control Technology to help 
prevent the air quality from deteriorating to the level set by NAAQS. 

[7] EPA believes that the Transport Rule addresses the court's 
concerns with CAIR by, among other things, introducing a state-
specific methodology for identifying significant contributions to 
nonattainment and interference with maintenance, and proposing remedy 
options to ensure that all necessary reductions are achieved in the 
covered states. 

[8] In particular, the Transport Rule focuses on helping states attain 
the 8-hour ozone standard and the particulate matter 2.5 standard. 
This particulate matter 2.5 standard focuses on particles that are 2.5 
micrometers in diameter and smaller, about 1/30th the diameter of a 
human hair, which have been shown to aggravate respiratory and 
cardiovascular disease. 

[9] Massachusetts Institute of Technology, The Future of Coal 
(Cambridge, Mass., 2007). 

[10] For the purposes of this report, our discussion of capacity 
refers to nameplate capacity, which refers to maximum rated output of 
electric generating units as designed by the manufacturer. 

[11] Percentages may not sum to 100 due to rounding. 

[12] Pollution control equipment is not installed directly on 
smokestacks. Instead, pollution control equipment is installed 
throughout a power plant to reduce the formation of pollutants and 
remove them before they are emitted through the stack. 

[13] NESCAUM, The Nature of the Ozone Air Quality Problem in the Ozone 
Transport Region: A Conceptual Description (Boston, Mass., August 
2010). The Ozone Transport Region of the eastern United States covers 
over 62 million people living in Connecticut, Delaware, the District 
of Columbia, Maine, Maryland, Massachusetts, New Hampshire, New 
Jersey, New York, Pennsylvania, Rhode Island, Vermont, and northern 
Virginia. 

[14] There are also other air models that are used to predict the 
dispersion of air pollution from specific sources of emissions, such 
as AERMOD. The data inputs into AERMOD include 5 years of regionally 
representative meteorological data, emissions rate, and stack 
parameters (height, velocity, and temperature of emissions). 

[15] A megawatt is a unit for measuring the electric generation 
capacity of a power plant. One megawatt of capacity operating for 1 
full day produces 24 megawatt-hours--or 24,000 kilowatt-hours of 
electricity. According to EIA analysis, the typical American home 
consumes about 11,040 kilowatt-hours of electricity a year. 

[16] For the purposes of this report, we refer to the capacity of 
boilers based on information from the EIA-860 form. This form provides 
capacity for generators that are associated with boilers at power 
plants. 

[17] GEP regulations permit nearby terrain features to be taken into 
account, but only when determining GEP through the fluid model 
approach. These terrain features must generally be within 0.5 mile to 
2 miles of the source being modeled. If GEP is calculated using only 
the dimensions of nearby buildings, such nearby terrain features are 
not part of this calculation. See EPA, Guidelines for Determination of 
Good Engineering Practice Stack Height. 

[18] The guidance on determining GEP permits aerodynamic structures 
such as hyperbolic cooling towers to be taken into account, but only 
when determining GEP through the fluid model approach. See EPA, 
Guidelines for Determination of Good Engineering Practice Stack Height. 

[19] The continued exemption of a stack also depends on whether the 
source using the stack is reconstructed or undergoes a major 
modification. Section 123 also exempts federal coal-fired power plants 
which commenced operations before July 1, 1957, and whose stacks were 
constructed under a contract awarded before February 8, 1974. 

[20] As we noted earlier, the Clean Air Act began requiring the 
incorporation of emissions limitations into operating permits in 1990. 
Prior to the 1990 amendments to the Clean Air Act, information 
applicable to individual sources, including the source's pollution 
control obligations, was not collected in a single permit but could be 
scattered throughout numerous provisions of the SIP. This fact may 
have contributed to officials' difficulty in finding information on 
sources for which GEP was calculated at an earlier time. 

[21] Our survey of 38 states included some stacks that were at power 
plants that were not fueled by coal or that were not operating yet. 
When we restricted our analysis to operating tall stacks at coal power 
plants, we found that such stacks were operating in 34 states. 

[End of section] 

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