2017 National Emissions Inventory Events and Nonroad Release and Updated Point Release Technical Support Document (Draft) February 2020


y,D,r«^
f A '

2017 National Emissions Inventory
Events and Nonroad Release and Updated
Point Release

Technical Support Document (DRAFT)

February 2020

-------
February 2020

2017 National Emissions Inventory, Feb2020 version
Technical Support Document

U.S. Environmental Protection Agency
Office of Air Quality Planning and Standards
Air Quality Assessment Division
Emissions Inventory and Analysis Group
Research Triangle Park, North Carolina

-------
Contents

List of Tables	ii

List of Figures	iii

Acronyms and Chemical Notations	iv

1	Introduction	1-1

1.1	What data are included in the 2017 NEl, Feb 2020 release?	1-1

1.2	What is included in this documentation?	1-2

1.3	Where can I obtain the 2017 NEI data?	1-2

1.3.1	Emission Inventory System Gateway	1-2

1.3.2	NEI main webpage	1-2

1.3.3	Modeling files	1-3

1.4	Why is the NEI created?	1-3

1.5	How is the NEI created?	1-3

1.6	Who are the target audiences for the 2017 NEI?	1-5

1.7	What are appropriate uses of the 2017 NEI and what are the caveats about the data?	1-6

1.8	Updates in the 2017 NEI point, February 2020 version	1-7

2	2017 NEI contents overview	2-1

2.1	What are EIS sectors?	2-1

2.2	How is the NEI constructed?	2-3

2.2.1	Toxics Release Inventory data	2-4

2.2.2	Chromium speciation	2-4

2.2.3	HAP augmentation	2-6

2.2.4	PM augmentation	2-7

2.2.5	Other EPA datasets	2-7

2.2.6	Data Tagging	2-7

2.2.7	Inventory Selection	2-8

2.3	References for 2017 inventory contents overview	2-8

3	Point sources	3-1

3.1	Point source approach: 2017	3-1

3.1.1	QA review of S/L/T data	3-1

3.1.2	Sources of EPA data and selection hierarchy	3-2

3.1.3	Particulate matter augmentation	3-5

3.1.4	Chromium speciation	3-5

3.1.5	Use of the 2017 Toxics Release Inventory	3-5

3.1.6	HAP augmentation based on emission factor ratios	3-11

3.1.7	Cross-dataset tagging rules for overlapping pollutants	3-12

3.1.8	Additional quality assurance and findings	3-13

3.2	Airports: aircraft-related emissions	3-13

i

-------
3.2.1	Sector Description	3-14

3.2.2	Sources aircraft emissions estimates	3-14

3.3	Rail yard-related emissions	3-15

3.4	EGUs	3-15

3.5	Landfills	3-16

3.6	2017EPA_gapfills	3-18

3.7	BOEM	3-18

3.8	PM species	3-18

3.9	References for point sources	3-18

4	Nonroad Equipment - Diesel, Gasoline and Other	4-1

4.1	Sector Description	4-1

4.2	MOVES-Nonroad	4-2

4.3	Default MOVES code and database	4-3

4.4	Additional Data: Nonroad County Databases (CDBs)	4-3

4.5	MOVES runs	4-5

4.6	Use of California Submitted Emissions	4-6

4.7	References for nonroad mobile	4-7

5	EVENTS Data Category	5-1

5.1	Sector description and overview	5-1

5.2	Sources of data	5-2

5.3	EPA methods summary	5-3

5.3.1	National Fire Information Data	5-3

5.3.2	State/Local/Tribal fire information	5-5

5.3.3	Emissions Estimation Methodology	5-8

5.4	Quality Assurance (QA) of Final Results	5-14

5.4.1	Input Fire Information Data Sets	5-14

5.4.2	Daily Fire Locations from SmartFire2	5-15

5.4.3	Emissions Estimates	5-15

5.4.4	Additional quality assurance on final results	5-15

5.5	Emissions Summaries	5-15

5.6	References	5-24

List of Tables

Table 1-1: Point source reporting thresholds (potential to emit) for CAPs in the AERR	1-4

Table 1-2: Examples of major current uses of the NEI	1-5

ii

-------
Table 2-1: EIS sectors/source categories with EIS data category emissions reflected	2-1

Table 2-2: Valid chromium pollutant codes	2-4

Table 3-1: Data sets and selection hierarchy used for 2017 NEI August release point source data category	3-3

Table 3-2: Mapping of TRI pollutant codes to EIS pollutant codes	3-6

Table 3-3: Landfill gas emission factors for 29 EIS pollutants	3-17

Table 4-1: MOVES-Nonroad equipment and fuel types	4-1

Table 4-2: Pollutants produced by MOVES-Nonroad for 2017 NEI	4-2

Table 4-3: Selection hierarchy for the Nonroad Mobile data category	4-4

Table 4-4: Submitted MOVES-Nonroad input tables, by agency	4-4

Table 4-5: Contents of the Nonroad Mobile supplemental folder	4-5

Table 4-6: HAPs calculated using MOVES ratios for California Nonroad SCCs	4-6

Table 5-1: SCCs for wildland fires	5-2

Table 5-2: 2017 NEI Wildfire and Prescribed Fires selection hierarchy	5-2

Table 5-3: PM species for all events, computed as fraction of total PM2.5	5-3

Table 5-4: National fire information databases used in EPA's 2017 NEI wildland fire emissions estimates	5-3

Table 5-5: Brief description of fire activity information submitted for 2017 NEI inventory use	5-6

Table 5-6: 2017 National SmartFire2 Reconciliation Weights	5-10

Table 5-7: Emission factor regions used to assign HAP emission factors for the 2017 NEI	5-11

Table 5-8: Prescribed fire HAP emission factors (lb/ton fuel consumed) for the 2017 NEI	5-11

Table 5-9: Wildfire HAP emission factors (lbs/ton fuel consumed) for the 2017 NEI	5-12

Table 5-10: CONUS (lower 48 states) and Alaska and Hawaii fire type information for 2017 NEI WLFs	5-17

Table 5-11: Summary of acres burned and PM2.5 emissions by state, fire type, and combustion phase	5-19

List of Figures

Figure 5-1: 2017 NEI Wildland Fire Data Sources including S/L/Ts	5-5

Figure 5-2: Processing flow for fire emission estimates in the 2017 NEI inventory	5-9

Figure 5-3: Default fire type assignment by state and month in cases where a satellite detect is only source of

fire information	5-10

Figure 5-4: BlueSky Modeling Framework	5-14

Figure 5-5: Annual comparison of PM2.5 emissions for lower 48 states	5-16

Figure 5-6: Annual comparison of area burned for lower 48 states	5-16

Figure 5-7: Monthly acres burned by fire type for 2017 NEI CONUS Wildland Fires	5-17

Figure 5-8: Monthly PM2.5 by fire type for 2017 NEI CONUS Wildland Fires	5-18

Figure 5-9: Total 2017 NEI area burned by state	5-22

Figure 5-10: Total 2017 NEI PM2.5 emissions by state	5-23

Figure 5-11: 2017NEI county PM2.5 emissions in tons per square mile	5-23

Figure 5-12: 2017NEI county area burned in acres per square mile	5-24

iii

-------
Acronyms and Chemical Notations

AERR	Air Emissions Reporting Rule

APU	Auxiliary power unit

BEIS	Biogenics Emissions Inventory System

CI	Category 1 (commercial marine vessels)

C2	Category 2 (commercial marine vessels)

C3	Category 3 (commercial marine vessels)

CAMD	Clean Air Markets Division (of EPA Office of Air and Radiation)

CAP	Criteria Air Pollutant

CBM	Coal bed methane

CDL	Cropland Data Layer

CEC	North American Commission for Environmental Cooperation

CEM	Continuous Emissions Monitoring

CENRAP	Central Regional Air Planning Association

CERR	Consolidated Emissions Reporting Rule

CFR	Code of Federal Regulations

CH4	Methane

CMU	Carnegie Mellon University

CMV	Commercial marine vessels

CNG	Compressed natural gas

CO	Carbon monoxide

C02	Carbon dioxide

CSV	Comma Separated Variable

dNBR	Differenced normalized burned ratio

E10	10% ethanol gasoline

EDMS	Emissions and Dispersion Modeling System

EF	emission factor

EGU	Electric Generating Utility

EIS	Emission Inventory System

EAF	Electric arc furnace

EF	Emission factor

El	Emissions Inventory

EIA	Energy Information Administration

EMFAC	Emission FACtor (model) - for California

EPA	Environmental Protection Agency

ERG	Eastern Research Group

ERTAC	Eastern Regional Technical Advisory Committee

FAA	Federal Aviation Administration

FACTS	Forest Service Activity Tracking System

FCCS	Fuel Characteristic Classification System

FETS	Fire Emissions Tracking System

FWS	United States Fish and Wildlife Service

FRS	Facility Registry System

GHG	Greenhouse gas

GIS	Geographic information systems

GPA	Geographic phase-in area

iv

-------
GSE	Ground support equipment

HAP	Hazardous Air Pollutant

HCI	Hydrogen chloride (hydrochloric acid)

Hg	Mercury

HMS	Hazard Mapping System

ICR	Information collection request

l/M	Inspection and maintenance

IPM	Integrated Planning Model

KMZ	Keyhole Markup Language, zipped (used for displaying data in Google Earth

LRTAP	Long-range Transboundarv Air Pollution

LTO	Landing and takeoff

LPG	Liquified Petroleum Gas

MARAMA	Mid-Atlantic Regional Air Management Association

MATS	Mercury and Air Toxics Standards

MCIP	Meteorology-Chemistry Interface Processor

MMT	Manure management train

MOBILE6	Mobile Source Emission Factor Model, version 6

MODIS	Moderate Resolution Imaging Spectroradiometer

MOVES	Motor Vehicle Emissions Simulator

MW	Megawatts

MWC	Municipal waste combustors

NAA	Nonattainment area

NAAQS	National Ambient Air Quality Standards

NAICS	North American Industry Classification System

NARAP	North American Regional Action Plan

NASF	National Association of State Foresters

NASS	USDA National Agriculture Statistical Service

NATA	National Air Toxics Assessment

NCD	National County Database

NEEDS	National Electric Energy Data System (database)

NEI	National Emissions Inventory

NESCAUM Northeast States for Coordinated Air Use Management

NFEI	National Fire Emissions Inventory

NG	Natural gas

NH3	Ammonia

NMIM	National Mobile Inventory Model

NO	Nitrous oxide

N02	Nitrogen dioxide

NOAA	National Oceanic and Atmospheric Administration

NOx	Nitrogen oxides

03	Ozone

OAQPS	Office of Air Quality Standards and Planning (of EPA)

OEI	Office of Environmental Information (of EPA)

ORIS	Office of Regulatory Information Systems

OTAQ	Office of Transportation and Air Quality (of EPA)

PADD	Petroleum Administration for Defense Districts

v

-------
PAH	Polycyclic aromatic hydrocarbons

Pb	Lead

PCB	Polychlorinated biphenyl

PM	Particulate matter

PM25-CON	Condensable PM2.5

PM25-FIL	Filterable PM2.5

PM25-PRI	Primary PM2.55 (condensable plus filterable)

PM2.5	Particulate matter 2.5 microns or less in diameter

PM10	Particular matter 10 microns or less in diameter

PM10-FIL	Filterable PM10

PM10-PRI	Primary PM10

POM	Polycyclic organic matter

POTW	Publicly Owned Treatment Works

PSC	Program system code (in EIS)

RFG	Reformulated gasoline

RPD	Rate per distance

RPP	Rate per profile

RPV	Rate per vehicle

RVP	Reid Vapor Pressure

Rx	Prescribed (fire)

SCC	Source classification code

SEDS	State Energy Data System

SFvl	SMARTFIRE version 1

SFv2	SMARTFIRE version 2

S/L/T	State, local, and tribal (agencies)

SMARTFIRE	Satellite Mapping Automated Reanalvsis Tool for Fire Incident Reconciliation

SMOKE	Sparse Matrix Operator Kernel Emissions

S02	Sulfur dioxide

S04	Sulfate

TAF	Terminal Area Forecasts

TEISS	Tribal Emissions Inventory Software Solution

TRI	Toxics Release Inventory

UNEP	United Nations Environment Programme

USDA	United States Department of Agriculture

VMT	Vehicle miles traveled

VOC	Volatile organic compounds

USFS	United States Forest Service

WebFIRE	Factor Information Retrieval System

WFU	Wildland fire use

WLF	Wildland fire

WRAP	Western Regional Air Partnership

WRF	Weather Resea rch and Forecasting Model

vi

-------
1 Introduction

EPA has updated the 2017 National Emissions Inventory (NEI), which includes an updated version of the data on
pollutant emissions for individual facilities (or "point sources"), emissions from prescribed burning and wildfires,
and emissions from nonroad mobile sources. The point sources data included in this release supersedes the
prior version released in August 2019. The full 2017 NEI is expected to be completed by Spring 2020, with data
about onroad mobile sources and nonpoint sources expected at that time to complete the release. This is the
first inventory for which EPA is releasing the data incrementally data prior to the full NEI release, providing the
data as soon as possible for public use. The 2017 NEI February release is available on the web at the 2017 NEI
Data page.

1.1 What data are included in the 2017 NEI, Feb 2020 release?

The National Emissions Inventory (NEI) is a national compilation of air emission estimates of criteria air
pollutants (CAPs), the precursors of CAPs, and hazardous air pollutants (HAPs). The hazardous air pollutants that
are included in the NEI are based on Section 112(b) of the Clean Air Act. State, local and tribal air agencies
submit emission estimates to EPA and the Agency adds information from EPA emissions programs, such as the
emission trading program, Toxics Release Inventory, and data collected during rule development or compliance
testing. The NEI includes estimates of emissions from stationary sources (large and small industries, commercial,
institutional and consumer), mobile sources, fires and biogenic emissions. EPA uses the NEI in rule
development, non-attainment area designations, and as an input to various reports and assessments.

The point data are collected from state, local, and tribal (S/L/T) air agencies and the Environmental Protection
Agency (EPA) emissions programs including the Toxics Release Inventory (TRI), the Acid Rain Program, and
Maximum Achievable Control Technology (MACT) standards development. The 2017 point, nonroad mobile and
events inventories, or more likely minor updates to it, will become a part of the full 2017 NEI to be released later
which will contain emissions from all data categories. This document discusses only the point, nonroad mobile
and events data categories of the NEI. The NEI program develops datasets, blends data from these multiple
sources, and performs data processing steps that further enhance, quality assure, and augment the compiled
data.

The emissions data in the NEI are compiled at different levels of granularity, depending on the data category. For
point sources (in general, large facilities), emissions are inventoried at a process-level within a facility. For
nonpoint sources (typically smaller, yet pervasive sources) and mobile sources (both onroad and nonroad),
emissions are given as county totals. For marine vessel and railroad in-transit sources, emissions are given at the
sub-county polygon shape-level. For wildfires and prescribed burning, the data are compiled as day-specific,
coordinate-specific (similar to point) events in the "event" portion of the inventory, and these emission
estimates are further stratified by smoldering and flaming components.

The pollutants included in the NEI are the pollutants associated with the National Ambient Air Quality Standards
(NAAQS), known as CAPs, as well as HAPs associated with EPA's Air Toxics Program. The CAPs have ambient
concentration limits or are precursors for pollutants with such limits from the NAAQS program. These pollutants
include lead (Pb), carbon monoxide (CO), nitrogen oxides (NOx), volatile organic compounds (VOCs), sulfur
dioxide (S02), particulate matter 10 microns or less (PM10), particulate matter 2.5 microns or less (PM2.5), and
ammonia (NH3), which is technically not a CAP, but an important PM precursor. The HAP pollutants include the
187 remaining HAP pollutants (methyl ethyl ketone was removed) from the original 188 listed in Section 112(b)

1-1

-------
of the 1990 Clean Air Act Amendments1. There are many different types of HAPs. For example, some are acid
gases such as hydrochloric acid (HCI); others are heavy metals such as mercury (Hg), nickel and cadmium; and
others are organic compounds such as benzene, formaldehyde, and acetaldehyde.

1.2 What is included in this documentation?

This technical support document (TSD) provides a reference for the 2017 NEI February 2020 release. The
primary purpose of this document is to explain the sources of information included in the February 2020 version
of the point, nonroad mobile and event data categories for the 2017 NEI. This includes showing the sources of
data and types of sources that are used, and then providing more information about the EPA-created
components of the data. Section II provides an overview of the contents of the inventory. Section 3 provides an
overview of point sources. Section 4 provides information on nonroad mobile sources. Fires (wild and prescribed
burning) are discussed in Section 5.

1.3 Where can I obtain the 2017 NEI data?

The 2017 NEI data are available in several different ways listed below. Data are available to the reporting
agencies and EPA staff via the Emission Inventory System (EIS).

1.3.1 Emission Inventory System Gateway

The EIS Gateway is available to all EPA staff, EIS data submitters (i.e., the S/L/T air agency staff), Regional
Planning Organization staff that support state, local and tribal agencies, and contractors working for the EPA on
emissions related work. The EIS reports functions can be used to obtain raw input datasets and create summary
files from these datasets as well as older versions of the NEI such as 2011 and 2008. The 2017 NEI Point,

Nonroad and Events dataset in the EIS is called "2017NEI_Feb2020." Note that if you run facility-, unit- or
process-level reports in the EIS, you will get the 2017 NEI emissions, but the facility inventory, which is dynamic
in the EIS, will reflect more current information. For example, if an Agency ID has been changed since the time
we ran the reports for the public website (August 2019), then that new Agency ID will be in the Facility Inventory
or a Facility Configuration report in the EIS but not in the report on the public website nor the Facility Emissions
Summary reports run on the "2017NEI_Feb2020" dataset in the EIS.

1.3.2 NEI main webpage

Next, data from the EIS are exported for public release on the 2017 NEI Data webpage. The 2017 NEI Data page
includes the most recent publicly-available version of the 2017 NEI. The 2017 NEI webpage includes the 2017
NEI plan and schedules, all publicly-available supporting materials by inventory data category (e.g., point,
nonroad mobile and events for now, but eventually nonpoint and onroad mobile) and this TSD.

On the 2017 NEI Data page, two types of point data summaries are available, facility summaries and process-
level summaries. The source classification codes (SCC) data files section of the webpage provides the process
level summaries for the point and nonroad mobile sources. These detailed CSV files (provided in zip files) contain
emissions at the process level. Due to their size, they are broken out into EPA regions. Facility-level by pollutant
summaries are also available. These CSV files must be "linked" (as opposed to imported) to open them with
Microsoft® Access®. County and tribe-level summaries for events are also provided.

1 The original of HAPs is available on the EPA Technology Transfer Network - Air Toxics Web Site.

1-2

-------
The 2017 NEI Documentation page includes links to the NEI TSD and supporting materials referenced in this TSD.
This page is a working page, meaning that content is updated as new products are developed.

1.3.3 Modeling files

The modeling files, provided on the Air Emissions Modeling website, are provided in formats that can be read by
the Sparse Matrix Operator Kernel Emissions (SMOKE). These files are also CSV formats that can be read by
other systems, such as databases. The modeling files provide the process-level emissions apportioned to release
points, and the release parameters for the release points. Release parameters include stack height, stack exit
diameter, exit temperature, exit velocity and flow rate. The EPA may make changes to the NEI modeling files
prior to use. The 2017 modeling platform is based on the 2017 NEI and is under development; it is expected to
be posted in the spring of 2020. Any changes between the NEI and modeling platform data will be described in
an accompanying TSD for the 2017 Emissions Modeling Platform, which would also be posted at the above
website.

The point, nonroad mobile and events data category SMOKE flat files for the February 2020 version of the 2017
NEI will be posted on the 2017 NEI Flat Files FTP site.

1.4 Why is the NEI created?

The NEI is created to provide the EPA, federal, state, local and tribal decision makers, and the national and
international public the best and most complete estimates of CAP and HAP emissions. While the EPA is not
directly obligated to create the NEI, the Clean Air Act authorizes the EPA Administrator to implement data
collection efforts needed to properly administer the NAAQS program. Therefore, the Office of Air Quality
Planning and Standards (OAQPS) maintains the NEI program in support of the NAAQS. Furthermore, the Clean
Air Act requires States to submit emissions to the EPA as part of their State Implementation Plans (SIPs) that
describe how they will attain the NAAQS. The NEI is used as a starting point for many SIP inventory development
efforts and for states to obtain emissions from other states needed for their modeled attainment
demonstrations.

While the NAAQS program is the basis on which the EPA collects CAP emissions from the S/L/T air agencies, it
does not require collection of HAP emissions. For this reason, the HAP reporting requirements are voluntary.
Nevertheless, the HAP emissions are an essential part of the NEI program. These emissions estimates allow EPA
to assess progress in meeting HAP reduction goals described in the Clean Air Act amendments of 1990. These
reductions seek to reduce the negative impacts to people of HAP emissions in the environment, and the NEI
allows the EPA to assess how much emissions have been reduced since 1990.

1.5 How is the NEI created?

The Air Emissions Reporting Rule (AERR) is the regulation that requires states to submit CAP emissions, and the
Emissions Inventory Sytem is the data system used to collect, QA, and compile those submittals as well as EPA
augmentation data. Most S/L/T air agencies also provide voluntary submissions of HAP emissions. The 2008 NEI
was the first inventory compiled using the AERR, rather than its predecessor, the Consolidated Emissions
Reporting Rule (CERR). The 2017 NEI is the fourth AERR-based inventory, and improvements in the 2017 NEI
process reflect lessons learned by the S/L/T air agencies and EPA from the prior NEI efforts. The AERR requires
agencies to report all sources of emissions, except fires and biogenic sources. Reporting of open fire sources,
such as wildfires, is encouraged, but not required. Sources are divided into large groups called "data categories":
stationary sources are "point" or "nonpoint" (county totals) and mobile sources are either onroad (cars and

1-3

-------
trucks driven on roads) or nonroad (locomotives, aircraft, marine, off-road vehicles and nonroad equipment
such as lawn and garden equipment).

The AERR has emissions thresholds above which States must report stationary emissions as "point" sources,
with the remainder of the stationary emissions reported as "nonpoint" sources.

The AERR changed the way these reporting thresholds work, as compared to the CERR, by changing these
thresholds to "potential to emit" thresholds rather than actual emissions thresholds. In both the CERR and the
AERR, the emissions that are reported are actual emissions, despite that the criteria for which sources to report
is now based on potential emissions. The AERR requires emissions reporting for point sources every year, with
additional requirements every third year in the form of lower point source emissions thresholds, and 2017 is one
of these third-year inventories.

Table 1-1 provides the potential-to-emit reporting thresholds that applied for the 2017 NEI cycle. "Type B" is the
terminology in the rule that represents the lower emissions thresholds required for point sources in the triennial
years. The reporting thresholds are sources with potential to emit of 100 tons/year or more for most criteria
pollutants, with the exceptions of CO (1000 tons/year), and, updated starting with the 2014 inventory, Pb (0.5
tons/year, actual). As shown in the table, special requirements apply to nonattainment area (NAA) sources,
where even lower thresholds apply. The relevant ozone (03), CO, and PM10 nonattainment areas that applied
during the year that the S/L/T agencies submitted their data for the 2017 NEI are available on the
Nonattainment Areas for Criteria Pollutants (Green Book) web site.

Table 1-1: Point source reporting thresholds (potential to emit) for CAPs in the AERR

Pollutant

Triennial reporting thresholds1

Type B Sources

Thresholds within Nonattainment Areas

(1) so2

>100

>100

(2) VOC

>100

03(moderate) > 100



03 (serious) > 50



03 (severe) > 25



03 (extreme) > 10

(3) NOx

>100

>100

(4) CO

>1000

03 (all areas) > 100

CO (all areas) > 100

(5) Lead

>0.5 (actual)

>0.5 (actual)

(6) Primary PMio

>100

PMio(moderate) >100

PMio(serious) >70

(7) Primary PM2 5

>100

>100

(8) NH3

>100

>100

thresholds for point source determination shown in tons per year of potential to emit as
defined in 40 CFR part 70, with the exception of lead.

Based on the AERR requirements, S/L/T air agencies submit emissions or model inputs of point, nonpoint,
onroad mobile, nonroad mobile, and fires emissions sources. With the exception of California, reporting
agencies were required to submit model inputs for onroad and nonroad mobile sources instead of emissions.
For the 2017 NEI, all these emissions and inputs were required to be submitted to the EPA per the AERR by
December 31, 2018 (with an extension given through January 15, 2019). Once the initial reporting NEI period
closed, the EPA provided feedback on data quality such as suspected outliers and missing data by comparing to

1-4

-------
previously established emissions ranges and past inventories. In addition, the EPA augmented the S/L/T data
using various sources of data and augmentation procedures. This documentation provides a detailed account of
EPA's quality assurance and augmentation methods.

1.6 Who are the target audiences for the 2017 NEI?

The comprehensive nature of the NEI allows for many uses and, therefore, its target audiences include EPA staff
and policy makers, the U.S. public, other federal and S/L/T decision makers, and other countries. Table 1-2
below lists the major current uses of the NEI and the plans for use of the 2017 NEI in those efforts. These uses
include those by the EPA in support of the NAAQS, Air Toxics, and other programs as well as uses by other
federal and regional agencies and for international needs. In addition to this list, the NEI is used to respond to
Congressional inquiries, provide data that supports university research, and allow environmental groups to
understand sources of air pollution.

Table 1-2: Examples of major current uses of the NEI

Audience

Purposes

U.S. Public

Learn about sources of air emissions

EPA-NAAQS

Regulatory Impact Analysis - benefits estimates using air quality modeling

NAAQS Implementations, including State Implementation Plans (SIPs)

Monitoring Rules

Final NAAQS designations

NAAQS Policy Assessments

Integrated Science Assessments

Transport Rule air quality modeling (e.g., Clean Air Interstate Rule, Cross-State Air Pollution Rule)

EPA-Air toxics

National Air Toxics Assessment (NATA)

Mercury and Air Toxics Standard - mercury risk assessment and Regulatory Impact Assessment

National Monitoring Programs Annual Report

Toxicity Weighted emission trends for the Government Performance and Reporting Act (GPRA)

Residual Risk and Technology Review - starting point for inventory development

EPA-other

NEI Reports - analysis of emissions inventory data

Report on the Environment

Air Emissions website for providing graphical access to CAP emissions for state maps and Google
Earth views of facility total emissions

Department of Transportation, national transportation sector summaries of CAPs

Black Carbon Report to Congress

Other federal or
regional agencies

Modeling in support of Regional Haze SIPs and other air quality issues

1-5

-------
Audience

Purposes

International

United Nations Environment Programme (UNEP) - global and North American Assessments

The Organization for Economic Co-operation and Development (OECD) - environmental data and
indicators report

UNECE Convention on Long-Range Transboundary Air Pollution (CLRTAP) - emission reporting
requirements, air quality modeling, and science assessments

Community Emissions Data System (CEDS) - science network for earth system, climate, and
atmospheric modeling

Commission for Environmental Cooperation (CEC) - North American emissions inventory
improvement and reduction policies

U.S. and Canada Air Quality Reports

Arctic Contaminants Action Program (ACAP) - national environmental and emission reduction
strategy for the Arctic Region

Other outside
parties

Researchers and graduate students

1.7 What are appropriate uses of the 2017 NEI and what are the caveats about the data?
As shown in the preceding section, the NEI provides a readily-available comprehensive inventory of both CAP
and HAP emissions to meet a variety of user needs. Although the accuracy of individual emissions estimates will
vary from facility-to-facility or county-to-county, the NEI largely meets the needs of these users in the aggregate,
Some NEI users may wish to evaluate and revise the emission estimates for specific pollutants from specific
source types for either the entire U.S. or for smaller geographical areas to meet their needs. Regulatory uses of
the NEI by the EPA, such as for interstate transport, always include a public review and comment period. Large-
scale assessment uses, such as the NATA study, also provide review periods and can serve as an effective
screening tool for identifying potential risks.

One of the primary goals of the NEI is to provide the best assessment of current emissions levels using the data,
tools and methods currently available. For significant emissions sectors of key pollutants, the available data,
tools and methods typically evolve over time in response to identified deficiencies and the need to understand
the costs and benefits of proposed emissions reductions. As these method improvements have been made,
there have not been consistent efforts to revise previous NEI year estimates to use the same methods as the
current year. Therefore, care must be taken when reviewing different NEI year publications as a time series with
the goal of determining the trend or difference in emissions from year to year. An example of such a method
change in the 2008 NEI v3 and 2011 NEI is the use of the Motor Vehicle Emissions Simulator (MOVES) model for
the onroad data category. Previous NEI years had used the Mobile Source Emission Factor Model, version 6
(MOBILES) and earlier versions of the MOBILE model for this data category. The 2011 NEI (2011v2) also used an
older version of MOVES (2014) that is being updated in the current 2017 NEI (MOVES2014b). The current
version of MOVES also calculates nonroad equipment emissions, adding VOCs and toxics, updating the gasoline
fuels used for nonroad equipment to be consistent with those used for onroad vehicles. These changes in
MOVES lead to a small increase in nonroad NOx emissions in some locations, introducing additional uncertainty
when comparing 2017 NEI to past inventories.

Other significant emissions sectors have also had improvements and, therefore, trends are also impacted by
inconsistent methods. Examples include paved and unpaved road PM emissions, ammonia fertilizer and animal
waste emissions, oil and gas production, residential wood combustion, solvents, industrial and
commercial/institutional fuel combustion and commercial marine vessel emissions.

Users should take caution in using the emissions data for filterable and condensable components of particulate
matter (PM10-FIL, PM2.5-FIL and PM-CON), which is not complete and should not be used at any aggregated

1-6

-------
level. These data are provided for users who wish to better understand the components of the primary PM
species, where they are available, in the disaggregated, process-specific emissions reports. Where not reported
by S/L/T agencies, the EPA augments these components (see Section 2.2.4). However, not all sources are
covered by this routine, and in mobile source and fire models, only the primary particulate species are
estimated. Thus, users interested in PM emissions should use the primary species of particulate matter (PM10-
PRI and PM25-PRI), described in this document simply as PM10 and PM2.5.

1.8 Updates in the 2017 NEI point, February 2020 version

Below is a list of items in the February 2020 release that are updated from the August 2019 release:

•	Added oil platform data for the Gulf of Mexico from the Bureau of Ocean Energy Management (BOEM)

•	Added railyard emissions (inadvertently left out of August release)

•	More extensive use of proposed rulemaking database from the Plywood and Composites Wood
Products Manufacturing Information Collection Request (ICR)

•	Improvements to hydrogen cyanide, cyanide, lead, and hexavalent chromium resulting from findings of
quality assurance

•	Minor data additions and corrections provide by state, local, and tribal partners
Additional issues not in the February 2020 release that will be included in the final 2017 NEI include:

•	The components of particulate matter: organic carbon, elemental carbon, sulfates, nitrates, and crustal
material

•	Diesel PM emissions from diesel fueled airport ground support equipment and locomotives

1-7

-------
2 2017 NEI contents overview

2.1 What are EIS sectors?

First used for the 2008 NEI, EIS Sectors continue to be used for all 2017 NEI data categories. The sectors were
developed to better group emissions for both CAP and HAP summary purposes. The sectors are based simply on
grouping the emissions by the emissions process as indicated by the SCC to an EIS sector. In building this list, we
gave consideration not only to the types of emissions sources our data users most frequently ask for, but also to
the need to have a relatively concise list in which all sectors have a significant amount of emissions of at least
one pollutant. The SCC-EIS Sector cross-walk used for the summaries provided in this document is available for
download from the Source Classification Codes (SCCs) website. No changes were made to the SCC-mapping or
sectors used for the 2017 NEI except where SCCs were retired, or new SCCs were added.

Some of the sectors include the nomenclature "NEC," which stands for "not elsewhere classified." This simply
means that those emissions processes were not appropriate to include in another EIS sector and their emissions
were too small individually to include as its own EIS sector.

Since the 2008 NEI, the inventory has been reported and compiled in EIS using five major data categories: point,
nonpoint, onroad, nonroad and events. The event category is used to compile day-specific data from prescribed
burning and wildfires. While events could be other intermittent releases such as chemical spills and structure
fires, prescribed burning and wildfires have been a focus of the NEI creation effort and are the only emission
sources contained in the event data category.

Table 2-1 shows the EIS sectors or source category component of the EIS sector in the left most column. EIS data
categories -Point, Nonpoint, Onroad, Nonroad, and Events- that have emissions in these sectors/source
categories are also reflected.

As Table 2-1 illustrates, many EIS sectors include emissions from more than one EIS data category because the
EIS sectors are compiled based on the type of emissions sources rather than the data category. Note that the
emissions summary sector "Mobile - Aircraft" is reported partly to the point and partly to the nonpoint data
categories and "Mobile - Commercial Marine Vessels" and "Mobile - Locomotives" are reported to the nonpoint
data category. We include biogenics emissions, "Biogenics - Vegetation and Soil," in the nonpoint data category
in the EIS; however, we document biogenics in its own Section (8). NEI users who aggregate emissions by EIS
data category rather than EIS sector should be aware that these changes will give differences from historical
summaries of "nonpoint" and "nonroad" data unless care is taken to assign those emissions to the historical
grouping.

Table 2-1: EIS sectors/source categories with EIS data category emissions reflected

Component

EIS Sector or EIS Sector: Source Category Name

Point

Nonpoint

Onroad

Nonroad

Event

Agriculture - Crops & Livestock Dust



0







Agriculture - Fertilizer Application



0







Agriculture - Livestock Waste

0

0







Biogenics - Vegetation and Soil



0







2-1

-------
Component

EIS Sector or EIS Sector: Source Category Name

Point

Nonpoint

Onroad

Nonroad

Event

Bulk Gasoline Terminals

0

0







Commercial Cooking



0







Dust - Construction Dust

0

0







Dust - Paved Road Dust



0







Dust - Unpaved Road Dust



0







Fires - Agricultural Field Burning



0







Fires - Prescribed Burning









0

Fires - Wildfires









0

Fuel Comb - Comm/lnstitutional - Biomass

0

0







Fuel Comb - Comm/lnstitutional - Coal

0

0







Fuel Comb - Comm/lnstitutional - Natural Gas

0

0







Fuel Comb - Comm/lnstitutional - Oil

0

0







Fuel Comb - Comm/lnstitutional - Other

0

0







Fuel Comb - Electric Generation - Biomass

0









Fuel Comb - Electric Generation - Coal

0









Fuel Comb - Electric Generation - Natural Gas

0









Fuel Comb - Electric Generation - Oil

0









Fuel Comb - Electric Generation - Other

0









Fuel Comb - Industrial Boilers, ICEs - Biomass

0

0







Fuel Comb - Industrial Boilers, ICEs - Coal

0

0







Fuel Comb - Industrial Boilers, ICEs - Natural Gas

0

0







Fuel Comb - Industrial Boilers, ICEs - Oil

0

0







Fuel Comb - Industrial Boilers, ICEs - Other

0

0







Fuel Comb - Residential - Natural Gas



0







Fuel Comb - Residential - Oil



0







Fuel Comb - Residential - Other



0







Fuel Comb - Residential - Wood



0







Gas Stations

0

0

0





Industrial Processes - Cement Manufacturing

0









Industrial Processes - Chemical Manufacturing

0

0







Industrial Processes - Ferrous Metals

0









Industrial Processes - Mining

0

0







Industrial Processes - NEC

0

0







Industrial Processes - Non-ferrous Metals

0

0







Industrial Processes - Oil & Gas Production

0

0







Industrial Processes - Petroleum Refineries

0

0







Industrial Processes - Pulp & Paper

0









Industrial Processes - Storage and Transfer

0

0







Miscellaneous Non-Industrial NEC: Residential Charcoal Grilling



0







2-2

-------
Component

EIS Sector or EIS Sector: Source Category Name

Point

Nonpoint

Onroad

Nonroad

Event

Miscellaneous Non-Industrial NEC: Portable Gas Cans



0







Miscellaneous Non-Industrial NEC: Nonpoint Hg



0







Miscellaneous Non-Industrial NEC (All other)

0

0







Mobile - Aircraft

0









Mobile - Commercial Marine Vessels



0







Mobile - Locomotives

0

0







Mobile - NonRoad Equipment - Diesel

0





0



Mobile - NonRoad Equipment - Gasoline

0





0



Mobile - NonRoad Equipment - Other

0





0



Mobile - Onroad - Diesel Heavy Duty Vehicles





0





Mobile - Onroad - Diesel Light Duty Vehicles





0





Mobile - Onroad - Gasoline Heavy Duty Vehicles





0





Mobile - Onroad - Gasoline Light Duty Vehicles





0





Solvent - Consumer & Commercial Solvent Use: Agricultural Pesticides



0







Solvent - Consumer & Commercial Solvent Use: Asphalt Paving



0







Solvent - Consumer & Commercial Solvent Use: All Other Solvents



0







Solvent - Degreasing

0

0







Solvent - Dry Cleaning

0

0







Solvent - Graphic Arts

0

0







Solvent - Industrial Surface Coating & Solvent Use

0

0







Solvent - Non-Industrial Surface Coating



0







Waste Disposal: Open Burning



0







Waste Disposal: Nonpoint POTWs



0







Waste Disposal: Human Cremation



0







Waste Disposal: Nonpoint Hg



0







Waste Disposal (all remaining sources)

0

0







2.2 How is the NEI constructed?

Data in the NEI come from a variety of sources. The emissions are predominantly from S/L/T agencies for both
CAP and HAP emissions. In addition, the EPA quality assures and augments the data provided by states to assist
with data completeness, particularly with the HAP emissions since the S/L/T HAP reporting is voluntary.

The NEI is built by data category for point, nonpoint, nonroad mobile, onroad mobile and events. Each data
category contains emissions from various reporters in multiple datasets which are blended to create the final
NEI "selection" for that data category. Each data category selection includes S/L/T data and numerous other
datasets that are discussed in more detail in each of the following sections in this document. In general, S/L/T
data take precedence in the selection hierarchy, which means that it supersedes any other data that may exist
for a specific county/tribe/facility/process/pollutant. In other words, the selection hierarchy is built such that
the preferred source of data, usually S/L/T, is chosen when multiple sources of data are available. There are

2-3

-------
exceptions, to this general rule, which arise based on quality assurance checks and feedback from S/L/Ts that we
will discuss in later sections.

The EPA uses augmentation and additional EPA datasets to create the most complete inventory for
stakeholders, for use in such applications as NATA, air quality modeling, national rule assessments, international
reporting, and other reports and public inquiries. Augmentation to S/L/T data, in addition to EPA datasets, fill in
gaps for sources and/or pollutants often not reported by S/L/T agencies. The basic types of augmentation are
discussed in the following sections.

2.2.1 Toxics Release Inventory data

The EPA used air emissions data from the 2017 Toxics Release Inventory (TRI) to supplement point source HAP
and NH3 emissions provided to EPA by S/L/T agencies. For 2017, all TRI emissions values that could reasonably
be matched to an EIS facility with some certainty and with limited risk of double-counting nonpoint emissions
were loaded into the EIS for viewing and comparison if desired, but only those pollutants that were not reported
anywhere at the EIS facility by the S/L/T agency were included in the 2017 NEI.

The TRI is an EPA database containing data on disposal or other releases including air emissions of over 650 toxic
chemicals from approximately 21,000 facilities. One of TRI's primary purposes is to inform communities about
toxic chemical releases to the environment. Data are submitted annually by U.S. facilities that meet TRI
reporting criteria. Section 3 provides more information on how TRI data was used to supplement the point
inventory.

2.2.2 Chromium speciation

The 2017 reporting cycle included 5 valid pollutant codes for chromium, as shown in Table 2-2.

Table 2-2: Valid chromium pollutant codes

Pollutant Code

Description

Pollutant Category Name

Speciated?

1333820

Chromium Trioxide

Chromium Compounds

yes

16065831

Chromium III

Chromium Compounds

yes

18540299

Chromium (VI)

Chromium Compounds

yes

7440473

Chromium

Chromium Compounds

7738945

Chromic Acid (VI)

Chromium Compounds

yes

In the above table, all pollutants but "chromium" are considered speciated, and so for clarity, chromium
(pollutant 7440473) is referred to as "total chromium" in the remainder of this section. Total chromium could
contain a mixture of chromium with different valence states. Since one key inventory use is for risk assessment,
and since the valence states of chromium have very different risks, speciated chromium pollutants are the most
useful pollutants for the NEI. Therefore, the EPA speciates S/L/T-reported and TRI-based total chromium into
hexavalent chromium and non-hexavalent chromium. Hexavalent chromium, or Chromium (VI), is considered
high risk and other valence states are not. Most of the non-hexavalent chromium is trivalent chromium
(Chromium III); therefore, the EPA characterized all non-hexavalent chromium as trivalent chromium. The 2017
NEI does not contain any total chromium, only the speciated pollutants shown in Table 2-2.

This section describes the procedure we used for speciating chromium emissions from total chromium that was
reported by S/L/T agencies.

We used the EIS augmentation feature to speciate S/L/T agency reported total chromium. For point sources, the
EIS uses the following priority order for applying the factors:

2-4

-------
1) By Process ID

2) By Facility ID

3) By County

4) By State

5) By Emissions Type (for NP only)

6) By SCC

7) By Regulatory Code

8) By NAICS

9) A Default value if none of the others apply

If a particular emission source of total chromium is not covered by the speciation factors specified by any of the
first 8 attributes, a default value of 34 percent hexavalent chromium, 66 percent trivalent chromium is applied.

For the 2017 chromium augmentation, only the "By Facility ID" (2), "By SCC" (6), and "By Default" (9) were used
on S/L/T-reported total chromium values. ForTRI dataset chromium, the "By NAICS" (8) option was primarily
used, although a small number of "By Facility" (2) occurences were used rather than NAICS. The EIS generates
and stores an EPA dataset containing the resultant hexavalent and trivalent chromium species. For all other data
categories (e.g., nonpoint, onroad and nonroad), chromium speciation is performed at the SCC level.

This procedure generated hexavalent chromium (Chromium (VI)) and trivalent chromium (Chromium III), and it
had no impact on S/L/T agency data that were provided as one of the speciated forms of chromium. The sum of
the EPA-computed species (hexavalent and trivalent chromium) equals the mass of the total chromium (i.e.,
pollutant 7440473) submitted by the S/L/T agencies.

The EPA then used this dataset in the 2017 NEI selection by adding it to the data category-specific selection
hierarchy and by excluding the S/L/T agency unspeciated chromium from the selection through a pollutant
exception to the hierarchy.

Most of the speciation factors used in the 2017 NEI are SCC-based and are the same as were used in 2011 and
2014, based on data that have long been used by the EPA for NATA and other risk projects. However, some
values are updated with every inventory cycle. New data may be developed by OAQPS during rule development
or review of NATA data. The speciation factors are accessed in the EIS through the reference data link
"Augmentation Profile Information." A chromium speciation "profile" is a set of output multiplication factors for
a type of emissions source. The profile data for chromium are stored in the same tables as the HAP
augmentation factors described in Section 2.2.3. The speciation factors are a specific case of HAP augmentation
whereby the "output pollutants" are always hexavalent chromium and trivalent chromium, and the "input
pollutant" is always chromium. There are 3 main tables and a summary table. The summary table excludes the
metadata and comments regarding the derivation of the factors and assignment to SCCs; to learn more of the
derivation of the factor or assignment of "profile" to a source, the main tables (not summary table) should be
consulted.

The three main tables are:

• Augmentation Profile Names and Input Pollutants - general information about the profile and source of
the profile names and factors.

• Augmentation Multiplication Factors - provides the output pollutants and multiplication factors
associated with a given Augmentation Profile and input pollutant.

• Augmentation Assignments - provides the assignment of the profile to the data source (the list of 9
items above).

2-5

-------
The summary table is the Augmentation Multiplication Factors and Assignments, a composite table that
provides a view of all the combinations of output pollutants and assignment information associated with a given
profile.

For non-EIS users, the data from the main tables were downloaded and provided as described in Section 3
(3.1.4-S/L/T chromium speciation, 3.1.6 -TRI chromium speciation and 3.1.6, HAP augmentation).

2.2.3 HAP augmentation

The EPA supplements missing HAPs in S/L/T agency-reported data. HAP emissions are calculated by multiplying
appropriate surrogate CAP emissions by an emissions ratio of HAP to CAP emission factors. For the 2017 NEI, we
augmented HAPs for the point and nonpoint data categories. Generally, for point sources, the CAP-to-HAP ratios
were computed using uncontrolled emission factors from the WebFIRE database (which contains primarily
AP-42 emissions factors). For nonpoint sources, the ratios were computed from the EPA-generated nonpoint
data, which contain both CAPs and HAPs where applicable.

HAP augmentation is performed on each emissions source (i.e., specific facility and process for point sources,
county and process level for nonpoint sources) using the same EIS augmentation feature as described in
chromium speciation. However, unlike chromium speciation, there is no default augmentation factor so that not
every process that has S/L/T CAP data will end up with augmented HAP data.

HAP augmentation input pollutants are S/L/T-submitted VOC, PM10-PRI, PM25-PRI, S02, and PM10-FIL. The
resulting output can be a single output pollutant or a full suite of output pollutants. Not every source that has a
CAP undergoes HAP augmentation (i.e., livestock NH3 and fugitive dust PM25-PRI). The sum of the HAP
augmentation factors does not need to equal 1 (100%); however, we try to ensure, for example, that the sum of
HAP-VOC factors is less than 1 for mass balance. HAP augmentation factors are grouped into profiles that
contain unique output pollutant factors related to a type of source. Assigning these profiles to the individual
sources depends on the source attributes, commonly the SCC.

There are business rules specific to each data category discussed in the point (Section 3) section of the TSD. The
ultimate goal is to prevent double-counting of HAP emissions between S/L/T data and the EPA HAP
augmentation output, and to prevent, where possible, adding HAP emissions to S/L/T-submitted processes that
are not desired. NEI developers use their judgment on how to apply HAP augmentation to the resulting NEI
selection.

Caveats

HAP augmentation does have limitations; HAP and CAP emission factors from WebFIRE do not necessarily use
the same test methods. In some situations, the VOC emission factor is less than the sum of the VOC HAP
emission factors. In those situations, we normalize the HAP ratios so as not to create more VOC HAPs than VOC.
We are also aware that there are many similar SCCs that do not always share the same set of emission
factors/output pollutants. We do not apply ratios based on emission factors from similar SCCs other than for
mercury from combustion SCCs. We would prefer to get HAPs reported from reporting agencies or get the data
from other sources (compliance data from rule), but such data are not always available.

Because much of the AP-42 factors are 20+ years old, many incremental edits to these factors have been made
over time. We have removed some factors based on results of NATA reviews. For example, we discovered
ethylene dichloride was being augmented for SCCs related to gasoline distribution. This pollutant was associated
with leaded gasoline which is no longer used. Therefore, we removed it from our HAP augmentation between
2011 NEI v2 and 2014. We also received specific facility and process augmentation factors resulting from the

2-6

-------
NATA reviews. More discussion of the underlying data used for the 2017 NEI August2019 point version is
discussed in Section 3.1.6.

For point sources, HAPs augmentation data are not used when S/L/T air agency data exists at any process at the
facility for the same pollutant. That means that if a S/L/T reports a particular HAP at some processes but misses
others, then those other processes will not be augmented with that HAP.

2.2.4 PM augmentation

Particulate matter (PM) emissions species in the NEI are: primary PM10 (called PM10-PRI in the EIS and NEI) and
primary PM2.5 (PM25-PRI), filterable PM10 and filterable PM2.5 (PM10-FIL and PM25-FIL) and condensable PM
(PM-CON). The EPA needed to augment the S/L/T agency PM components for the point and nonpoint
inventories to ensure completeness of the PM components in the final NEI and to ensure that S/L/T agency data
did not contain inconsistencies. An example of an inconsistency is if the S/L/T agency submitted a primary PM2.5
value that was greater than a primary PM10 value for the same process. Commonly, the augmentation added
condensable PM or PM filterable (PM10-FIL and/or PM25-FIL) where none was provided, or primary PM2.5
where only primary PM2.5 was provided.

In general, emissions for PM species missing from S/L/T agency inventories were calculated by applying factors
to the PM emissions data supplied by the S/L/T agencies. These conversion factors were first used in the 1999
NEI's "PM Calculator" as described in an NEI conference paper [ref 1], The resulting methodology allows the EPA
to derive missing PM10-FIL or PM25-FIL emissions from incomplete S/L/T agency submissions based on the SCC
and PM controls that describe the emissions process. In cases where condensable emissions are not reported,
conversion factors are applied to S/L/T agency reported PM species or species derived from the PM Calculator
databases. The PM Calculator has undergone several edits since 1999; now called the "PM Augmentation Tool,"
this Microsoft ® Access ® database is no longer made available because it should not be run for any purpose
other than gap-filling the final NEI selection.

The PM Augmentation Tool is used only for point and nonpoint sources, and the output from the tool is heavily-
screened prior to use in the NEI. This screening is done to prevent trivial overwriting of S/L/T data from PM
Augmentation Tool calculations, particularly for primary PM submittals by S/L/Ts. More details on the caveats to
using the PM Augmentation Tool are discussed in Section 3 on point sources and Section 4 on nonpoint sources.

2.2.5 Other EPA datasets

In addition to TRI, chromium speciation, HAP and PM augmentation, the EPA generates other data to produce a
complete inventory. Examples of EPA data for point sources, discussed in Section 3, include EPA landfills, electric
generating units (EGUs), and aircraft.

2.2.6 Data Tagging

S/L/T agency data generally is used first when creating the NEI selection. When S/L/T data are used, then the NEI
would not use other data (primarily EPA data from stand-alone datasets or HAP, PM or TRI augmentation) that
also may exist for the same process/pollutant. Thus, in most cases the S/L/T agency data are used; however, for
several reasons, sometimes we need to exclude, or "tag out" S/L/T agency data. Examples of these "S/L/T tags"
are when S/L/T agency staff alert the EPA to exclude their data (because of a mistake or outdated value), or
when EPA staff find problems with submitted data. Another example is when S/L/T emissions data are
significantly less than TRI and are presumed to be incomplete, which can happen for S/L/T that use automated
gap-filling procedures for facilties that do not voluantarily provide HAP emissions. These automated procedures

2-7

-------
gap-fill only for processes that have emission factors and miss proceeses/pollutants for may have been reported
to TRI using other means besides published emisson factors.

In previous NEI years data tagging had also been used to avoid double-counting emissions by using emissions
from more than one dataset because the two datasets were at different levels of granularity and thus not able
to be integrated to the full process level of detail required by the standard selection hierarchy software. The
primary eample of this is the TRI dataset, which provides facility-total emissions rather than individual process-
level emissions. Because the TRI emissions must be stored to a single emission process that is not the same as
that used by the S/L/T agency, the standard hierarchy selction software would use both. Thus, tagging was used
to "block" any TRI values where the S/L/T had reported the same pollutant at any process(es) within the same
facility. For the 2017 NEI, a series of additional rules were added to the selection hierarchy to avoid such
tagging. Point source datasets are now identified as being either Process-level, Unit-level, or Facility-level
granularity, and the selection software now uses those identifications to avoid double-counting, avoiding the
need for those types of tags.

2.2.7 Inventory Selection

Once all S/L/T and EPA data are quality assured in the EIS, and all augmentation and data tagging are complete,
then we use the EIS to create a data category-specific inventory selection. To do this, each EIS dataset is
assigned a priority ranking prior to running the selection with EIS. The EIS then performs the selection at the
most detailed inventory resolution level for each data category. For point sources, this is the process and
pollutant level. For nonpoint sources, it is the process (SCC)/shape ID (i.e., ports) and pollutant level. For onroad
and nonroad sources, it is process/pollutant, and for events it is day/location/process and pollutant. At these
resolutions, the inventory selection process uses data based on highest priority and excludes data where it has
been tagged. The EPA then quality assures this final blended inventory to ensure expected processes/pollutants
are included or excluded. The EIS uses the inventory selection to also create the SMOKE Flat Files, EIS reports
and data that appear on the NEI website.

2,3 References for 2017 inventory contents overview

1. Strait, R.; MacKenzie, D.; and Huntley, R., 2003. PM Augmentation Procedures for the 1999 Point and
Area Source NEI. 12th International Emission Inventory Conference - "Emission Inventories - Applying
New Technologies", San Diego, April 29 - May 1, 2003.

2-8

-------
3 Point sources

This section provides a description of sources that are in the point data category. Point sources are included in
the inventory as individual facilities, usually at specific latitude/longitude coordinates, rather than as county or
tribal aggregates. These facilities include large energy and industrial sites, such as electric generating utilities
(EGUs), mines and quarries, cement plants, refineries, large gas compressor stations, and facilities that
manufacture pulp and paper, automobiles, machinery, chemicals, fertilizers, pharmaceuticals, glass, food
products, and other products. Additionally, smaller points sources are included voluntarily by S/L/T agencies,
and can include small facilities such as crematoria, dry cleaners, and even gas stations. These smaller sources
may appear in one state but not another due to the voluntary nature of providing smaller sources. There are
also some portable sources in the point source data category, such as hot mix asphalt facilities, which relocate
frequently as a road construction project progress. The point source data category also includes emissions from
the landing and take-off portions of aircraft operations, the ground support equipment at airports, and
locomotive emissions within railyards. Within a point source facility, emissions are estimated and reported for
individual emission units and processes. Those emissions are associated with any number of stack and fugitive
release points that each have parameters needed for atmospheric modeling exercises.

The approach used to build the 2017 National Emissions Inventory (NEI) for all point sources is discussed in
Section 3.1 through Section 3.8. Some changes to aircraft for the 2017 NEI are also discussed in Section 3.2, and
revisions to rail yard estimates for 2017 are included in Section 3.3.

3.1 Point source approach: 2017

The general approach to building the NEI point source inventory is to use state/local/tribal (S/L/T)-submitted
emissions, locations, and release point parameters wherever possible. Missing emissions values are gap-filled
with EPA data where available. Quality assurance reviews of the emission values, locations, and release point
modeling parameters are done by the EPA on the most significant emission sources and where data does not
pass quality assurance checks.

3.1.1 QA review of S/L/T data

State/local/tribal agency submittals for the 2017 NEI point sources were accepted through January 15, 2019. We
then compared facility-level pollutant sums appearing in either the 2017 NEI S/L/T-submitted values or the
2014v2 NEI. The comparison included all facilities and pollutants, including any missing from the 2017 submittals
(i.e., present in 2014 but not 2017) as well as any that were new in the 2017 submittals and all that were
common to both years. The comparison table also showed the 2017 emission values from the 2017 Toxics
Release Inventory (TRI). We added columns that showed the percent differences between the 2017 S/L/T
agency-submitted facility totals and the 2014 NEIv2 and 2017 TRI datasets. To create a more focused review and
comparison table, we limited these results to include only cases where the 2017 S/L/T agency-submitted facility
total was more than 50 percent different from the 2014 facility total and with an absolute mass value of the
difference greater than a pollutant-specific threshold amount2. When a facility-pollutant combination was new
in 2017 or appeared only in the 2014 NEI v2, we included those values only when they exceeded the absolute

2 These thresholds are available on the 2014vl Supplemental Data FTP site as file
"2014_point_pollutant_thresholds_qa_flagl.xlsx"

3-1

-------
mass values greater than the pollutant-specific thresholds because the percent differences were undefined. We
provided3 the resulting table of 3,860 records to S/L/T agencies for review.

State/local/tribal edits to address any emissions values were accepted in the Emissions Inventory System (EIS)
until July 1, 2019. The S/L/T agencies did not change most of the highlighted values. Where the comparisons
were exceptionally suspect, the EPA contacted the agencies by phone or by email if no edits had been made to
obtain confirmation of the reported values. For a small number of cases, neither confirmation nor edits were
obtained, and the value was tagged to be excluded from selection for the NEI. In some but not all of these
instances, a value from TRI or the CAMD data sets was available as a replacement.

Similar to previous NEI years, we quality assured the latitude-longitude coordinates at both the site level and the
release point level. In previous NEI cycles, we had reviewed, verified, and locked (in EIS) approximately 2,500
site-level coordinates of the most significant emitting facilities. For the 2014 NEI coordinate review, we
compared all other site coordinate pairs to the county boundaries for the FIPS county codes reported for those
facilities. We then identified all facilities that met the following criteria: (1) more than 50 tons total criteria
pollutant emissions or more than 20 pounds total hazardous air pollutants (HAPs) for 2014, (2) the coordinates
caused the location of the facility to be more than a half mile outside of its indicated county. For these facilities,
we reviewed the location using Google Earth, edited the location as needed in EIS, and locked the location in EIS.

In addition, we compared the release point coordinates of all release points with any 2017 emissions to their
site level coordinates, whether protected or not. In cases that we found a difference of more than 0.005 degrees
(approximately 0.25 miles) in total latitude plus longitude, we reviewed the release point coordinates in Google
Earth and edited as needed in EIS, and the site-level coordinates were then locked in EIS. This check was able to
find two cases: (1) where the independently-reported release point coordinates may indicate either a suspect
site-level coordinate, even if plotting within the correct county, or (2) an inaccurate release point coordinate.
We also made a third quality assurance check to ensure that the coordinates for any release point that had
emissions greater than 10 pounds for any key high-risk HAP that was within 0.005 degrees of a verified site
coordinate. This check resulted in additional site coordinate reviews and protections. Finally, the site
coordinates as found in the EPA's Facility Registry System were compared to those in EIS. Any facilities where
these coordinates differed by more than 0.01 degrees and with greater than 50 tons criteria emissions or 500
pounds HAP emissions were reviewed, edited, and protected as needed.

3.1.2 Sources of EPA data and selection hierarchy

Table 3-1 lists the datasets that we used to compile the 2017 NEI point inventory and the hierarchy used to
choose which data value to use for the NEI when multiple data sets are available for the same emissions source
(see Section 2.2 for more detail on the EIS selection process).

The EPA developed all datasets other than those containing S/L/T agency data and the dataset containing
emissions from offshore oil and gas platforms in federal waters in the Gulf of Mexico. The primary purpose of
the EPA datasets is to add or "gap fill" pollutants or sources not provided by S/L/T agencies, to resolve
inconsistencies in S/L/T agency-reported pollutant submissions for particulate matter (PM) (Section 3.1.3) and to
speciate S/L/T agency reported total chromium into hexavalent and trivalent forms (Section 3.1.4).

The hierarchy or "order" provided in the tables below defines which data are to be used for situations where
multiple datasets provide emissions for the same pollutant and emissions process. The dataset with the lowest
order number on the list is preferentially used over other datasets. The table includes the rationale for why each

3 We emailed the Emission Inventory System data submitters the table and instructions on March 13, 2019.

3-2

-------
dataset was assigned its position in the hierarchy. In addition to the order of the datasets, the selection also
considers whether individual data values have been tagged (see Section 2.2.6). Any data that were tagged by the
EPA in any of the datasets were not used. State/local/tribal agency data were tagged only if they were deemed
to be likely outliers and were not addressed during the S/L/T agency data reviews. As in earlier NEI years, the
2017vl point source selection also excluded dioxins, furans and radionuclides. The EPA has not evaluated the
completeness or accuracy of the S/L/T agency dioxin and furan values nor radionuclides and does not have plans
to supplement these reported emissions with other data sources to compile a complete and estimate for these
pollutants as part of the NEI. The 2017 NEI point source inventory does include greenhouse gas emissions.

Facility total values for four GHGs (C02, CH4, N20, and SF6) were copied from the U.S. Greenhouse Gas
Inventory Report website and matched to EIS facilities.

Table 3-1: Data sets and selection hierarchy used for 2017 NEI August release point source data category

Dataset name

Description and Rationale for the Order of the Selected Datasets

Order

2017EPA_GHG

Facility-level emissions for four specific GHGs from the USEPA's Greenhouse
Gas Reporting Program

2017EPA_EGUmats

Emission unit level emissions for 29 HAPs from the Mercury and Air Toxics
(MATS) RTR modeling file for electric generating utilities (EGUs)

Responsible Agency Data
Set

S/L/T agency submitted data. These data are selected ahead of lower
hierarchy datasets except where individual values in the S/L/T agency
emissions were suspected outliers that were not addressed during the draft
review and therefore tagged by the EPA.

2017EPA_Cr_Aug

Hexavalent and trivalent chromium speciated from S/L/T agency reported
chromium. EIS augmentation function creates the dataset by applying
multiplication factors by SCC, facility, process or North American Industry
Classification System (NAICS) code to S/L/T agency total chromium. See
Section 3.1.4.

2017EPA_PM-Aug

PM components added to gap fill missing S/L/T agency data or make
corrections where S/L/T agency have inconsistent emissions across PM
components. Uses ratios of emission factors from the PM Augmentation
Tool for covered source classification codes (SCCs). For SCCs without
emission factors in the tool, checks/corrects discrepancies or missing PM
species using basic relationships such as ensuring that primary PM is
greater than or equal to filterable PM (see Section 3.1.3).

2017EPA_EGU

CAP and HAP emission unit level emissions from either the annual sum of
CAMD hourly CEM data for S02 and NOx or from emission factors used in
previous NEI year inventories from AP-42 and other sources multiplied by
2017 CAMD heat input data.

2017EPA_TRI

TRI data for the year 2017 (see Section 3.1.5). These data are selected for a
facility only when the S/L/T agency data do not include emissions for a
given pollutant at any process for that facility.

2017EPA_TRIcr

TRI data reported as total chromium for the year 2017 speciated into the
chromium III and chromium VI valence amounts, usually by use of a NAICs-
based speciation profile, but possibly by use of a facility-specific profile.

3-3

-------
Dataset name

Description and Rationale for the Order of the Selected Datasets

Order

2017EPA_Airports

CAP and HAP emissions for aircraft operations including commercial,
general aviation, air taxis and military aircraft, auxiliary power units and
ground support equipment computed by the EPA for approximately 20,000
airports. Methods include the use of the Federal Aviation Administration's
(FAA's) Emissions and Dispersion Modeling System (EDMS) (see Section
3.2).

9

2017EPA_BOEM

2017 Gulfwide Emission Inventory CAP emissions from Offshore oil
platforms located in Federal Waters in the Gulf of Mexico developed by the
U.S. Department of the Interior, Bureau of Ocean and Energy Management
(BOEM), Regulation, and Enforcement in the National Inventory Input
Format and converted to the CERS format by the EPA. The state code for
data from the data set is "DM" (Federal Waters).

10

2017EPA_LF

Landfill emissions developed by EPA using methane data from the EPA's
GHG reporting rule program.

11

2017EPA_SPPD_PCWP

Subset of the Plywood and Composite Wood Products Manufacture (PCWP)
Risk and Technology Review (RTR) data used for gap filling HAPs at facilities
and updating facility configurations. Facilities were initially selected if either
formaldehyde or benzene were greater than 0.1 tpy. The PCWP rule
information can be found on the Plywood and Composite Wood Products
Manufacture NESHAP weboaee.

12

2017EPA_HAPAug

HAP data computed from S/L/T agency criteria pollutant data using
HAP/CAP EF ratios based on the EPA Factor Information Retrieval System
(WebFIRE) database as described in Section 3.1.6. These data are selected
below the TRI data because the TRI data are expected to be better.

13

2017EPA_HAPAug-
PMaug

This dataset was created in the same fashion as the 2017EPA_HAPAug
dataset above and is a supplement to it. This dataset contains HAPs
calculated by applying a ratio to PM10-FIL emissions, for those instances
where the S/L/T dataset did not contain any PM10-FIL emissions, but the
PM augmentation routine was able to calculate a PM10-FIL value from
some PM species that was reported by the S/L/T.

14

2017ERTAC_Rail

2017 estimates compiled by the Eastern Regional Technical Advisory
Committee (ERTAC) for most rail yards in the US. The ERTAC effort was
comprised of a collaborative of state/local agencies, rail companies, and the
Federal Rail Administration. Yard emissions are associated with the
operation of switcher engines at each yard.

15

2017EPA_gapfills

2014 emissions values for 212 facilities and 12 pollutants not reported in
2017 S/L/T datasets but appear to still be operating and were above CAP
reporting thresholds in 2014. This data set also includes 2017 mercury
emissions for 6 municipal waste combustor facilities that were provided
(outside of EIS) by Maryland and Massachusetts.

16

2017EPA_2016TRI

2016 TRI ethylene oxide emission estimates for 6 facilities that are still
operating but were not reported by S/L/T or are missing from the 2017 TRI.

17

3-4

-------
3.1.3 Particulate matter augmentation

Particulate matter emissions components4 in the NEI are: primary PM10 (called PM10-PRI in the EIS and NEI)
and primary PM2.5 (PM25-PRI), filterable PM10 (PM10-FIL) and filterable PM2.5 (PM25-FIL) and condensable
PM (PM-CON, which is all within the PM2.5 portion on PM, i.e., PM25-PRI = PM25-FIL + PM-CON). The EPA
needed to augment the S/L/T agency PM components to ensure completeness of the PM components in the
final NEI and to ensure that S/L/T agency data did not contain inconsistencies. An example of an inconsistency is
if the S/L/T agency submitted a primary PM2.5 value that was greater than a primary PM10 value for the same
process. Commonly, the augmentation added condensable PM or PM filterable (PM10-FIL and/or PM25-FIL)
where no value was provided, or primary PM2.5 where only primary PM10 was provided. Additional information
on the procedure is provided in the 2008 NEI PM augmentation documentation [ref 1],

In general, emissions for PM species missing from S/L/T agency inventories were calculated by applying factors
to the PM emissions data supplied by the S/L/T agencies. These conversion factors were first used in the 1999
NEI's "PM Calculator" as described in an NEI conference paper [ref 2], The resulting methodology allows the EPA
to derive missing PM10-FIL or PM25-FIL emissions from incomplete S/L/T agency submissions based on the SCC
and PM controls that describe the emissions process. In cases where condensable emissions are not reported,
conversion factors developed are applied to S/L/T agency reported PM species or species derived from the PM
Calculator databases.

3.1.4 Chromium speciation

An overview of chromium speciation, as it impacts both the point and nonpoint data category, is discussed in
Section 2.2.2.

The EIS generates and stores an EPA dataset containing the resultant hexavalent and trivalent chromium
species. The EPA then used this dataset in the 2017 NEI selection by adding it to the selection hierarchy shown in
Table 3-1, excluding the S/L/T agency total chromium from the selection through a pollutant exception to the
hierarchy. This EIS feature does not speciate chromium from any of the EPA datasets because the EPA data
contains only speciated chromium.

For the 2017 NEI, the EPA named this dataset "2017EPA_Cr_Aug." Most of the speciation factors used in the
2017 NEI are SCC-based and are the same as were used for the 2008, 2011 and 2014 NEIs. There are some
facility-specific factors resulting from reviews of previous year (e.g., 2014 and 2011) National Air Toxics
Assessment (NATA) data. Facility-specific factors were also provided for several facilities by the state of Indiana.
The factors "SLT_based_chromium_speciation.zip", based on data that have long been used by the EPA for
NATA and other risk projects, are available on the 2017 Supplemental data FTP site.

3.1.5 Use of the 2017 Toxics Release Inventory

The EPA used air emissions data from the 2017 TRI to supplement point source HAP and ammonia emissions
provided to the EPA by S/L/T agencies. The resulting augmentation dataset is labeled as "2017EPA_TRI" in the
Table 3-1 selection hierarchy shown above. For 2017, all TRI emissions values that could reasonably be matched
to an EIS facility were loaded into the EIS for viewing and comparison if desired, but only those pollutants that
were not reported anywhere at the EIS facility by the S/L/T agency were included in the 2017 NEI. The October

4 We use the term "components" here rather than "species" to avoid confusion with the PM2.5 "species" that are used for
air quality modeling (e.g., organic carbon, elemental carbon, sulfate, nitrate, and other PM).

3-5

-------
2018 version of these data were used, however, where emissions changes between this version and the April

2019 version of the 2017 TRI data exceeded 2%, the April 2019 version was used.

The basis of the 2017EPA_TRI dataset is the US EPA's 2017 Toxics Release Inventory (TRI) Program. The TRI is an
EPA database containing data on disposal or other releases including air emissions of over 650 toxic chemicals
from approximately 21,000 facilities. One of TRI's primary purposes is to inform communities about toxic
chemical releases to the environment. Data are submitted annually by U.S. facilities that meet TRI reporting
criteria.

The approach used for the 2017 NEI was like that used for the 2014 NEI. The TRI emissions were included in the
EIS (and the NEI) as facility-total stack and facility-total fugitive emissions processes, which matches the
aggregation detail of the TRI database. For the 2017 NEI PT, a change was made in how we avoid double-
counting of TRI and other data sources (primarily the S/L/T data). Rather than tagging each individual TRI facility-
based value for wherever the S/L/T had reported that pollutant at any process(es) within the same facility, we
enhanced the EIS selection software to not use values from a "Facility" level dataset if a more preferred dataset
(the S/L/T datsets) had the pollutant at that facility, (see section 2.2.6). In addition to using this new "facility-
based rule" in the selection software, we also implemented a new "pollutant family rule" into the selection
software, which prevents pollutants defined as belonging to the same overlapping family of pollutants from
being selected for use if a higher preference dataset has already provided a pollutant value for that family. This
procedure had also been accomplished using tagging in previous NEI years.

The following steps describe in more detail the development of the 2017EPA_TRI dataset.

1. Update the TRI_ID to EISJD facility-level crosswalk

For the 2017 NEI, the same crosswalk list of TRI IDs that was used for the 2014 NEI was used as a starting
point. A limited review of the 2017 TRI facilities was conducted to identify new facilities with significant
emissions that had not been previously matched to an EIS facility. A total of approximately 50 additional
TRI facilities were added to the crosswalk for 2017.

2. Map TRI pollutant codes to valid EIS pollutant codes and sum where necessary

Table 3-2 provides the pollutant mapping from TRI pollutants to EIS pollutants. Many of the 650 TRI
pollutants do not have any EIS counterpart, and so are not shown in Table 3-2. In addition, several EIS
pollutants may be reported to TRI as either of two TRI pollutants. For example, both Pb and Pb
compounds may be reported to TRI, and similarly for several other metal and metal compound TRI
pollutants. Table 3-2 shows where such pairs of TRI pollutants both correspond to the same EIS
pollutant. In such cases, we summed the two TRI pollutants together as part of the step of assigning the
TRI emissions to valid EIS pollutant codes. For the 2017 NEI, a total of 197 TRI pollutant codes were
mapped to 185 unique EIS pollutant codes. Similar to the 2011 and 2014 NEIs, we did not use TRI
emissions reported for TRI pollutants: "Certain Glycol Ethers," "Dioxin and Dioxin-like Compounds,"
Dichlorobenzene (mixed isomers)," and "Toluene di-isocyanate (mixed isomers)," because they do not
represent the same scope as the EIS pollutants: "Glycol ethers," "Dioxins/Furans as 2,3,7,8-TCDD TEQs,"
"1,4-Dichlorobenzene," and "2,4-Di-isocyanate," respectively. We maintained TRI stack and fugitive
emissions separately during the summation step and maintained that separation through the storage of
the TRI emissions in the EIS.

Table 3-2: Mapping of TRI pollutant codes to EIS pollutant codes

TRI CAS

TRI Pollutant Name

EIS Pollutant
Code

EIS Pollutant Name

79345

1,1,2,2-TETRACHLOROETHANE

79345

1,1,2,2-TETRACH LOROETH ANE

3-6

-------
TRI CAS

TRI Pollutant Name

EIS Pollutant
Code

EIS Pollutant Name

79005

1,1,2-TRICHLOROETHANE

79005

1,1,2-TRICHLOROETHANE

57147

1,1-DIMETHYL HYDRAZINE

57147

1,1-DIMETHYL HYDRAZINE

120821

1,2,4-TRICHLOROBENZENE

120821

1,2,4-TRICHLOROBENZENE

96128

l,2-DIBROMO-3-CHLOROPROPANE

96128

l,2-DIBROMO-3-CHLOROPROPANE

57147

1,1-DIMETHYL HYDRAZINE

57147

1,1-Dimethyl Hydrazine

106887

1,2-BUTYLENE OXIDE

106887

1,2-EPOXYBUTANE

75558

PROPYLENEIMINE

75558

1,2-PROPYLENIMINE

106990

1,3-BUTADIENE

106990

1,3-BUTADIENE

542756

1,3-DICHLOROPROPYLENE

542756

1,3-DICHLOROPROPENE

1120714

PROPANE SULTONE

1120714

1,3-PROPANESULTONE

106467

1,4-DICHLOROBENZENE

106467

1,4-DICHLOROBENZENE

25321226

DICHLOROBENZENE (MIXED ISOMERS)



NA- pollutant not used

95954

2,4,5-TRICHLOROPHENOL

95954

2,4,5-TRICHLOROPHENOL

88062

2,4,6-TRICHLOROPHENOL

88062

2,4,6-TRICHLOROPHENOL

94757

2,4-DICHLOROPHENOXY ACETIC ACID

94757

2,4-DICHLOROPHENOXY ACETIC ACID

51285

2,4-DINITROPHENOL

51285

2,4-DINITROPHENOL

121142

2,4-DINITROTOLUENE

121142

2,4-DINITROTOLUENE

53963

2-ACETYLAMINOFLUORENE

53963

2-ACETYLAMINOFLUORENE

79469

2-NITROPROPANE

79469

2-NITROPROPANE

91941

3,3'-DICHLOROBENZI DINE

91941

3,3'- DICHLOROBENZIDINE

119904

3,3'-DIMETHOXYBENZIDINE

119904

3,3'- DIMETHOXYBENZIDINE

119937

3,3'-DIMETHYLBENZIDINE

119937

3,3'-DIMETHYLBENZIDINE

101144

4,4'-METHYLENEBIS(2-CHLOROANILINE)

101144

4,4'-METHYLENEBIS(2-CHLORANILINE)

101779

4,4'-METHYLEN EDI ANILINE

101779

4,4'-METHYLENEDIANILINE

534521

4,6-DINITRO-O-CRESOL

534521

4,6-DINITRO-O-CRESOL

92671

4-AMINOBIPHENYL

92671

4-AMINOBIPHENYL

60117

4-DIMETHYLAMINOAZOBENZENE

60117

4-DIMETHYLAMINOAZOBENZENE

100027

4-NITROPHENOL

100027

4-NITROPHENOL

75070

ACETALDEHYDE

75070

ACETALDEHYDE

60355

ACETAMIDE

60355

ACETAMIDE

75058

ACETONITRILE

75058

ACETONITRILE

98862

ACETOPHENONE

98862

ACETOPHENONE

107028

ACROLEIN

107028

ACROLEIN

79061

ACRYLAMIDE

79061

ACRYLAMIDE

79107

ACRYLIC ACID

79107

ACRYLIC ACID

107131

ACRYLONITRILE

107131

ACRYLONITRILE

107051

ALLYL CHLORIDE

107051

ALLYL CHLORIDE

7664417

AMMONIA

NH3

AMMONIA

62533

ANILINE

62533

ANILINE

7440360

ANTIMONY

7440360

ANTIMONY

N010

ANTIMONY COMPOUNDS

7440360

ANTIMONY

7440382

ARSENIC

7440382

ARSENIC

N020

ARSENIC COMPOUNDS

7440382

ARSENIC

1332214

ASBESTOS (FRIABLE)

1332214

ASBESTOS

71432

BENZENE

71432

BENZENE

92875

BENZIDINE

92875

BENZIDINE

98077

BENZOIC TRICHLORIDE

98077

BENZOTRICHLORIDE

100447

BENZYL CHLORIDE

100447

BENZYL CHLORIDE

7440417

BERYLLIUM

7440417

BERYLLIUM

N050

BERYLLIUM COMPOUNDS

7440417

BERYLLIUM

92524

BIPHENYL

92524

BIPHENYL

117817

DI(2-ETHYLHEXYL) PHTHALATE

117817

BIS(2-ETHYLHEXYL)PHTHALATE

542881

BIS(CHLOROMETHYL) ETHER

542881

BIS(CHLOROMETHYL)ETHER

75252

BROMOFORM

75252

BROMOFORM

7440439

CADMIUM

7440439

CADMIUM

N078

CADMIUM COMPOUNDS

7440439

CADMIUM

156627

CALCIUM CYANAMIDE

156627

CALCIUM CYANAMIDE

133062

CAPTAN

133062

CAPTAN

63252

CARBARYL

63252

CARBARYL

75150

CARBON DISULFIDE

75150

CARBON DISULFIDE

56235

CARBON TETRACHLORIDE

56235

CARBON TETRACHLORIDE

463581

CARBONYL SULFIDE

463581

CARBONYL SULFIDE

3-7

-------
TRI CAS

TRI Pollutant Name

EIS Pollutant
Code

EIS Pollutant Name

120809

CATECHOL

120809

CATECHOL

57749

CHLORDANE

57749

CHLORDANE

7782505

CHLORINE

7782505

CHLORINE

79118

CHLOROACETIC ACID

79118

CHLOROACETIC ACID

108907

CHLOROBENZENE

108907

CHLOROBENZENE

510156

CHLOROBENZILATE

510156

Chlorobenzilate

67663

CHLOROFORM

67663

CHLOROFORM

107302

CHLOROMETHYL METHYL ETHER

107302

CHLOROMETHYL METHYL ETHER

126998

CHLOROPRENE

126998

CHLOROPRENE

7440473

CHROMIUM

7440473

CHROMIUM

N090

CHROMIUM COMPOUNDS (EXCEPT CHROMITE
ORE MINED IN THE TRANSVAAL REGION)

7440473

CHROMIUM

7440484

COBALT

7440484

COBALT

N096

COBALT COMPOUNDS

7440484

COBALT

1319773

CRESOL (MIXED ISOMERS)

1319773

CRESOL/CRESYLIC ACID (MIXED ISOMERS)

108394

M-CRESOL

108394

M-CRESOL

95487

O-CRESOL

95487

O-CRESOL

106445

P-CRESOL

106445

P-CRESOL

98828

CUMENE

98828

CUMENE

N106

CYANIDE COMPOUNDS

57125

CYANIDE

74908

HYDROGEN CYANIDE

57125

CYANIDE

132649

DIBENZOFURAN

132649

DIBENZOFURAN

84742

Dl BUTYL PHTHALATE

84742

DIBUTYL PHTHALATE

111444

BIS(2-CHLOROETHYL) ETHER

111444

DICHLOROETHYL ETHER

62737

DICHLORVOS

62737

DICHLORVOS

111422

DIETHANOLAMINE

111422

DIETHANOLAMINE

64675

DIETHYL SULFATE

64675

DIETHYL SULFATE

131113

DIMETHYL PHTHALATE

131113

DIMETHYL PHTHALATE

77781

DIMETHYL SULFATE

77781

DIMETHYL SULFATE

79447

DIMETHYLCARBAMYL CHLORIDE

79447

DIMETHYLCARBAMOYL CHLORIDE

N120

DIISOCYANATES



NA- pollutant not used

26471625

TOLUENE DIISOCYANATE (MIXED ISOMERS)



NA- pollutant not used

584849

TOLUENE-2,4-DIISOCYANATE

584849

2,4-TOLUENE DIISOCYANATE

N150

DIOXIN AND DIOXIN-LIKE COMPOUNDS



NA- pollutant not used

106898

EPICHLOROHYDRIN

106898

EPICHLOROHYDRIN

140885

ETHYL ACRYLATE

140885

ETHYL ACRYLATE

51796

URETHANE

51796

ETHYL CARBAMATE

75003

CHLOROETHANE

75003

ETHYL CHLORIDE

100414

ETHYLBENZENE

100414

ETHYL BENZENE

106934

1,2-DIBROMOETHANE

106934

ETHYLENE DIBROMIDE

107062

1,2-DICHLOROETHANE

107062

ETHYLENE DICHLORIDE

107211

ETHYLENE GLYCOL

107211

ETHYLENE GLYCOL

151564

ETHYLENEIMINE

151564

ETHYLENEIMINE

75218

ETHYLENE OXIDE

75218

ETHYLENE OXIDE

96457

ETHYLENE THIOUREA

96457

ETHYLENE THIOUREA

75343

ETHYLIDENE DICHLORIDE

75343

ETHYLIDENE DICHLORIDE

50000

FORMALDEHYDE

50000

FORMALDEHYDE

N230

CERTAIN GLYCOL ETHERS

171

N/A Pollutant not used

76448

HEPTACHLOR

76448

HEPTACHLOR

118741

HEXACHLOROBENZENE

118741

HEXACHLOROBENZENE

87683

HEXACHLORO-l,3-BUTADIENE

87683

HEXACHLOROBUTADIENE

77474

HEXACHLOROCYCLOPENTADIENE

77474

HEXACHLOROCYCLOPENTADIENE

67721

HEXACHLOROETHANE

67721

HEXACHLOROETHANE

110543

N-HEXANE

110543

HEXANE

302012

HYDRAZINE

302012

HYDRAZINE

7647010

HYDROCHLORIC ACID (1995 AND AFTER "ACID
AEROSOLS" ONLY)

7647010

HYDROCHLORIC ACID

7664393

HYDROGEN FLUORIDE

7664393

HYDROGEN FLUORIDE

123319

HYDROQUINONE

123319

HYDROQUINONE

7439921

LEAD

7439921

LEAD

N420

LEAD COMPOUNDS

7439921

LEAD

58899

LINDANE

58899

1,2,3,4,5,6-HEXACHLOROCYCLOHEXANE

3-8

-------
TRI CAS

TRI Pollutant Name

EIS Pollutant
Code

EIS Pollutant Name

108316

MALEIC ANHYDRIDE

108316

MALEIC ANHYDRIDE

7439965

MANGANESE

7439965

MANGANESE

N450

MANGANESE COMPOUNDS

7439965

MANGANESE

7439976

MERCURY

7439976

MERCURY

N458

MERCURY COMPOUNDS

7439976

MERCURY

67561

METHANOL

67561

METHANOL

72435

METHOXYCHLOR

72435

METHOXYCHLOR

74839

BROMOMETHANE

74839

METHYL BROMIDE

74873

CHLOROMETHANE

74873

METHYL CHLORIDE

71556

1,1,1-TRICHLOROETHANE

71556

METHYL CHLOROFORM

74884

METHYL IODIDE

74884

METHYL IODIDE

108101

METHYL ISOBUTYL KETONE

108101

METHYL ISOBUTYL KETONE

624839

METHYL ISOCYANATE

624839

METHYL ISOCYANATE

80626

METHYL METHACRYLATE

80626

METHYL METHACRYLATE

1634044

METHYL TERT-BUTYL ETHER

1634044

METHYLTERT-BUTYL ETHER

75092

DICHLOROMETHANE

75092

METHYLENE CHLORIDE

60344

METHYL HYDRAZINE

60344

METHYLHYDRAZINE

121697

N,N-DIMETHYLANILINE

121697

N,N-DIMETHYLANILINE

68122

N,N-DIMETHYLFORM AMIDE

68122

N,N-DIMETHYLFORMAMIDE

91203

NAPHTHALENE

91203

NAPHTHALENE

7440020

NICKEL

7440020

NICKEL

N495

NICKEL COMPOUNDS

7440020

NICKEL

98953

NITROBENZENE

98953

NITROBENZENE

684935

N-NITROSO-N-METHYLUREA

684935

N-NITROSO-N-METHYLUREA

90040

O-ANISIDINE

90040

O-ANISIDINE

95534

O-TOLUIDINE

95534

O-TOLUIDINE

123911

1,4-DIOXANE

123911

P-DIOXANE

56382

PARATHION

56382

PARATHION

82688

QUINTOZENE

82688

PENTACHLORONITROBENZENE

87865

PENTACHLOROPHENOL

87865

PENTACHLOROPHENOL

108952

PHENOL

108952

PHENOL

75445

PHOSGENE

75445

PHOSGENE

7803512

PHOSPHINE

7803512

PHOSPHINE

7723140

PHOSPHORUS (YELLOW OR WHITE)

7723140

PHOSPHORUS

85449

PHTHALIC ANHYDRIDE

85449

PHTHALIC ANHYDRIDE

1336363

POLYCHLORINATED BIPHENYLS

1336363

POLYCHLORINATED BIPHENYLS

120127

ANTHRACENE

120127

ANTHRACENE

191242

BENZO(G,H,l)PERYLENE

191242

BENZO[G,H,l,]PERYLENE

85018

PHENANTHRENE

85018

PHENANTHRENE

N590

POLYCYCLIC AROMATIC COMPOUNDS

130498292

PAH, TOTAL

106503

P-PHENYLENEDIAMINE

106503

P-PHENYLENEDIAMINE

123386

PROPIONALDEHYDE

123386

PROPIONALDEHYDE

114261

PROPOXUR

114261

PROPOXUR

78875

1,2-DICHLOROPROPANE

78875

PROPYLENE DICHLORIDE

75569

PROPYLENE OXIDE

75569

PROPYLENE OXIDE

91225

QUINOLINE

91225

QUINOLINE

106514

QUINONE

106514

QUINONE

7782492

SELENIUM

7782492

SELENIUM

N725

SELENIUM COMPOUNDS

7782492

SELENIUM

100425

STYRENE

100425

STYRENE

96093

STYRENE OXIDE

96093

STYRENE OXIDE

127184

TETRACHLOROETHYLENE

127184

TETRACHLOROETHYLENE

7550450

TITANIUM TETRACHLORIDE

7550450

TITANIUM TETRACHLORIDE

108883

TOLUENE

108883

TOLUENE

95807

2,4-DIAMINOTOLUENE

95807

TOLUENE-2,4-DI AMINE

8001352

TOXAPHENE

8001352

TOXAPHENE

79016

TRICHLOROETHYLENE

79016

TRICHLOROETHYLENE

121448

TRIETHYLAMINE

121448

TRIETHYLAMINE

1582098

TRIFLURALIN

1582098

TRIFLURALIN

108054

VINYL ACETATE

108054

VINYL ACETATE

75014

VINYL CHLORIDE

75014

VINYL CHLORIDE

75354

VINYLIDENE CHLORIDE

75354

VINYLIDENE CHLORIDE

3-9

-------
TRI CAS

TRI Pollutant Name

EIS Pollutant
Code

EIS Pollutant Name

108383

M-XYLENE

108383

M-XYLENE

95476

O-XYLENE

95476

O-XYLENE

106423

P-XYLENE

106423

P-XYLENE

1330207

XYLENE (MIXED ISOMERS)

1330207

XYLENES (MIXED ISOMERS)

An electronic database of the TRI/NEI Pollutant Crosswalk showing NEI and TRI pollutant mappings can
be downloaded from the "State/Local/Tribal (S/L/T), National Emission Inventory (NEI), Toxic Release
Inventory (TRI) Mapping" portion of the Product Design Team website. It should be noted that while
HCN is in the NEI and the electronic mapping shows NEI HCN to TRI HCN, we brought in both TRI HCN
and TRI CN emissions as NEI CN. We did this to avoid double counting of S/L/T CN with TRI HCN since
some S/L/T include HCN emissions as CN.

Split TRI total chromium emissions into hexavalent and trivalent emissions

The TRI allows facilities to report either "Chromium" or "Chromium compounds/' but not the hexavalent
or trivalent chromium species that are needed for the NEI (see Section 3.1.3). Because the only
characterization available for the TRI facilities or their emissions is the facilities' NAICS codes, we created
a NAICS-based set of fractions to split the TRI-reported total chromium emissions into the hexavalent
and trivalent chromium species. A table of Standard Industrial Classification (SlC)-based chromium split
fractions was available from earlier year NEI usage of TRI databases, which had been compiled by SIC
rather than NAICS. The earlier SIC-based fractions were used wherever they could be re-assigned to a
closely matching NAICS description.

Unfortunately, not all SIC-based fractions could be assigned this way, so we computed NAICS-based split
fractions for any NAICS codes in the 2017 TRI data that did not already have an SIC-to-NAICS assigned
split fraction. These factors were used for the remaining TRI-reported chromium. To calculate the NAICS-
based factors, we summed by NAICS the total amounts of chromium III and chromium VI for the entire
U.S. in the 2014 draft NEI data. These 2017 NEI S/L/T emissions were either reported directly by the
S/L/T agencies as chromium III and chromium VI, or they had been split from S/L/T agency-reported
total chromium by the EPA using the procedures described in Section 3.1.4. Those procedures largely
rely on either SCC-based or Regulatory code-based split factors. The derived NAICS split factors,
therefore, represent a weighted average of the SCC and Regulatory code-based split factors, weighted
according to the mass of each chromium valence in the 2017 NEI for that NAICS.

After all TRI facilities with chromium had been assigned a NAICS-based split factor, the factors were
applied separately to both the TRI stack and fugitive total chromium emissions. This resulted in
speciated chromium emissions for each facility's stack and fugitive emissions that were included in the
EIS as part of the 2017EPA_TRI dataset.

Similar to S/L/T chromium speciation data, the TRI chromium speciation data includes some facility-
specific values resulting from 2011 and/or 2014 NATA reviews or provided by S/L/T for use in the 2017
NEI. The TRI-chromium speciation data "TRI_based_chromium_speciation.zip" is available are available

on the 2017 Supplemental data FTP site.

3-10

-------
4. Review high TRI emissions values for and exclude any data suspected to be outliers

A review and comparison of the largest TRI emissions values was conducted for several key high-risk
pollutants. The following pollutants were specifically reviewed, although a few extremely large values
for some of the other TRI pollutants were also noticed and treated in the same manner: Hg, Pb,
chromium, manganese, nickel, arsenic, 1,3 butadiene, benzene, toluene, ethyl benzene, p-xylene,
methanol, acrolein, carbon tetrachloride, tetrachloroethylene, methylene chloride, acrylonitrile, 1,4-
dichlorobenzene, ethylene oxide, hydrochloric acid, hydrogen fluoride, chlorine, 2,4-toluene
diisocyanate, hexamethylene diisocyanate, and naphthalene. The review included looking at the largest
10 emitting facilities for each of the pollutants in the 2017 TRI dataset itself to identify large differences
between facilities and unexpected industry types. Comparisons were then made to the 2014 TRI and the
2017 draft NEI emissions values from S/L/T agencies for any suspect facilities identified by that review
(as described above in Section 3.1.1).

5. Write the 2017 TRI emissions to EIS Process IDs with stack and fugitive release points

The total facility stack and total facility fugitive emissions values from the above steps were written to a
set of EIS process IDs created to reflect those facility total type emissions. In most cases, the EIS process
IDs for a given facility already existed in EIS as a result of earlier NEI.

6. Revise SCCs on the EIS Processes used for the TRI emissions

The 2002 and 2005 NEIs had assigned all the TRI emissions to a default process code SCC of 39999999,
which caused a large amount of HAP emissions to be summed to a misleading "miscellaneous" sector.
The 2008 NEI approach reduced this problem somewhat because it apportioned all TRI emissions to the
multiple processes and SCCs that were used by the S/L/T agencies to report their emissions, but this
apportioning created other distortions. The 2011 NEI reverted back to loading the TRI emissions as the
single process stack and fugitive values as reported by facilities to the TRI, but we revised the SCCs on
those single processes to something other than the default 39999999 wherever possible. The purpose of
this is to allow the TRI emissions to map to a more appropriate EIS sector. For the 2017 NEI, we retained
the 2011 approach, process IDs, and SCCs.

On occasion, TRI SCCs are updated where the process is known based on the type of facility or SCCs from
processes for which CAPs were reported. However, there has not been a systematic approach to fill in all
SCCs and for large industrial facilities, it would not be possible due to the variety of different process
operations that can occur at such facilities.

3.1.6 HAP augmentation based on emission factor ratios

The 2017EPA_HAP-augmentation dataset was used for gap filling missing HAPs in the S/L/T agency-reported
data. We calculated HAP emissions by multiplying the appropriate surrogate CAP emissions (provided by S/L/T
agencies) by an emissions ratio of HAP to CAP EFs. For point sources, these EF ratios were largely the same as
were used in the 2008 NEI v3, though additional quality assurance resulted in some changes. The ratios were
computed using the EFs from WebFIRE and are based solely on the SCC code. The computation of these point
HAP to CAP ratios is described in detail in the 2008 NEI documentation. Section 3.1.5.

For pollutants other than Hg, we computed ratios for only the SCCs in WebFIRE that met specific criteria: 1) the
CAP and HAP WebFIRE EFs were both based on uncontrolled emissions and, 2) the units of the EF had to be the
same or be able to be converted to the same units. In addition, for Hg, we added ratios for point SCCs that were
not in WebFIRE for both PM10-FIL (the CAP surrogate for Hg) and Hg by using Hg or PM10-FIL factors for similar

3-11

-------
SCCs and computing the resulting ratio. That process is described (and supporting data files provided) in the
2008 NEI documentation (Section 3.1.5.2), since these additional Hg augmentation factors were used in the
2008 NEI v3 as well.

A HAP augmentation feature was built into the EIS for the 2011 cycle, and the HAP EF ratios are available to the
EIS users through the reference data link "Augmentation Profile Information." The same tables provide both the
HAP augmentation factors and chromium speciation factors and were discussed in Section 2.2.2.

Since the initial set of HAP augmentation factors, factors and/or SCC-assignments were added including facility-
specific HAP augmentation factors resulting from NATA reviews. Also new for the 2017 NEI are facility-specific
coke oven to S02 ratios used to compute coke oven emissions for specific facilies with operating coke ovens that
were missing coke oven emissions. We have been also exploring using test-based emission factor ratios in place
of WebFIRE-based ratios where data are sufficient to do so. Users interested the few test-based factors that do
not have access to EIS can download the full set of HAP augmentation factors from the 201? Supplemental data
FTP site ("HAPaugmentation.zip") and peruse the metadata information (data source and factor comments) to
extract them.

A key facet of our approach is that the resulting HAP augmentation dataset does duplicate HAPs from the S/L/T
agency data or other EPA datasets. The extra step of data tagging of the HAP augmentation dataset was taken to
ensure the NEI would not use the data from the HAP augmentation dataset for facilities where the HAP was
reported by an S/L/T agency at any process at the facility or where the HAP was included in the EPA TRI dataset.
For example, if a facility reported formaldehyde at process A only, and the WebFIRE emission factor database
yields formaldehyde emissions for processes A, B, and C, then we would not use any records from the HAP
augmentation dataset containing formaldehyde from any processes at the facility. If that facility had no
formaldehyde, but the TRI dataset had formaldehyde for any processes at that facility, then the NEI would still
not use formaldehyde from the HAP augmentation dataset for any of the processes (it would use the TRI data).
If the EPA EGU dataset contained formaldehyde for that facility, we would use the HAP augmentation set but
not for any process at the same unit as EPA EGU dataset. If the EPA EGU dataset contained formaldehyde at
process A or any other process within the same unit as process A, then the HAP augmentation dataset would be
used for processes B and C, but not process A.

This approach was taken to be conservative in our attempt to prevent double counted emissions, which is
necessary because we know that some states aggregate their HAP emissions and assign to fewer or different
processes than their CAP emissions. These types of differences are expected since CAPs are required to be
submitted at the process level, but HAPs are entirely voluntary for the NEI's reporting rule. We used the EIS new
pollutant overlapping business rules (Section 3.3.17) to prevent double counting of pollutants belonging to
pollutant groups that may overlap with other pollutants in that group.

One of the changes we made from previous NEI's is that we no longer tag out point source HAP augmentation
values where the HAP augmentation value exceeded the maximum emissions reported by any S/L/T agency for
the same SCC/pollutant combination, or if no S/L/T agency reported any values for the same SCC/pollutant.

3.1.7 Cross-dataset tagging rules for overlapping pollutants

Several HAPs can be reported as individual chemicals or chemicals that reflect a group which can overlap with
individual chemicals, e.g., o-Xylene and Xylenes (mixed isomers). In previous NEI cycles, we tagged out data to
prevent double counting of pollutants across datasets that overlap one another. For the 2017 NEI, a software
solution that occurs during the blending process was developed so that overlapping pollutants would be
excluded from the selection. The business rules were documented as part of the 2017 NEI plan (see Appendix 5).

3-12

-------
One change to these "Proposed" rules that we implemented for the 2017 NEI is that we allow individual xylene
isomers to be reported with Xylenes (mixed isomers) within the same dataset. The cross-data business rules
used are the same as documented the plan.

One issue that came up with these rules regards the hexavalent chromium and trivalent chromium in the
2017EPA_CR_Aug dataset. This dataset, which contains S/L/T speciated chromium (i.e., hexavalent and trivalent
chromim), is separate from the S/L/T datasets but contains data that could be largely characterized as S/L/T
data. While we intended to allow S/L/T to report either unspeciated chromium or hexavalent chromium along
with chromic acid VI ro chromium trioxide at the same process, the software did not allow the hexavalent
chromium in the 2017EPA_CR_Aug dataset to be used with S/L/T chromic acid VI. This occurred only in 2 states,
NC and KY. For KY, the specated chromium was less than 0.1 lb and no corrections were made. In NC, there was
about 500 lbs hex chromium that would have been dropped so we corrected it. The correction was for NCto
incorporate the speciated chromium from2017EPA_CR_Aug into their dataset (instead of unspeciated
chromium) so that both pollutants would be used in the 2017 NEI selection. All records where EPA speciated
chromium data were used include an emissions comment to that effect.

3.1.8 Additional quality assurance and findings

Prior to the release of the data, we created national summaries of key pollutants and sectors. The list below
provides findings and associated follow-up steps:

• We created a preliminary summary of mercury from point source emissions, even in the absence of the
other sectors that feed the final mercury summary that will be included in Section 2 of the
documentation once the NEI is complete. Such a summary has been included in past documentation for
other inventories. This summary revealed a possible underestimation of mercury from the Commercial
and Industrial Solid Waste Incineration (CISWI) sector. Since not all sources are reported to NEI as point
sources, the NEI may not include all CISWI sources. In addition, the Hg estimates of these sources are
highly uncertain, could be underestimated, and the EPA is currently working to get improved mercury
and other emissions estimates for these sources.

• We summarized hydrazine emissions and found a significantly larger hydrazine estimate in Arkansas
than had been present in past inventories. This makes Hydrazine emissions overall in the NEI increase
since 2014. We contacted the air office of the Arkansas Department of Environmental Quality, and the
inventory staff there confirmed the accuracy of these emissions.

• We summarized ethylene oxide emissions and found that several facilities did not report ethylene oxide
to both the state air agency and to the TRI program in 2017, but those facilities were still operating in
2017. To gap-fill those missing emissions, we used the 2016 TRI data.

• We summarized hexavalent chromium emissions and found a significant increase in emissions since
2014. We identified some missing emissions for sources in NC and worked with NC to include those
chromium emissions. We did not find any errors in hexavalent chromium in the 2017 data, which shows
an increase in these emissions as compared to the 2014 NEI. This could be due to a more complete
inventory or to an actual increase.

3.2 Airports: aircraft-related emissions

The EPA estimated emissions related to aircraft activity for all known U.S. airports, including seaplane ports and
heliports, in the 50 states, Puerto Rico, and U.S. Virgin Islands. All of the approximately 20,000 individual airports
are geographically located by latitude/longitude and stored in the NEI as point sources. As part of the

3-13

-------
development process, S/L/T agencies had the opportunity to provide both activity data as well emissions to the
NEI. When activity data were provided, the EPA used that data to calculate the EPA's emissions estimates.

3.2.1 Sector Description

The aircraft sector includes all aircraft types used for public, private, and military purposes. This includes four
types of aircraft: (1) commercial, (2) air taxis (AT), (3) general aviation (GA), and (4) military. A critical detail
about the aircraft is whether each aircraft is turbine- or piston-driven, which allows the emissions estimation
model to assign the fuel used, jet fuel or aviation gas, respectively. The fraction of turbine- and piston-driven
aircraft is either collected or assumed for all aircraft types.

Commercial aircraft include those used for transporting passengers, freight, or both. Commercial aircraft tend to
be larger aircraft powered with jet engines. Air taxis carry passengers, freight, or both, but usually are smaller
aircraft and operate on a more limited basis than the commercial aircraft. General aviation includes most other
aircraft used for recreational flying and personal transportation. Finally, military aircraft are associated with
military purposes, and they sometimes have activity at non-military airports.

The national AT and GA fleets include both jet- and piston-powered aircraft. Most of the AT and GA fleets are
made up of larger piston-powered aircraft, though smaller business jets can also be found in these categories.
Military aircraft cover a wide range of aircraft types such as training aircraft, fighter jets, helicopters, and jet-
and piston-powered planes of varying sizes.

The NEI also includes emission estimates for aircraft auxiliary power units (APUs) and aircraft ground support
equipment (GSE) typically found at airports, such as aircraft refueling vehicles, baggage handling vehicles and
equipment, aircraft towing vehicles, and passenger buses. These APUs and GSE are located at the airport
facilities as point sources along with the aircraft exhaust emissions.

3.2.2 Sources aircraft emissions estimates

Aircraft exhaust, GSE, and APU emissions estimates are associated with aircrafts' landing and takeoff (LTO) cycle.
LTO data were available from both S/L/T agencies and FAA databases. For airports where the available LTO
included detailed aircraft-specific make and model information (e.g., Boeing 747-200 series), we used the FAA's
Aviation Environmental Design Tool (AEDT) to estimate emissions. Note that this is the first NEI to use this
model. 2008 and 2011 used the FAA's previous model, Emissions and Dispersion Modeling System (EDMS).
Therefore, comparisons of aircraft emissions output may be a function of model revisions, rather than an actual
trend in emissions. For airports where FAA databases do not include such detail, the EPA used assumptions
regarding the percent of LTOs that were associated with piston-driven (using aviation gas) versus turbine-driven
(using jet fuel) aircraft. Then, the EPA estimated emissions based on the percent of each aircraft type, LTOs, and
EFs The emissions factors used, as well as the complete methodology for estimating aircraft exhaust from LTOs
is in the aircraft documentation available in the document "2017Aircraft_main_19aug2019.pdf" on the 2017
Supplemental data FTP site. Only Texas and California submitted aircraft emissions.

In addition to airport facility point, the EPA also estimated in-flight Pb (from aviation gas) emissions that are
allocated to counties in the nonpoint inventory. Details about EPA's estimates

(2017Aircraft_lnflightLead_19aug2019.pdf), including a summary of state-level in-flight lead estimates
"2017Aircraft_lnflightLeadByState_19aug2019.csv" can be found on the 2017 Supplemental data FTP site.

3-14

-------
3.3 Rail yard-related emissions

The 2017 NEI includes estimates compiled by the Eastern Regional Technical Advisory Committee (ERTAC) for
most rail yards in the US. The ERTAC effort was comprised of a collaborative of state/local agencies, rail
companies, and the Federal Rail Administration. Yard emissions are associated with the operation of switcher
engines at each yard. The project is documented in a report" 2017Rail_main_21aug2019.pdf" on the 2017
Supplemental data FTP site. S/L/Ts submitted point rail yard emissions were given priority over the ERTAC
estimates when present.

3.4 EGUs

The EPA developed a single combined dataset of emission estimates for EGUs to be used to fill gaps for
pollutants and emission units not reported by S/L/T agencies. For the 2017EPA_EGU dataset, the emissions were
estimated at the unit level, because that is the level at which the CAMD heat input activity data and the MATS-
based emissions factors and the CAMD CEM data are available. The 2017EPA_EGU dataset was developed from
three separate estimation sources. The three sources were the 2010 MATS rule development testing program
EFs for 15 HAPs; annual sums of S02 and NOx emissions based on the hourly CEM emissions reported to the
EPA's CAMD database; and heat-input based EFs that were built from AP-42 EFs and fuel heat and sulfur
contents as part of the 2008 NEI development effort. We used the 2014 annual throughputs in BTUsfrom the
CAMD database with the two EF sets to derive annual emissions for 2017. A small number of the AP-42-based
estimates were discarded because the fuels or control configurations were found to be different than what they
were during the 2008 development effort that provided the heat-input based EFs that were available.

As shown above in Table 3-1, the selection hierarchy was set such that S/L/T-submitted data was used ahead of
the values in the 2017EPA_EGU dataset. In the 2011 NEI, the EPA EGU estimated emissions that were derived
from the MATS testing program were used ahead of the S/L/T values, unless the S/L/T submittal indicated that
the value was from either a CEM or a recent stack test. For the 2017 NEI, we used the S/L/T-reported values
wherever they were reported (unless they were tagged out as an outlier), including where a MATS-based value
existed in the 2017EPA EGU dataset. In addition, we made the MATS emission factors available to S/L/T agencies
far in advance of the data being submitted so that facilities and/or S/L/T agencies could choose to use that
information to compute emissions if it was most applicable.

We assumed that all heat input came from the primary fuel, and the EFs used reflected only that primary fuel.
This introduces a small amount of uncertainty as many EGU units use a small amount of alternative fuels. The
resultant unit-level estimates had to be loaded into EIS at the process-level to meet the EIS requirement that
emissions can only be associated with the most detailed level. To do this for the EGU sectors, we needed to
bridge the unit level (i.e., the boiler or gas turbine unit as a whole) to the process level (i.e., the individual fuels
burned within the units). So, the EPA emissions were assigned to a single process for the primary fuel that was
used by the responsible S/L/T agency for reporting the largest portion of their emissions. The EPA emissions
were then "tagged out" wherever the S/L/T agency had reported the same pollutant at any process within the
same emission unit. This approach prevented double counting of a portion of the S/L/T-reported emissions in
cases where the S/L/T agency may have reported a unit's emissions using two different coal processes and a
small oil process, for example.

The matching of the 2017EPA_EGU dataset to the responsible agency facility, unit and process IDs was done
largely by using the ORIS plant and CAMD boiler IDs as found in the CAMD heat input activity dataset and linking
these to the same two IDs as had been stored in EIS. We also compared the facility names and counties for
agreement between the S/L/T-reported values and those in CAMD, and we revised the matches wherever

3-15

-------
discrepancies were noted. As a final confirmation that the correct emissions unit and a reasonable process ID in
EIS had been matched to the EPA data, the magnitudes of the S02 and NOx emissions for all preliminary
matches were compared between the S/L/T agency-reported datasets and the EPA dataset. We identified and
resolved several discrepancies from this emissions comparison.

Alternative facility and unit IDs needed for matching with other databases

The 2017 NEI data contains two sets of alternate unit identifiers related to the ORIS plant and CAMD boiler IDs
(as found in the CAMD heat input activity dataset) for export to the Sparse Matrix Operator Kernel Emissions
(SMOKE) modeling file. The first set is stored in EIS with a Program System Code (PSC) of "EPACAMD." The
alternate unit IDs are stored as a concatenation of the ORIS Plant ID and CAMD boiler ID with "CAMDUNIT"
between the two IDs. These IDs are exported to the SMOKE file in the fields named ORIS_FACILITY_CODE and
ORIS_BOILER_ID. These two fields are used by the SMOKE processing software to replace the annual NEI
emissions values with the appropriate hourly CEM values at model run time. The second set of alternate unit IDs
are stored in EIS with a PSC of "EPAIPM" and are exported to the SMOKE file as a field named "IPM_YN." The
SMOKE processing software uses this field to determine if the unit is one that will have future year projections
provided by the integrated planning model (IPM). The storage format of these alternate EPAIPM unit IDs, in both
EIS and in the exported SMOKE file, replicates the IDs as found in the National Electric Energy Data
System (NEEDS) database used as input to the IPM model. The NEEDS IDs are a concatenation of the ORIS plant
ID and the CAMD boiler ID, with either a "_B_" or a "_G_" between the two IDs, indicating "Boiler" or
"Generator." The ORIS Plant IDs and CAMD boiler IDs as stored in the CAMD Business System (CAMDBS) dataset
and in the NEEDS database are almost always the same, but there are occasional differences for the same unit.
The EPACAMD alternate unit IDs available in the 2017 NEI are believed to be a complete set of all those that can
safely be used for the purpose of substituting hourly CEM values without double-counting during SMOKE
processing. The EPAIPM alternate unit IDs in the 2017 NEI are not a complete listing of all the NEEDS/IPM units,
although most of the larger emitters do have an EPAIPM alternate unit ID. The NEEDS database includes a much
larger set of smaller, non-CEM units.

3.5 Landfills

The point source emissions in the EPA's Landfill dataset includes CO and 28 HAPs, as shown in Table 3-3. This set
of pollutants was included in the 1999 NEI, and we continue to use the same set of pollutants each year for a
consistent time series. To estimate emissions, we used the methane emissions reported by landfill operators in
compliance with Subpart HH of the Greenhouse Gas Reporting Program (GHGRPi as a "surrogate" activity
indicator. We converted the methane as reported in Mg C02 equivalent to Mg as actual methane emitted by
dividing by 23 (the Global Warming Potential of methane believed to be used in the version of the 2017 GHGRP
facility inventory) to get MG methane emitted, and then multiplied by 1.1023 to get tons methane emitted5. We
created emission factors for CO and the 28 HAPs on a per ton of methane emitted basis using the default
concentrations (ppmv) in AP-42 Section 2.4 (final section dated Jan 1998), Table 2.4-1. The concentrations for
toluene and benzene were taken from Table 2.4-2 of AP-42, for the case of "no or unknown" co-disposal history.
Per Equation 4 of that AP-42 section, Mp=Qp x MWp x constant (at any given temperature). Writing this

equation twice, for the mass of any pollutant "P" and for methane (CH4), and dividing Mp by McH4 yields:
Mp / MCH4 = (Qp x MWp x k) / QCH4 x MWCH4 x k) = (Qp/QcH4) x (MWp/MWcH4)

5 For more information on C02 equivalent and global warming potential, please refer to EPA's page "Understanding Global
Warming Potentials".

3-16

-------
in units of pounds pollutant "?" per pound CH4.

A rearrangement of Equation 3 of that AP-42 section provides Qp/ QcH4 = 1-82 x Cp/1000000, where the 1.82 is

based upon a default methane concentration of 55 % (550,000 ppm). Plugging this expression for Qp/ QCH4 into
the first expression yields:

Mp / McH4 = (1-82 x Cp/1000000) x (MWp/ MWCH4) x 2000, units of pounds p/ton CH4
Mp / McH4 = (1-82 x Cp/1000000) x (MWp/16) x 2000 = Cp x MWp / 4395.6

Table 3-3: Landfill gas emission factors for 29 EIS pollutants

Pollutant
code

Pollutant description

MW

ppmv

MW x
ppmv

lbs/Ton

ch4

CO

Carbon monoxide

28.01

141

3949.41

0.89849

108883

toluene

92.13

39.3

3620.709

0.82371

1330207

Xylenes

106.16

12.1

1284.536

0.29223

75092

Dichloromethane (methylene chloride)

84.94

14.3

1214.642

0.27633

7783064

Hydrogen sulfide

34.08

35.5

1209.84

0.27524

127184

Perchloroethylene (tetrachloroethylene)

165.83

3.73

618.5459

0.14072

110543

Hexane

86.18

6.57

566.2026

0.12881

100414

Ethylbenzene

106.16

4.61

489.3976

0.11134

75014

Vinyl chloride

62.5

7.34

458.75

0.10437

79016

Trichloroethylene (trichloroethene)

131.4

2.82

370.548

0.08430

107131

Acrylonitrile

53.06

6.33

335.8698

0.07641

75343

1,1-Dichloroethane (ethylidene dichloride)

98.97

2.35

232.5795

0.05291

108101

Methyl isobutyl ketone

100.16

1.87

187.2992

0.04261

79345

1,1,2,2-Tetrachloroethane

167.85

1.11

186.3135

0.04239

71432

benzene

78.11

1.91

149.1901

0.03394

75003

Chloroethane (ethyl chloride)

64.52

1.25

80.65

0.01835

71556

1,1,1-Trichloroethane (methyl chloroform)

133.41

0.48

64.0368

0.01457

74873

Chloromethane

50.49

1.21

61.0929

0.01390

75150

Carbon disulfide

76.13

0.58

44.1554

0.01005

107062

1,2-Dichloroethane (ethylene dichloride)

98.96

0.41

40.5736

0.00923

106467

Dichlorobenzene

147

0.21

30.87

0.00702

463581

Carbonyl sulfide

60.07

0.49

29.4343

0.00670

108907

Chlorobenzene

112.56

0.25

28.14

0.00640

78875

1,2-Dichloropropane (propylene dichloride)

112.99

0.18

20.3382

0.00463

75354

1,1-Dichloroethene (vinylidene chloride)

96.94

0.2

19.388

0.00441

67663

Chloroform

119.39

0.03

3.5817

0.00081

56235

Carbon tetrachloride

153.84

0.004

0.61536

0.00014

106934

Ethylene dibromide

187.88

0.001

0.18788

0.00004

7439976

Mercury (total)

200.61

0.000292

0.05857812

0.00001

3-17

-------
3.6 2017EPA_gapf ills

This EPA dataset is used to fill in miscellaneous emissions which were not reported by S/L/T agencies for 2017,
and for which no EPA dataset has 2017 emissions, but which are believed to exist in 2017. These unreported
facilities and pollutants were identified as part of the QA review steps performed on the S/L/T data (see Section
3.1.1). A total of 95 unique facilities across 4 different States and 88 different pollutants are represented in this
dataset. Most of the additions were for Indiana (73 facilities), which did not submit emissions for all of their
operating facilities for 2017. 2016 NEI emissions were copied into the gapfills dataset for those facilities. Nine
facilities in Pinal County, AZ were also added using 2016 NEI emissions. NOx emissions only were added for
eleven coal mines in Wyoming which have significant emissions from trucks and other mobile equipment which
were not included in WYDEQ's point source dataset, and which are not expected to be adequately covered in
EPA's nonroad emission estimates. WYDEQ sent 2017 facility totals for these facilities mobile emissions to be
added to the 2017 NEI PT. Lastly, mercury emissions for two municipal waste combustors in Maryland and four
municipal waste combustors in Massachusetts were added.

3.7 BOEM

The U.S. Department of the Interior, Bureau of Ocean and Energy Management (BOEM) estimates emissions of
CAPs in the Gulf of Mexico from offshore oil platforms in Federal waters, and these data have been previously
incorporated into the NEI. More information on the 2017 Outer Continental Shelf (OCS) offshore data is
available on the BOEMS OCS Emissions Inventory - 2017 site.

3.8 PM species

For the 2017 NEI PT inventory, the five species (EC, OC, S04, N03, and other) of PM2.5-PRI and diesel PM (which
are estimated for diesel mobile engines such as locomotives and diesel-fueled ground support equipment) were
not included. These species will be generated in full NEI release in the Spring of 2020, similar to earlier NEI years
by using the PM speciation ratios as found on the Air Emissions Modeling website.

3.9 References for point sources

1. Dorn, J, 2012. Memorandum: 2011 NEI Version 2 - PM Augmentation approach. Memorandum to Roy
Huntley, US EPA. (PM augmt 2011 NEIv2 feb2012.pdf, accessible in the file "2008nei_reference.zip" on

the 2008v3 NEI FTP site.

2. Strait et al. (2003). Strait, R.; MacKenzie, D.; and Huntley, R., 2003. PM Augmentation Procedures for the
1999 Point and Area Source NEI. 12th International Emission Inventory Conference - "Emission
Inventories - Applying New Technologies", San Diego, April 29 - May 1, 2003.

3-18

-------
4 Nonroad Equipment - Diesel, Gasoline and Other

Although "nonroad" is used to refer to all mobile sources that are not on-highway, this section addresses
nonroad equipment other than locomotives, aircraft, or commercial marine vessels. Locomotive emissions from
railyards and aircraft and associated ground support equipment are described in Section 3. The nonpoint portion
of locomotives and commercial marine vessel emissions will be provided with the nonpoint section when it is
later-available with the full 2017 NEI release.

4.1 Sector Description

This section deals specifically with emissions processes calculated by the nonroad component of EPA's MOVES
model (herein referred to as MOVES-Nonroad) [ref 1] and the family of off-road models used by California [ref
2], They include nonroad engines and equipment, such as lawn and garden equipment, construction equipment,
engines used in recreational activities, portable industrial, commercial, and agricultural engines. Nonroad
equipment emissions are included in every state, the District of Columbia, Puerto Rico, and the U.S. Virgin
Islands.

Nonroad mobile source emissions are generated by a diverse collection of equipment from lawn mowers to
locomotive support. MOVES-Nonroad estimates emissions from nonroad mobile sources using a variety of fuel
types, as shown in Table 4-1.

Table 4-1: MOVES-Nonroad equipment and fuel types

Equipment Types

Fuel Types

Recreational



Construction



Industrial



Lawn and Garden



Agriculture

Commercial

Logging

Airport Ground Support Equipment (GSE; excludes aircraft)*
Underground Mining

Compressed Natural Gas (CNG)

Diesel

Gasoline

Liquified Petroleum Gas (LPG)

Oilfield**



Pleasure Craft (recreational marine; excludes commercial marine



vessels)



Railroad (excludes locomotives)



*Although MOVES-Nonroad estimates emissions from GSE, the results are not used in the NEI. NEI GSE
estimates are instead calculated via the Federal Aviation Administration's Aviation Environmental

Design Tool (AEDT).

**Although MOVES-Nonroad estimates emissions from Oilfield equipment, the results are not used in
the NEI, because they are duplicative of results from EPA's Oil and Gas Tool used in nonpoint source
calculations.

4-1

-------
4.2 MOVES-Nonroad

MOVES2014b, the latest public release of EPA's Motor Vehicle Emissions Simulator (MOVES) Model, estimates
daily emissions for total hydrocarbons (THC), nitrogen oxides (NOx), carbon monoxide (CO), carbon dioxide
(C02), particulate matter 10 microns and less (PM10), and sulfur dioxide (S02), as well as calculating fuel
consumption. MOVES2014b (version 20180726 [ref 1] uses ratios from some of these emissions to calculate
emissions for particular matter 2.5 microns and less (PM2.5), methane, ammonia (NH3), four more aggregate
hydrocarbon groups (NMHC, NMOG, TOG, and VOC), 14 hazardous air pollutants (HAPs), 17 dioxin/furan
congeners, 32 polycyclic aromatic hydrocarbons, and six metals. For a complete list of these pollutants, see
Table 4-2. All the input and activity data required to run MOVES-Nonroad are contained within the MOVES
default database, which is distributed with the model. State- and county-specific data can be used by creating a
supplemental database known as a county database (CDB) and specifying it in the MOVES run specification
(runspec). State, local and tribal (S/L/T) agencies can update the data within the CDBs to produce emissions
estimates that accurately reflect local conditions and equipment usage. MOVES first uses the data in the CDBs
and fills in any missing data from the MOVES default database.

Table 4-2: Pollutants produced by MOVES-Nonroad for 2017 NEI

Pollutant ID

Pollutant Name

Pollutant ID

Pollutant Name

1

Total Gaseous Hydrocarbons

83

Phenanthrene particle

2

Carbon Monoxide (CO)

84

Pyrene particle

3

Oxides of Nitrogen (NOx)

86

Total Organic Gases

5

Methane (CH4)

87

Volatile Organic Compounds

20

Benzene

88

NonHAPTOG

21

Ethanol

90

Atmospheric C02

22

MTBE

99

Brake Specific Fuel Consumption (BSFC)

23

Naphthalene particle

100

Primary Exhaust PM10 - Total

24

1,3-Butadiene

110

Primary Exhaust PM2.5 - Total

25

Formaldehyde

130

1,2,3,7,8,9-Hexachlorodibenzo-p-Dioxin

26

Acetaldehyde

131

Octachlorodibenzo-p-dioxin

27

Acrolein

132

1,2,3,4,6,7,8-Heptachlorodibenzo-p-Dioxin

30

Ammonia (NH3)

133

Octachlorodibenzofuran

31

Sulfur Dioxide (S02)

134

1,2,3,4,7,8-Hexachlorodibenzo-p-Dioxin

40

2,2,4-Trimethylpentane

135

1,2,3,7,8-Pentachlorodibenzo-p-Dioxin

41

Ethyl Benzene

136

2,3,7,8-Tetrachlorodibenzofuran

42

Hexane

137

1,2,3,4,7,8,9-Heptachlorodibenzofuran

43

Propionaldehyde

138

2,3,4,7,8-Pentachlorodibenzofuran

44

Styrene

139

1,2,3,7,8-Pentachlorodibenzofuran

45

Toluene

140

1,2,3,6,7,8-Hexachlorodibenzofuran

46

Xylene

141

1,2,3,6,7,8-Hexachlorodibenzo-p-Dioxin

60

Mercury Elemental Gaseous

142

2,3,7,8-Tetrachlorodibenzo-p-Dioxin

61

Mercury Divalent Gaseous

143

2,3,4,6,7,8-Hexachlorodibenzofuran

62

Mercury Particulate

144

1,2,3,4,6,7,8-Heptachlorodibenzofuran

63

Arsenic Compounds

145

1,2,3,4,7,8-Hexachlorodibenzofuran

65

Chromium 6+

146

1,2,3,7,8,9-Hexachlorodibenzofuran

66

Manganese Compounds

168

Dibenzo(a,h)anthracene gas

67

Nickel Compounds

169

Fluoranthene gas

4-2

-------
Pollutant ID

Pollutant Name

Pollutant ID

Pollutant Name

68

Dibenzo(a,h)anthracene particle

170

Acenaphthene gas

69

Fluoranthene particle

171

Acenaphthylene gas

70

Acenaphthene particle

172

Anthracene gas

71

Acenaphthylene particle

173

Benz(a)anthracene gas

72

Anthracene particle

174

Benzo(a)pyrene gas

73

Benz(a)anthracene particle

175

Benzo(b)fluoranthene gas

74

Benzo(a)pyrene particle

176

Benzo(g,h,i)perylene gas

75

Benzo(b)fluoranthene particle

177

Benzo(k)fluoranthene gas

76

Benzo(g,h,i)perylene particle

178

Chrysene gas

77

Benzo(k)fluoranthene particle

181

Fluorene gas

78

Chrysene particle

182

lndeno(l,2,3,c,d)pyrene gas

79

Non-Methane Hydrocarbons

183

Phenanthrene gas

80

Non-Methane Organic Gases

184

Pyrene gas

81

Fluorene particle

185

Naphthalene gas

82

lndeno(l,2,3,c,d)pyrene particle





4.3	Default MOVES code and database

The nonroad runs were executed using MOVES2014b, the most current publicly-released version of MOVES
available at the time. The code version for this release is moves20180726. The default database is
movesdb20181022, the same one released publicly with MOVES2014b.

Additionally, national updates that were made to the MOVES2014b default database for the 2016vl Platform
were used in the MOVES-Nonroad run for the 2017 NEI. This includes updated surrogate data for allocating
national populations of Agricultural and Construction equipment to the state and county levels, as described in
the 2016vl Platform Nonroad Mobile Emissions Specification Sheet [ref 4],

4.4	Additional Data: Nonroad County Databases (CDBs)

MOVES uses county databases (CDBs) to provide detailed local information for developing nonroad emissions.
The EPA encouraged S/L/T agencies to submit MOVES-Nonroad CDBs to the Emission Inventory System (EIS) for
the 2017 NEI. Data not provided in CDBs is automatically supplied from the MOVES default database. As is also
true for MOVES onroad runs, even if an agency submitted fuel or meteorological data, the EPA's values for these
data parameters were used. Fuels values were developed specifically for the 2017 NEI, based on the extensive
refinery gate batch dataset collected as a part of EPA's fuel compliance programs. The meteorological data were
provided by OAQPS and were derived from a Weather Research and Forecasting Model (WRF) version 3.8 [ref 5]
run.

Table 5-3 shows the selection hierarchy for the nonroad data category. The modified MOVES default database
for MOVES2014b containing refinements to construction and agricultural sectors [ref 4],
(movesdb20181022_nrupdates) and state-submitted inputs in CDBs were used to run MOVES-Nonroad to
produce emissions for all states other than California. California-submitted emissions were used.

4-3

-------
Table 4-3: Selection hierarchy for the Nonroad Mobile data category

Priority

Dataset

Notes

1

Responsible Agency
Data Set

Several tribes submitted nonroad emissions: Northern Cheyenne
Tribe, Kootenai Tribe of Idaho, Coeur d'Alene Tribe, Nez Perce Tribe,
Shoshone-Bannock Tribes of the Fort Hall Reservation of Idaho.
California submitted emissions calculated with their own model,
OFFROAD2007.*

2

2017EPA_Ca_MOVES

Includes California CAPs and HAPs speciated from California VOC and
PM based on MOVES ratios

3

2017EPA_MOVES

EPA defaults and S/L/T-supplied input data from 2017 NEI process

* Metro Public Health of Nashville/Davidson County also successfully submitted nonroad emissions but agreed
that EPA MOVES data should be used instead.

EPA asked S/L/T agencies to provide model inputs (CDBs) for 2017. Table 5-4 shows the S/L/T agencies that
submitted nonroad model inputs for the 2017 NEI via the EIS Gateway. Table 5-4 also shows data carried over
from prior NEI submittals for the LADCO states for day and month allocations. Two agencies submitted CDBs
through the EIS are not listed in the table (Delaware state and Davidson County, Tennessee), because they
provided only a ZoneMonthHour table that EPA did not use in the 2017 NEI.

Table 4-4: Submitted MOVES-Nonroad input tables,

State
Code

State or
County(ies) in
the Agency

nrbaseyearequippopulation

(source populations)

nrdayallocation

(allocation to day type)

nrfuelsupply(

(allocation of fuels)

nrgrowthindex

(population growth)

nrhourallocation

(allocation to diurnal pattern)

nrmonthallocation

(seasonal allocation)

nrsourceusetype

(yearly activity)

nrstatesurrogate

(allocation to counties)

countyyear

(stage II information)

nrequipmenttype

(surrogate selection)

nrsurrogate

(surrogate identification)

nrscc (SCCs)

4

Arizona -
Maricopa Co.

A



X







A

A

A

A

A



9

Connecticut

A























13

Georgia





A









A









16

Idaho



C





















17

Illinois











D













18

Indiana



C







D













19

Iowa



C







D













26

Michigan



C







D













27

Minnesota

A

C







D













29

Missouri











D













36

New York

A

A

X

A

A

A

A

A









39

Ohio



C







D













48

Texas

A

A

X





A

A

A



A

A

A

49

Utah

B

A



A

A





E









53

Washington















A



A

A



55

Wisconsin











D













ay agency.

A Submitted data.

4-4

-------
B Submitted data with modification: deleted records that were not snowmobile source types 1002-1010.
c 2014NEIv2 data used for 2017 NEI.

D Spreadsheet "Iadco_nei2017_nrmonthallocation.xlsx" (see discussion below)

E Submitted data with modification: deleted records that were not the snowmobile surrogate ID 14.
x Submitted data not used in 2017 NEI. The GA NRFuelSupply table is only used to divide counties into groups.

The 557 submitted CDBs used for the MOVES-Nonroad run are included in the full set of 3,225 CDBs collected
together in 2017_NonroadCDBs.zip in the 2017 NEI Supplemental nonroad mobile data FTP site. Outside of the
557 CDBs with the data inputs outlined above in Table 5.4, EPA also created a new CDB for each of the other US
counties with only the fuel tables to receive the information EPA developed from the refinery gate batch
dataset. The rest were run using the MOVES default database, which does not require CDBs. A list of all 3,225
U.S. counties and their corresponding CDBs, if any, is available in 2017_nonroad_counties_ FinalList.xlsx. These
supplemental nonroad mobile data contents are listed in Table 4-5 and are all available on the 2017 NEI
Supplemental nonroad mobile data FTP site.

Table 4-5: Contents of the Nonroad Mobile supplemental folder

File or Folder

Description

2017_NonroadCDBs.zip

Submitted nonroad CDBs used to run MOVES2014b and
EPA CDBs containing only 2017 EPA fuels.

2017 nonroad counties Final List.xlsx

List of all counties and their CDBs.

2017_zonemonthhour.zip

Zonemonthhour table (meteorology data).

2017_NonroadRunspecs.zip

Runspecs for all counties.

2017_postp rocess_n ra q_n rvoc. zip

Post-processing scripts for MOVES runs.

2017NR_CaEIS_SCC_Crosswalk.xlsx

File mapping California emission inventory codes (EICs) to
EPA SCCs.

4.5 MOVES runs

In the 2017 NEI Supplemental nonroad mobile data FTP site, the Excel® file

2017_nonroad_counties_nei2014vl_FinalList.xlsx lists all 3,225 counties and their corresponding CDBs. The
CDBs that were used are in 2017_NonroadCDBs.zip in the online NRSupplementatalData folder. If no CDB was
listed for a county, that county was run with the MOVES default database for MOVES2014b
(movesdb20180517). The supplemental nonroad mobile data is listed in Table 4-5.

MOVES was run for each county in a single, separate run specification file (runspec). All the runspecs are in the
2017_NonroadRunspecs.zip file in the online NRSupplementatalData folder. The MOVES-Nonroad runs were
checked for completeness and absence of error messages in the run logs. The output was post-processed to
consolidate each county into a single database and to produce SMOKE-ready input. The scripts that performed
these processes are in 2017_postprocess_nraq_nrvoc.zip in the 2.017 NEI Supplemental nonroad mobile data
FTP site. The MOVES runs created monthly, day type (weekday and weekend) total inventories for every U.S.
county, and post-processing scaled the day totals to monthly and annual values.

The following additional steps were taken on the monthly MOVES nonroad outputs to prepare data for loading
into EIS:

1. The gas and particle components of PAHs (e.g., Chrysene, Fluorene) were combined.

2. The individual mercury species were combined into total mercury (i.e., pollutant 7439976).

3. Emissions were aggregated from the more detailed SCCs modeled in MOVES to the SCCs modeled in
SMOKE.

4-5

-------
4. Modes for exhaust and evaporative were removed from pollutant names and separated out into the
emis_type data field in flat file 10 files that were then loaded into EIS.

5. Pollutants produced by MOVES but not accepted in the NEI were removed (e.g., ethanol, NONHAPTOG,
and total hydrocarbons).

6. Five speciated PM2.5 species were added based on speciation profiles (i.e., elemental carbon, organic
carbon, nitrate, sulfate and other PM2.5).

7. DIESEL-PM10 and DIESEL-PM25 were added by copying the PM10 and PM2.5 pollutants (respectively) as
DIESEL-PM pollutants for all diesel SCCs.

8. Airport ground support equipment emissions were removed.

9. Oil and gas field equipment emissions were removed.

10. Emissions from Wade Hampton Census Area, Alaska (FIPS code 02270) were reassigned to Kusilvak
Census Area (FIPS code 02158) to reflect a name and FIPS code change for 2017.

11. Incorporated California-submitted nonroad emissions.

Following the completion of the MOVES runs, railway maintenance emissions were removed from specific
counties / census areas in Alaska because Alaska DEC specified that this type of activity not happen in those
areas. Specifically, emissions from SCCs 2285002015, 2285004015, 2285006015 were removed from the
following counties / census areas: 02013, 02016, 02050, 02060, 02070, 02100, 02105, 02110, 02130, 02150,
02158, 02164, 02180, 02185, 02188, 02195, 02198, 02220, 02240, 02261, 02275, and 02282. Alaska DEC also
specified some counties / census areas in which logging and agricultural emissions do not happen, but the
emissions for the specified SCCs were already zero in the specified areas.

4.6 Use of California Submitted Emissions

California submitted criteria and HAP nonroad emissions for EPA's use in the NEI. California estimates emissions
with a California-specific model and converts them from their EIC codes to SCC codes via a crosswalk
(2017NR_CaEIS_SCC_Crosswalk.xlsx). The California criteria emissions were used directly. However, the HAP
values were incongruent with the criteria estimates.

MOVES was run for California to establish county/SCC-level ratios of VOC/VOC-HAP and PM/HAP-metal. The
ratios were applied to California-provided VOC and PM to estimate HAPs. VOC-HAP and HAP-Metals are
indicated in Table 4-6.

Table 4-6: HAPs calculated using MOVES ratios for California Nonroad SCCs

Pollutant

Pollutant Code

HAP Type

1,2,3,4,6,7,8-Heptachlorodibenzofuran

67562394

HAP-VOC

1,2,3,4,6,7,8-Heptachlorodibenzo-p-Dioxin

35822469

HAP-VOC

1,2,3,4,7,8,9-Heptachlorodibenzofuran

55673897

HAP-VOC

1,2,3,4,7,8-Hexachlorodibenzofuran

70648269

HAP-VOC

1,2,3,4,7,8-Hexachlorodibenzo-p-Dioxin

39227286

HAP-VOC

1,2,3,6,7,8-Hexachlorodibenzofuran

57117449

HAP-VOC

1,2,3,6,7,8-Hexachlorodibenzo-p-Dioxin

57653857

HAP-VOC

1,2,3,7,8,9-Hexachlorodibenzofuran

72918219

HAP-VOC

1,2,3,7,8,9-Hexachlorodibenzo-p-Dioxin

19408743

HAP-VOC

1,2,3,7,8-Pentachlorodibenzofuran

57117416

HAP-VOC

1,2,3,7,8-Pentachlorodibenzo-p-Dioxin

40321764

HAP-VOC

1,3-Butadiene

106990

HAP-VOC

2,2,4-Trimethylpentane

540841

HAP-VOC

4-6

-------
Pollutant

Pollutant Code

HAP Type

2,3,4,6,7,8-Hexachlorodibenzofuran

60851345

HAP-VOC

2,3,4,7,8-Pentachlorodibenzofuran

57117314

HAP-VOC

2,3,7,8-Tetrachlorodibenzofuran

51207319

HAP-VOC

2,3,7,8-Tetrachlorodibenzo-p-Dioxin

1746016

HAP-VOC

Acenaphthene

83329

HAP-VOC

Acenaphthylene

208968

HAP-VOC

Acetaldehyde

75070

HAP-VOC

Acrolein

107028

HAP-VOC

Anthracene

120127

HAP-VOC

Arsenic

7440382

HAP-Metal

Benz[a] Anthracene

56553

HAP-VOC

Benzene

71432

HAP-VOC

Benzo[a]Pyrene

50328

HAP-VOC

Benzo[b]Fluoranthene

205992

HAP-VOC

Benzo[g,h,i,]Perylene

191242

HAP-VOC

Benzo[k]Fluoranthene

207089

HAP-VOC

Chromium (VI)

18540299

HAP-Metal

Chrysene

218019

HAP-VOC

Dibenzo[a,h] Anthracene

53703

HAP-VOC

Ethyl Benzene

100414

HAP-VOC

Fluoranthene

206440

HAP-VOC

Fluorene

86737

HAP-VOC

Formaldehyde

50000

HAP-VOC

Hexane

110543

HAP-VOC

lndeno[l,2,3-c,d]Pyrene

193395

HAP-VOC

Manganese

7439965

HAP-Metal

Mercury

7439976

HAP-Metal

Naphthalene

91203

HAP-VOC

Nickel

7440020

HAP-Metal

Octachlorodibenzofuran

39001020

HAP-VOC

Octachlorodibenzo-p-Dioxin

3268879

HAP-VOC

Phenanthrene

85018

HAP-VOC

Propionaldehyde

123386

HAP-VOC

Pyrene

129000

HAP-VOC

Styrene

100425

HAP-VOC

Toluene

108883

HAP-VOC

Xylenes (Mixed Isomers)

1330207

HAP-VOC

In addition, C02 data were added to the California data based on EPA estimates, because C02 emissions were
not provided in the submission. We also speciated CARB total PM2.5 and PM10 using the same approach as for
other states and copied the PM2.5 and PM10 to DIESEL-PM "pollutants" for all diesel SCCs.

4.7 References for nonroad mobile

1. MOVES-Nonroad, its documentation and technical reports can be found here: Nonroad Technical
Reports.

4-7

-------
2.	CARB's group of models for off-road equipment may be linked to from this site: Mobile Source Emissions
Inventory.

3.	MOVES2Q14b, its default database, documentation and technical reports.

4.	National Emissions Inventory Collaborative (2019). Specification Sheet - 2016vl Platform Nonroad
Mobile Emissions. Retrieved from the Specification Sheet: Mobile Nonroad.

5.	Detailed information on The Weather Research & Forecasting Model (WRF) may be found here:

Weather Research and Forecasting Model and here: Skamarock, W.C., et al., National Center for
Atmospheric Research, Mesoscale and Microscale Meteorology Division, Boulder CO, June 2008,
NCAR/TN-475+STR, A Description of the Advanced Research WRF Version 3.

6.	Crosswalk of CA EIC to SCC: 2017NR CaEIS SCC Crosswalk.xlsx

4-8

-------
5 EVENTS Data Category

5.1 Sector description and overview

Wildfires and prescribed burns (Wildland Fires in sum, WLFs) that occur during the inventory year are included
in the NEI as "event" sources. Emissions from these fires, as well as agricultural fires, make up the National Fire
Emissions Inventory (NFEI). For the 2017 NFEI, the EPA calculated emissions from agricultural fires separately
from WLF emissions as described elsewhere in this TSD. This portion of the document describes the calculation
of WLF emissions portion of the 2017 NEI.

Estimated emissions from wildfires and prescribed burns in the 2017 NEI (termed in the remainder of this
section as the "2017 NEI"—as this section only pertains to WLFs) are calculated from burned area data. Input
data sets are collected from State/Local/Tribal (S/L/T) agencies and from national agencies and organizations.
S/L/T agencies that provide input data were also asked to complete the NEI Wildland Fire Inventory Database
Questionnaire, which consists of a self-assessment of data completeness. Raw burned area data compiled from
S/L/T agencies and national data sources are cleaned and combined to produce a comprehensive burned area
data set. Emissions are then calculated using fire emission models that rely on burned area as well as fuel and
weather information. The resulting emissions are compiled by date and location as day-specific emission
estimates.

For purposes of emission inventory preparation, wildland fire (WLF) is defined as "any non-structure fire that
occurs in the wildland (an area in which human activity and development are essentially non-existent, except for
roads, railroads, power lines, and similar transportation facilities). Wildland fire activity is categorized by the
conditions under which the fire occurs. These conditions influence important aspects of fire behavior, including
smoke emissions. In the 2014 NEI, data processing is conducted differently depending on the fire type, as
defined below:

Wildfire (WF): "any fire started by an unplanned ignition caused by lightning; volcanoes; other acts of nature;
unauthorized activity; or accidental, human-caused actions, or a prescribed fire that has developed into a
wildfire."

Prescribed (Rx) fire: "any fire intentionally ignited by management actions in accordance with applicable laws,
policies, and regulations to meet specific land or resource management objectives." Prescribed fire is one type
of fuels treatment. Fuels treatments are vegetation management activities intended to modify or reduce
hazardous fuels. Fuels treatments include prescribed fires, wildland fire use, and mechanical treatment.

Agricultural burning is a type of prescribed fire, specifically used on land used or intended to be used for raising
crops or grazing. This is dealt with in a different section of this document.

Pile burning is a type of prescribed fire in which fuels are gathered into piles before burning. In this type of
burning, individual piles are ignited separately. Pile burn emissions are not currently included in the NEI due to
lack of usable data and default methods. EPA continues to work to develop methods for estimating emissions of
this source type.

Table 5-1 lists the Source Classification Codes (SCCs) that define the different types of WLFs in the 2017 NEI,
both for EPA data and for S/L/T agency data. The leading SCC description for these SCCs is "Miscellaneous Area
Sources; Other Combustion - as Event". Since the 2014 NEI, the EPA has compiled WLF emissions by smoldering

5-1

-------
and flaming phases. The SCCs shown in are used to denote this differentiation. There are five valid SCCs for
events in EIS for the 2017 NEI, and EPA reports estimates into each of these SCCs. One difference to note for the
2017 NEI is that we have included a specific SCC (2801500170) that houses only the grassland fires of "Flint
Hills/' which occur over much of KS and a small part of OK. The other SCCs are carried over from the 2014 NEI.
The SCCs that were available for pile burns in the 2014 NEI have been omitted here, since EPA does not yet have
a default method for estimating those emissions. In addition, other grassland fires (other than "Flint Hills" fires)
are processed via the SF2/BS process described below and inventoried along with other wildfires. Please note
that in the 2014 NEI, these grassland fires were all inventoried as part of agricultural fires (in the nonpoint data
category), and here we are switching to housing them in the events data category. This decision was made
based on some analysis done during the 2016 Modeling Platform Collaborative inventory process [ref 1],

Table 5-1: SCCs for wildland fires

SCC

Description

2801500170

Grassland fires; prescribed

2810001001

Forest Wildfires; Smoldering; Residual smoldering only (includes grassland wildfires)

2810001002

Forest Wildfires; Flaming (includes grassland wildfires)

2811015001

Prescribed Forest Burning; Smoldering; Residual smoldering only

2811015002

Prescribed Forest Burning; Flaming

5,2 Sources of data

The WLF EIS sectors include data only from three components: S/L/T agency-provided emissions data for
Georgia and Washington (day-specific data in events format), the EPA dataset created from SmartFire version 2
(SF2/BS), which used available state inputs, and a PM2.5 speciation file that contains the five components of
PM2.5 for each fire. This merged information is the basis of the WLF 2017 NEI. The hierarchy of data used to
compile the 2017 NEI was very straightforward: the PM2.5 speciation dataset comes first, followed by Georgia's
and Washington's submitted emissions data, followed by EPA's dataset, as shown in Table 5-2.

Table 5-2: 2017 NEI Wildfire and Prescribed Fires selection hierarchy

Priority

Dataset Name

Dataset Content

Is Dataset in EIS?

PM2.5 Speciation

PM2.5 species for all data

YES

State/Local/Tribal Data

Submitted data as discussed above

Yes

2017EPA_EVENT

Emissions from SFv2

Yes

The NEI includes only Georgia and Washington-provided data for that S/L/T; in other words, there were no
additions with any EPA-based data based on the questionnaire GA and WA submitted that indicated their
submissions were complete for each of these states. Both Georgia and Washington were supplied HAP to VOC
ratios by EPA, which they used to estimate HAPs based on their VOC emissions to calculate HAP emissions, so
that these emissions calculations were used consistent with what was used for the remainder of the U.S. via the
EPA methods. In 2017, while tribes submitted some WLF emissions data, they were not explicitly used in the
BS/SF2 processing. Instead, EPA used the nationwide NEI WLF emission estimates and developed tribal land
emission estimates using appropriate shapefiles and GIS. These estimates over tribal lands are available as part
of the public release of 2017 Events data.

The S/L/Ts were not permitted to submit PM2.5 speciated emissions, which are required in the NEI. These PM
species pollutants include EC, OC, S04, N03, and "other" (PMFINE). These were estimated for all events data
(WA, GA, and all other states) by EPA using the fractions shown in Table 5-3.

5-2

-------
Table 5-3: PM species for all events, computed as fraction of total PM2.5

Species

Fraction

PEC

0.0323

POC

0.4688

PN03

0.0003

PS04

0.0013

PMFINE

0.4973

5.3 EPA methods summary

Preparation of the EPA WLF emissions begins with raw input data and ends with daily estimates of emissions
from flaming combustion and smoldering combustion phases. Flaming combustion is combustion that occurs
with a flame. Flaming combustion is more complete combustion and is more prevalent with fuels that have a
high surface-to-volume ratio, a low bulk density, and low moisture content. Smoldering combustion is
combustion that occurs without a flame. Smoldering combustion is less complete and produces some pollutants,
such as PM2.5, VOCs, and CO at higher rates than flaming combustion. Smoldering combustion is more prevalent
with fuels that have low surface-to-volume ratios, high bulk density, and high moisture content. Models
sometimes differentiate between smoldering emissions that are lofted with a smoke plume and those that
remain near the ground (residual emissions). In the 2017 NEI, all flaming emissions are made up of any
component that has a flaming component to it while the smoldering emissions are the residual smoldering
component that is generated by the CONSUME model, as described further below. The emissions estimates
were estimated and compiled separately for flaming and smoldering combustion phases of fire to facilitate air
quality modeling and fine-scale research in areas such as health impacts of smoke emissions, where the known
impacts of varying PM and VOC composition by combustion phase likely play a role.

In the 2017 NEI process, EPA developed draft 2017 emission estimates based just on default information. S/L/Ts
had an opportunity to review these estimates and: 1) accept them as final, 2) submit activity data and a
questionnaire (as detailed below), or 3) provide comments. In developing final 2017 WLF estimates, EPA took
into consideration all 3 of these items. If an S/L/T accepted the draft estimates, those estimates were not
changed in the process to develop final estimates.

5.3.1 National Fire Information Data

Numerous fire information databases are available from U.S. national government agencies. Some of the
databases are available via the internet while others must be obtained directly from agency staff. Table 5-4
provides the national fire information databases that were used for the EPA's 2017 NEI methods for wildland fire
emissions estimates, including the website where the 2017 data were downloaded.

Table 5-4: National fire information databases used in EPA's 2017 NEI wildland fire emissions estimates

Dataset Name

Fire Types

Format

Agency

Coverage

Source

Hazard Mapping System
(HMS)

WF/ RX

CSV

NOAA

North
America

Hazard Mapping System Fire
and Smoke Product

5-3

-------
Dataset Name

Fire Types

Format

Agency

Coverage

Source

Geospatial Multi-Agency
Coordination (GeoMAC)

SHP

USGS

Entire US

Geosciences and
Environmental Change
Science Center

Incident Command System
Form 209: Incident Status
Summary (ICS-209)

WF/ RX

CSV

Multi

Entire US

FAMWEB Data Warehouse

ICS-209

National Association of State
Foresters (NASF)

CSV

Multi

Participating
US states

FAMWEB Home

Forest Service Activity
Tracking System (FACTS)

SHP

USFS

Entire US

Hazardous Fuel Treatment
Reduction: Polygon

US Fish and Wildland Service
(USFWS) fire database

WF/ RX

CSV

USFWS

Entire US

Direct communication with
USFWS

The Hazard Mapping System (HMS) was developed in 2001 by the National Oceanic and Atmospheric
Administration's (NOAA) National Environmental Satellite and Data Information Service (NESDIS) as a tool to
identify fires over North America in an operational environment. The system utilizes geostationary and polar
orbiting environmental satellites. Automated fire detection algorithms are employed for each of the sensors.
When possible, HMS data analysts apply quality control procedures for the automated fire detections by
eliminating those that are deemed to be false and adding hotspots that the algorithms have not detected via a
thorough examination of the satellite imagery.

The HMS product used for the 2017 NEI inventory consisted of daily comma-delimited files containing fire detect
information including latitude-longitude, satellite used, time detected, and other information. Landcover was
spatially associated with each HMS detects using the Cropland Data Layer (CDL). HMS detects over croplands
were removed from the input files so that only wildland fires are included. Unlike in prior wildland fire NEIs all
grassland fire HMS satellite detects were included in the EPA's 2017 NEI wildland fire emissions estimates. These
grassland fires were processed through SmartFire2 and BlueSky with the other wildland fires.

GeoMAC (Geospatial Multi-Agency Coordination) is an online wildfire mapping application designed for fire
managers to access maps of current U.S. fire locations and perimeters. The wildfire perimeter data is based
upon input from incident intelligence sources from multiple agencies, GPS data, and infrared (IR) imagery from
fixed wing and satellite platforms. Fires in the year-specific GeoMAC shapefile with dates outside of 2017 were
removed. Some polygons have geometries which cause errors in SmartFire2 processing. These problematic
polygons were simplified using standard GIS methods.

The Incident Status Summary, also known as the "ICS-209" is used for reporting specific information on
significant fire incidents. The ICS-209 report is a critical interagency incident reporting tool giving daily
'snapshots' of the wildland fire management situation and individual incident information which include fire
behavior, size, location, cost, and other information. Data from two tables in the ICS-209 database were merged
and used for the EPA's 2017 NEI wildland fire emissions estimates: the

SIT209_HISTORY_INCIDENT_209_REPORTS table contained daily 209 data records for large fires, and the
SIT209_HISTORY_INCIDENTS table contained summary data for additional smaller fires. Some entries in the ICS-
209 database contained location and date errors. In situations where the errors were obvious in nature, such as
swapped latitude and longitudes or a typo in the year of the data, then appropriate corrections were made.

5-4

-------
Fires with unclear location and date issues or those fires without an associated burned area were removed.
Significant location errors for some large fires were noted and corrected in the 2017 ICS-209 database.

The National Association of State Foresters (NASF) is a non-profit organization composed of the directors of
forestry agencies in the states, U.S. territories, and District of Columbia to manage and protect state and private
forests, which encompass nearly two-thirds of the nation's forests. The NASF compiles fire incident reports from
agencies in the organization and makes them publicly available. The NASF fire information includes dates of fire
activity, acres burned, and fire location information. Similar to entries in the ICS-209 database, entries with
obvious and resolvable date and location errors were corrected. Fires with unclear location and date issues or
those fires without an associated burned area were removed.

The US Forest Service (USFS) compiles a variety of fire information every year. Year 2017 data from the USFS
Natural Resource Manager (NRM) Forest Activity Tracking System (FACTS) were acquired and used for 2017 NEI
emissions inventory development. This database includes information about activities related to fire/fuels,
silviculture, and invasive species. The FACTS database consists of shapefiles for prescribed burns that provide
acres burned and start and ending time information. As detailed earlier, all fires labeled as pile burns were
removed because the EPA does not currently develop emissions for pile burning.

The US Fish and Wildland Service (USFWS) also compiles wildfire and prescribed burn activity on their federal
lands every year. Year 2017 data were acquired from USFWS through direct communication with USFWS staff
and were used for 2017 NEI emissions inventory development. The USFWS fire information provided fire type,
acres burned, latitude-longitude, and start and ending times. As with the FACTS dataset, fires labeled as pile
burns were removed because the EPA does not currently develop emissions for pile burning.

5.3.2 State/Local/Tribal fire information

As in previous NEI years and building off the 2016 modeling platform collaborative efforts, S/L/Ts were asked to
submit fire occurrence/activity data for the 2017 NEI. A template form containing the desired format for data
submittals was provided to S/L/T air agencies. A map of all states that returned the template form is shown in
Figure 5-1. States that did not return the template form are shown in gray and had emissions based only on
national default data. In total, 20 states returned the template form for the EPA's 2017 NEI wildland fire
emissions estimates processing. The states that returned the forms directly to the EPA are Alaska, Alabama,
Arizona, Delaware, Georgia, Florida, Hawaii, Iowa, Kansas, Massachusetts, New Jersey, Nevada, North Carolina,
South Carolina, Utah, and Washington. Four other states -Idaho, Montana, Oregon, and Wyoming- had forms
returned by the Western Regional Air Partnership (WRAP) as part of the Fire Emissions Tracking System (FETS).
In addition to supplying activity data, S/L/Ts that supplied such data were also requested to complete a
questionnaire to help EPA determine how complete their activity data submissions were.

Figure 5-1: 2017 NEI Wildland Fire Data Sources including S/L/Ts

5-5

-------
DRAFT

When fire activity or emissions were provided by S/L/Ts the data were evaluated by EPA and further feedback
on the data submitted by the state was requested at times. Table 5-5 provides a summary of the type of data
submitted by each S/L/T agency and includes spatial, temporal, acres burned, and other information provided by
the agencies.

Table 5-5: Brief description of fire activity information submitted for 2017 NEI inventory use.

S/L/T name

Fire Types

Description

Alaska

WF/RX

Latitude-longitude, FCCS fuel beds, and acres burned for wildfire and
prescribed burns

Alabama

WF/RX

Start and end dates, latitude-longitude, and acres burned for wildfire and
prescribed burns

Arizona

RX

Day-specific, latitude-longitude, and acres burned for prescribed burns

Delaware

RX

Day-specific, latitude-longitude, and fuel loading for prescribed burns.
Opted to use national default datasets

Florida

WF/RX

Start and end dates, latitude-longitude, and acres burned for wildfire and
prescribed burns

Georgia

WF/RX

Emissions data submitted included all fires types via EIS. The wildfire and
prescribed burn data were provided as daily, point emissions sources.

Iowa

WF/RX

Day-specific, latitude-longitude, and acres burned for wildfire and
prescribed burns. Did not contain end dates.

Idaho

RX

Day-specific, latitude-longitude, acres burned, and fuel loading for
prescribed burns. Data included pile burn activity, which was removed prior
to emissions estimation.

Kansas

RX

Day-specific, county-centroid, and acres burned for Flint Hills prescribed
grassland burning

5-6

-------
S/L/T name

Fire Types

Description

Massachusetts

WF/RX

Day-specific, latitude-longitude, and acres burned for wildfire and
prescribed burns. Did not contain end dates.

Montana

RX

Day-specific, latitude-longitude, acres burned, and fuel loading for
prescribed burns. Data included pile burn activity, which was removed prior
to emissions estimation.

New Jersey

WF/RX

Day-specific, latitude-longitude, and acres burned for wildfire and
prescribed burns. Did not contain end dates. Opted to use national default
datasets.

North Carolina

WF/RX

Day-specific, latitude-longitude, and acres burned for wildfire and
prescribed burns. Camp Lejeune activity carried forward from 2014
estimates.

Nevada

WF

Day-specific, latitude-longitude, and acres burned for wildfires.

Oregon

RX

Day-specific, latitude-longitude, acres burned, and fuel loading for
prescribed burns. Data included pile burn activity, which was removed prior
to emissions estimation.

South Carolina

WF/RX

Day-specific, latitude-longitude, and acres burned for wildfire and
prescribed burns

Utah

WF/RX

Day-specific, latitude-longitude, and acres burned for wildfire and
prescribed burns

Washington

WF/RX

Emissions data submitted included all fires types via EIS. The wildfire and
prescribed burn data were provided as daily, point emissions sources.

Wyoming

RX

Day-specific, latitude-longitude, acres burned, and fuel loading for
prescribed burns. Data included pile burn activity, which was removed prior
to emissions estimation.

In order to develop a format that could be ingested into SmartFire or directly into Bluesky certain preprocessing
steps were taken with the S/L/T submitted datasets. The names of columns and formats were changed to match
what the processors required. Additionally, all datasets were reviewed for invalid locations or those that were
spatially identified as occurring outside the submitting state. Obvious location errors, such as those where the
latitude and longitude were swapped or a sign was missing, were fixed. The Alabama and Iowa submittals
contained many valid locations that were outside of the respective state by a large distance. Without additional
information identifying an activity location within the respective state, these records were dropped. Overall the
records dropped accounted for a very small portion of the total activity.

The temporal approach for the S/L/T varied based on the information provided in the submitted data and
direction from the individual agencies. Iowa, Kansas, and Massachusetts submitted activity without end dates.
Each of these states provided direction to assume that all fires lasted for a single day. Alabama, Florida, North
Carolina, South Carolina, and Utah all provided end dates along with start dates, however it was necessary to
apportion the activity to each day in the range to develop daily emissions. In the case of Alabama, North
Carolina, and South Carolina multi-day fires were assumed to have an equal proportion of the total event
activity on each day of the event. Alaska, Florida, and Utah utilized a different approach where an attempt was
made to reconcile the daily events in SmartFire2 against the HMS activity. Where a multi-day event could be
matched to HMS detections the number of HMS detections on each day within the event were used to
apportion the total event activity. When a spatial and temporal match could not be made between the
submitted data a flat approach was used for the multi-day event as described for Alabama, North Carolina, and
South Carolina.

5-7

-------
The following states required additional preprocessing steps:

• Alaska. Start and end dates were not included in the submission. Dates were filled from the national
default data using the submitted location information and fire name. After some discussion, Alaska
approved of the use of EPA WLF estimates for their entire domain.

• Kansas. The activity for the Flint Hills region was spatially reapportioned from the county-level to 2011
NLCD grass land area at centroids of 4 km grid cells. Weighting of activity was done using the area of
overlap between the grass land grid cells and the respective county.

• North Carolina. The 247-day long Pocosin fire was dropped from the submitted data with direction from
the state.

5.3.3 Emissions Estimation Methodology

The national and S/L/T data mentioned earlier were used to estimate daily wildfire and prescribed burn
emissions from flaming combustion and smoldering combustion phases for the 2017 NEI inventory. Flaming
combustion is more complete combustion than smoldering and is more prevalent with fuels that have a high
surface-to-volume ratio, a low bulk density, and low moisture content. Smoldering combustion occurs without a
flame, is a less complete burn, and produces some pollutants, such as PM2.5, VOCs, and CO, at higher rates than
flaming combustion. Smoldering combustion is more prevalent with fuels that have low surface-to-volume
ratios, high bulk density, and high moisture content. Models sometimes differentiate between smoldering
emissions that are lofted with a smoke plume and those that remain near the ground (residual emissions), but
for the purposes of the 2017 NEI inventory the residual smoldering emissions were allocated to the smoldering
SCCs ending in "1", while the lofted smoldering emissions were assigned to the flaming emissions SCCs ending in

Figure 5-2 is a schematic of the data processing stream for the 2017 NEI inventory for wildfire and prescribe
burn sources. The EPA's 2017 NEI wildland fire emissions estimates were estimated using Satellite Mapping
Automated Reanalysis Tool for Fire Incident Reconciliation version 2 (SMARTFIRE2) and BlueSky Framework.
SMARTFIRE2 is an algorithm and database system that operate within a geographic information system (GIS).
SMARTFIRE2 combines multiple sources of fire information and reconciles them into a unified GIS database. It
reconciles fire data from space-borne sensors and ground-based reports, thus drawing on the strengths of both
data types while avoiding double-counting of fire events. At its core, SMARTFIRE2 is an association engine that
links reports covering the same fire in any number of multiple databases. In this process, all input information is
preserved, and no attempt is made to reconcile conflicting or potentially contradictory information (for
example, the existence of a fire in one database but not another). Further details of the SMARTFIRE2 process as
applied to NEI development can be found in the literature [ref 2],

For the 2017 NEI inventory, the national and S/L/T fire information was input into SMARTFIRE2 and then merged
and reconciled together based on user-defined weights for each fire information dataset. The relative weights
used for the national data stream are shown in Table 5-6. A dataset type with a higher ranking gets preference
for that attribute in the reconciled activity. The output from SMARTFIRE2 was daily acres burned by fire type,
and latitude-longitude coordinates for each fire. The fire type assignments were made using the fire information
datasets. If the only information for a fire was a satellite detect for fire activity, then Figure 5-3 was used to
make fire type assignment by state and by month.

5-8

-------
DRAFT

Figure 5-2: Processing flow for fire emission estimates in the 2017 NEI inventory

Input Data Sets
(state/local/tribal and national data sets)

Fuel Moisture and
Fuel Loading Data



Smoke Modeling (BlueSky Framework)



Daily smoke emissions
for each fire



Emissions Post-Processing



Final Wildland Fire Emissions Inventory







Data Preparation



0 O



Data Aggregation and Reconciliation
(SmartFire2)



Daily fire locations
with fire size and type



5-9

-------
DRAFT

Figure 5-3: Default fire type assignment by state and month in cases where a satellite detect is only source of

fire information

None

Table 5-6: 2017 National SmartFire2 Reconciliation Weights

Rank

Location
Weight

Size Weight

Shape
Weight

Growth
Weight

Name
Weight

Fire Type
Weight

1

SLT

Supplemental
Data

SLT

Supplemental
Data

GeoMAC

SLT

Supplemental
Data

GeoMAC

SLT

Supplemental
Data

2

GeoMAC

GeoMAC

FACTS

HMS

ICS-209

ICS-209

3

HMS

FACTS

HMS

GeoMAC

NASF

GeoMAC

4

FACTS

ICS-209

SLT

Supplemental
Data

ICS-209

FETS

NASF

5

ICS-209

FETS

FETS

NASF

USFWS

FETS

6

FETS

NASF

ICS-209

USFWS

FACTS

FACTS

7

NASF

USFWS

NASF

FETS

HMS

USFWS

8

USFWS

HMS

USFWS

FACTS

SLT

Supplemental
Data

HMS

Supplemental S/L/T activity from Arizona, Idaho, Montana, Nevada, Oregon, and Wyoming were incorporated
with the national defaults into the national data reconciliation stream. States that submitted complete activity
datasets were not processed through SmartFire2 with the default national activity. An exception is for those
states that used HMS fire detections for daily apportionment of activity data. Alaska, Florida, and Utah all had
their submitted data reconciled against the HMS fire detections. All resulting activity that was identified only
through HMS was removed from the final activity dataset so that only state-submitted event values were used

5-10

-------
for emissions estimates. State-submitted activity from Iowa, Kansas, Massachusetts, North Carolina, and South
Carolina were not processed through SmartFire2. Instead each activity dataset was converted into daily activity
files in a format that can be read directly by the BlueSky Framework.

The BlueSky Modeling Framework version 3.5 (revision #38169) was used to calculate fuel loading and
consumption, and emissions using various models depending on the available inputs as well as the desired
results. The contiguous United States and Alaska, where Fuel Characteristic Classification System (FCCS) fuel
loading data are available, were processed using the modeling chain described in Figure 5-4. The Fire Emissions
Production Simulator (FEPS) in the BlueSky Framework generated all the CAP emission factors for wildland fires
used in the 2017 NEI inventory [ref 3], The HAP emission factors used in this work came from Urbanski, 2014 [ref
4], These emission factors were regionalized and handled differently by wild and prescribed fire. Table 5-7 below
outlines the regionalization scheme used while Table 5-8 and Table 5-9 show the HAP EFs employed in this work
separately for wild and prescribed fires. Note the differences, in bold in Table Table 5-7, for wildfires and
prescribed burning region assignments for Alaska and Wisconsin.

Table 5-7: Emission factor regions used to assign HAP emission factors for the 2017 NEI

Region

Wildfires

Prescribed burning

Region 1

AZ, CA, IA, IL, IN, KS, MO, NM, NV, OH, OK, TX

AZ, CA, IA, IL, IN, KS, MO, NM, NV, OH, OK, TX

Region 2

AK, AL, AR, CT, DC, DE, FL, GA, HI, KY, LA, MA,
MD, ME, Ml, MN, MS, NC, NH, NJ, NY, PA, PR,
Rl, SC, TN, VA, VI, VT, Wl, WV

AL, AR, CT, DC, DE, FL, GA, HI, KY, LA, MA, MD,
ME, Ml, MN, MS, NC, NH, NJ, NY, PA, PR, Rl, SC,
TN, VA, VI, VT, WV

Region 3

CO, ID, MT, ND, NE, OR, SD, UT, WA, WY

AK, CO, ID, MT, ND, NE, OR, SD, UT, WA, Wl,
WY

Table 5-8: Prescribed fire HAP emission factors (lb/ton fuel consumed) for the 2017 NEI

HAP

Flaming

Smoldering

Region 1

Region 2

Region 3

Region 1

Region 2

Region 3

1,3-Butadiene (HAP 106990)

0.272326792

0.516619944

0.362434922

0.272326792

0.516619944

0.362434922

Acetaldehyde (HAP 75070)

1.678013616

1.283540248

2.240688827

1.678013616

1.283540248

2.240688827

Acetonitrile (HAP 75058)

0.322386864

0.064076892

0.43051662

0.322386864

0.064076892

0.43051662

Acrolein (HAP 107028)

0.512615138

0.646776131

0.684821786

0.512615138

0.646776131

0.684821786

Acrylic Acid (HAP 79107)

0.070084101

0.058069684

0.094112936

0.070084101

0.058069684

0.094112936

Anthracene (HAP 120127)

0.005

0.005

0.005

0.005

0.005

0.005

Benz(a)anthracene (HAP 56553)

0.0062

0.0062

0.0062

0.0062

0.0062

0.0062

Benzene (HAP 71432)

0.450540649

0.566680016

0.600720865

0.450540649

0.566680016

0.600720865

Benzo(a)fluoranthene (HAP
203338)

0.0026

0.0026

0.0026

0.0026

0.0026

0.0026

Benzo(a)pyrene (HAP 50328)

0.00148

0.00148

0.00148

0.00148

0.00148

0.00148

Benzo(c)phenanthrene (HAP
195197)

0.0039

0.0039

0.0039

0.0039

0.0039

0.0039

Benzo(e)pyrene (HAP 192972)

0.00266

0.00266

0.00266

0.00266

0.00266

0.00266

Benzo(ghi)perylene (HAP 191242)

0.00508

0.00508

0.00508

0.00508

0.00508

0.00508

Benzo(k)fluoranthene (HAP
207089)

0.0026

0.0026

0.0026

0.0026

0.0026

0.0026

5-11

-------
HAP

Flaming

Smoldering

Region 1

Region 2

Region 3

Region 1

Region 2

Region 3

Benzofluoranthenes (HAP
56832736)

0.00514

0.00514

0.00514

0.00514

0.00514

0.00514

Carbonyl Sulfide (HAP 463581)

0.000534

0.000534

0.000534

0.000534

0.000534

0.000534

Chrysene (HAP 218019)

0.0062

0.0062

0.0062

0.0062

0.0062

0.0062

Fluoranthene (HAP 206440)

0.00673

0.00673

0.00673

0.00673

0.00673

0.00673

Formaldehyde (HAP 50000)

2.515018022

3.366039247

4.475370445

2.515018022

3.366039247

4.475370445

lndeno(l,2,3-cd)pyrene (HAP
193395)

0.00341

0.00341

0.00341

0.00341

0.00341

0.00341

m,p-Xylenes (HAP 1330207)

0.216259511

0.160192231

0.288346015

0.216259511

0.160192231

0.288346015

Methanol (HAP 67561)

2.306768122

1.974369243

5.036043252

2.306768122

1.974369243

5.036043252

Methyl Chloride (HAP 74873)

0.128325

0.128325

0.128325

0.128325

0.128325

0.128325

Methylanthracene (HAP
26914181)

0.00823

0.00823

0.00823

0.00823

0.00823

0.00823

Methylbenzopyrenes (HAP
65357699)

0.00296

0.00296

0.00296

0.00296

0.00296

0.00296

Methylchrysene (HAP 41637905)

0.0079

0.0079

0.0079

0.0079

0.0079

0.0079

Methylpyrene, fluoranthene (HAP
2381217)

0.00905

0.00905

0.00905

0.00905

0.00905

0.00905

n-Hexane(HAP 110543)

0.048057669

0.024028835

0.064076892

0.048057669

0.024028835

0.064076892

Naphthalene (HAP 91203)

0.486583901

0.398478174

0.650780937

0.486583901

0.398478174

0.650780937

o-Xylene (HAP 95476)

0.07609131

0.050060072

0.100120144

0.07609131

0.050060072

0.100120144

Perylene (HAP 198550)

0.000856

0.000856

0.000856

0.000856

0.000856

0.000856

Phenanthrene (HAP 85018)

0.005

0.005

0.005

0.005

0.005

0.005

Pyrene(HAP 129000)

0.00929

0.00929

0.00929

0.00929

0.00929

0.00929

Styrene (HAP 100425)

0.10412495

0.080096115

0.138165799

0.10412495

0.080096115

0.138165799

Toluene (HAP 108883)

0.344413296

0.398478174

0.45855026

0.344413296

0.398478174

0.45855026

Table 5-9: Wildfire HAP emission factors (lbs/ton fuel consumed) for the 2017 NEI

HAP

Flaming

Smoldering

Region 1

Region 2

Region 3

Region 1

Region 2

Region 3

1,3-Butadiene (HAP 106990)

0.272326792

0.140168202

0.362434922

0.272326792

0.140168202

0.362434922

Acetaldehyde (HAP 75070)

1.678013616

1.908289948

2.240688827

1.678013616

1.908289948

2.240688827

Acetonitrile (HAP 75058)

0.322386864

0.600720865

0.43051662

0.322386864

0.600720865

0.43051662

Acrolein (HAP 107028)

0.512615138

0.582699239

0.684821786

0.512615138

0.582699239

0.684821786

Acrylic Acid (HAP 79107)

0.070084101

0.080096115

0.094112936

0.070084101

0.080096115

0.094112936

Anthracene (HAP 120127)

0.005

0.005

0.005

0.005

0.005

0.005

benz(a)anthracene (HAP 56553)

0.0062

0.0062

0.0062

0.0062

0.0062

0.0062

Benzene(HAP 71432)

0.450540649

1.101321586

0.600720865

0.450540649

1.101321586

0.600720865

Benzo(a)fluoranthene (HAP
203338)

0.0026

0.0026

0.0026

0.0026

0.0026

0.0026

Benzo(a)pyrene (HAP 50328)

0.00148

0.00148

0.00148

0.00148

0.00148

0.00148

5-12

-------
HAP

Flaming

Smoldering

Region 1

Region 2

Region 3

Region 1

Region 2

Region 3

Benzo(c)phenanthrene (HAP
195197)

0.0039

0.0039

0.0039

0.0039

0.0039

0.0039

Benzo(e)pyrene (HAP 192972)

0.00266

0.00266

0.00266

0.00266

0.00266

0.00266

Benzo(ghi)perylene (HAP
191242)

0.00508

0.00508

0.00508

0.00508

0.00508

0.00508

Benzo(k)fluoranthene (HAP
207089)

0.0026

0.0026

0.0026

0.0026

0.0026

0.0026

Benzofluoranthenes (HAP
56832736)

0.00514

0.00514

0.00514

0.00514

0.00514

0.00514

Carbonyl Sulfide (HAP 463581)

0.000534

0.000534

0.000534

0.000534

0.000534

0.000534

Chrysene (HAP 218019)

0.0062

0.0062

0.0062

0.0062

0.0062

0.0062

Fluoranthene (HAP 206440)

0.00673

0.00673

0.00673

0.00673

0.00673

0.00673

Formaldehyde (HAP 50000)

2.515018022

3.954745695

4.475370445

2.515018022

3.954745695

4.475370445

lndeno(l,2,3-cd)pyrene (HAP
193395)

0.00341

0.00341

0.00341

0.00341

0.00341

0.00341

m,p-Xylenes (HAP 1330207)

0.216259511

0.120144173

0.288346015

0.216259511

0.120144173

0.288346015

Methanol (HAP 67561)

2.306768122

2.613135763

5.036043252

2.306768122

2.613135763

5.036043252

Methyl Chloride (HAP 74873)

0.128325

0.128325

0.128325

0.128325

0.128325

0.128325

Methylanthracene (HAP
26914181)

0.00823

0.00823

0.00823

0.00823

0.00823

0.00823

Methylbenzopyrenes (HAP
65357699)

0.00296

0.00296

0.00296

0.00296

0.00296

0.00296

Methylchrysene (HAP 41637905)

0.0079

0.0079

0.0079

0.0079

0.0079

0.0079

Methylpyrene,-fluoranthene
(HAP 2381217)

0.00905

0.00905

0.00905

0.00905

0.00905

0.00905

n-Hexane(HAP 110543)

0.048057669

0.054064878

0.064076892

0.048057669

0.054064878

0.064076892

Naphthalene (HAP 91203)

0.486583901

0.554665599

0.650780937

0.486583901

0.554665599

0.650780937

o-Xylene (HAP 95476)

0.07609131

0.054064878

0.100120144

0.07609131

0.054064878

0.100120144

Perylene (HAP 198550)

0.000856

0.000856

0.000856

0.000856

0.000856

0.000856

Phenanthrene (HAP 85018)

0.005

0.005

0.005

0.005

0.005

0.005

Pyrene (HAP 129000)

0.00929

0.00929

0.00929

0.00929

0.00929

0.00929

Styrene (HAP 100425)

0.10412495

0.11814177

0.138165799

0.10412495

0.11814177

0.138165799

Toluene (HAP 108883)

0.344413296

0.480576692

0.45855026

0.344413296

0.480576692

0.45855026

5-13

-------
DRAFT

Figure 5-4: BlueSky Modeling Framework

For the 2017 NEI inventory, the FCCSv2 spatial vegetation cover was upgraded to the LANDFIRE vl.4 fuel
vegetation cover. The FCCSv3 fuel bed characteristics were implemented along with LANDFIREvl.4 to provide
better fuel classification for the BlueSky Framework. The LANDFIREvl.4 raster data were aggregated from the
native resolution and projection to 200-meter resolution using a nearest-neighbor methodology. Aggregation
and reprojection was required to allow these data to work in the BlueSky Framework.

Outputs from each BlueSky Framework processing stream were aggregated into an annual file. Fires identified as
being over water by FCCS were removed because they produce no fuel consumption in the CONSUME model
and thus no emissions. Emissions for some prescribed burns were proportionally adjusted to account for an
overestimate of duff consumption in CONSUME. Those states in the eastern United States had duff consumption
capped at 5 tons per acre, while those in the west had duff consumption capped at 20 tons per acre.

5.4 Quality Assurance (QA) of Final Results

Different types of QA were generally applied with the different parts of the process described above. The
summary below briefly describes the QA checks used in these processes.

5.4.1 Input Fire Information Data Sets

• Reviewed input data sets to identify data gaps.

• Identified fire incidents that appeared to be double-counted in individual data sets and removed
duplicate records.

• Examined fires with long durations or conflicts between date fields such as start date and report date to
identify fires that may have erroneous dates and made necessary corrections.

• Reviewed fire locations to ensure that they fell within the United States. Obvious errors in data entry
such as the reversal of latitude and longitude were corrected where possible.

• Reviewed large and small fires in each data set for validity.

• Modified distant fires (in different states) with the same names to ensure that the events were not
associated.

5-14

-------
5.4.2 Daily Fire Locations from SmartFire2

Quality assurance actions applied to daily fire locations from SmartFire2 included:

• Checked the location, fire type, duration, underlying fire activity input data, final shape, and final size for
large fire events (i.e., area burned >20,000 acres) to ensure that the results were reasonable.

• Checked large fire events by state and by name, removed duplicate events, and renamed fires as
needed.

• Reviewed large fire events with multiple data sources to ensure that SmartFire2 reconciliation rankings
were correct and produced sensible results.

• Identified and removed fire event duplicates incorrectly created by the SmartFire2 reconciliation
process.

• Checked fire events with large differences between the calculated fire area and the geometric fire area.
Since the shape and area are calculated separately in SmartFire2, a large discrepancy can indicate errors
in reconciliation. For the 2014 NWLFEI, no errors of this sort were identified.

5.4.3 Emissions Estimates

Quality assurance actions applied to resulting emissions estimates included:

• Checked the location of all final fires and emission estimates. Fires falling outside of the United States
were removed. Some fires near the border were retained if fuel information was available in that
location.

• Identified fire records that were incorrectly associated and adjusted fire event size and emissions
proportionally.

• Produced and reviewed summary tables and plots of the 2017 fire inventory data.

• Compared acres burned by state to National Interagency Fire Center (NIFC) data to ensure the summary
values were within reasonable range, knowing that NIFC acres burned tend to be underestimated.

5.4.4 Additional quality assurance on final results

WLF emissions developed using the methods described above were compared to EPA's 2016 estimates, and all
the way back to 2005, since the models used are similar. The spatial (and temporal) patterns seen in the data
correspond to what was expected in 2017. In general, 2017 was a "worse" fire year than many previous years
(including 2016 and 2014) as more acres were burned, so the emissions are expected to be higher in 2017
compared to 2014 and 2016. The trends graphic shown in the next section below (see Figure 5-5 and Figure 5-6)
indicates how the 2017 PM2.5 estimates compare to other years (using similar methods). These trends
represent only the lower 48 states.

5.5 Emissions Summaries

This section shows several graphics and tables that describe emissions of wild and prescribed fires in the 2017
NEI based on the methods discussed above.

In Figure 5-5 and Figure 5-6, the trend in PM2.5 emissions and acres burned is shown from 2006 to 2017. Over
this 12-year time frame similar SF2/BS frameworks were used to estimate these emissions. However, it should
be noted that the estimates are much more robust for NEI years (2008, 2011, 2014 and 2017) since S/L/T
involvement and data acquisition from S/L/Ts is much higher. In addition, year 2016 was generated with limited
national fire information databases. It can be noted from both these graphics that the year to year variability is

5-15

-------
DRAFT

more controlled by wildfire activity. In recent years, however, the amount of prescribed fire activity has been on
the rise as seen in Figure 5-5 and Figure 5-6. At this point, it is unclear whether this is due to true increases in
prescribed fire activity across the US, or whether its increasing due to better and more complete reporting.

Figure 5-5: Annual comparison of PM2.5 emissions for lower 48 states

3,000

2,500

8 2,000

§ 1,500

[o

E

m 1,000

LTI
(N

2

500
0

I

I

2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017

Year

I WF

RX

Figure 5-6: Annual comparison of area burned for lower 48 states

Table 5-10 shows acres burned, PM2.5, NOx and VOC emissions by the states of AK, HI, and all the lower 48
states combined. Alaska has a significant amount of the total acres burned in the US in 2017, and (as evident
from Figure 5-5 and Figure 5-6) 2017 was a generally bad fire year compared to the other 11 years shown in the
trend lines above.

5-16

-------
DRAFT

Table 5-10: CONUS (lower 48 states) and Alaska and Hawaii fire type information for 2017 NEI WLFs

Fire Type

Millions of Acres

PM2.5 (Tons)

NOx (Tons)

VOC (Tons)

CONUS Wildfires

8.67

1,283,871

192,966

3,518,534

CONUS Prescribed

14.54

803,347

164,209

2,037,071

Alaska All

0.67

372,386

37,882

1,061,964

Hawaii All

0.01

936

190

2,478

Total

23.90

2,460,540

395,247

6,620,048

Figure 5-7 and Figure 5-8 show acres burned and PM2.5 emissions for all fires by month in 2017. The total
emissions that result from month-to-month result from a combination of different fuels that burn in different
fires. It is seen that wild fires are more prevalent in the hotter months, and prescribed fires occur more often in
the shoulder months of 2017.

Figure 5-7: Monthly acres burned by fire type for 2017 NEI CONUS Wildland Fires



5



4.5

""t/T



<3J

4

O

ro
c

3.5

o



=

3

£



•—¦

2.5

¦o



O)



c

I—

2

3

QD

1.5

V)

-------
DRAFT

Figure 5-8: Monthly PM2.5 by fire type for 2017 NEI CONUS Wildland Fires

500
450

Tn

= 400

+-1

g 350
o

300

00

| 250
"in

•| 200

S 150

5 100
a.

50
0

123456789 10 11 12

Month

Next, Table 5-11 shows a summary of acres burned and PM2.5 by state, fire type and combustion phase. In
terms of total WLF acres burned, several states are shown to have more than one million acres burned in 2017,
with KS and TX being the highest acres burned states. However, due to the nature of fuels burned and the type
of fire that occurs in the various States, CA and AK are highest for estimated PM2.5 emissions.

5-18

-------
Table 5-11: Summary of acres burned and PM2.5 emissions by state, fire type, and combustion phase

5-19

-------
State

Area (Acres



PM2.5 Emissions (tons)

Prescribed

Wildfire

Total

Prescribed

Wildfire

Flaming

Smoldering

Total

Flaming

Smoldering

Total

Alabama

784,520

19,865

804,385

31,835

5,221

37,055

2,075

297

2,372

Alaska

26,915

647,524

674,439

1,343

47

1,390

229,027

141,969

370,996

Arizona

207,248

430,594

637,841

7,033

5,903

12,937

23,566

8,656

32,222

Arkansas

602,658

33,908

636,566

45,972

9,959

55,931

7,352

1,311

8,662

California

156,371

1,377,051

1,533,422

8,687

4,594

13,280

224,304

108,122

332,426

Colorado

92,125

174,825

266,951

4,343

2,134

6,477

9,711

4,096

13,807

Connecticut

710

264

974

64

10

74

64

12

76

Delaware

1,920

22

1,942

85

25

110

3

0

4

Florida

1,431,895

200,509

1,632,404

50,024

8,413

58,436

12,537

1,521

14,058

Georgia

1,075,287

53,551

1,128,838

38,131

4,782

42,913

5,765

2,683

8,449

Hawaii

5,000

5,865

10,865

357

213

571

347

18

366

Idaho

111,534

695,123

806,657

7,753

3,491

11,244

93,352

40,224

133,576

Illinois

147,286

1,980

149,266

13,616

3,924

17,539

559

178

737

Indiana

47,916

1,251

49,167

3,258

1,158

4,416

207

46

253

Iowa

17,856

9,532

27,387

1,177

352

1,530

1,200

268

1,468

Kansas

2,784,939

421,000

3,205,939

89,153

4,159

93,312

17,529

884

18,413

Kentucky

118,110

23,779

141,889

8,762

1,918

10,680

6,870

1,291

8,160

Louisiana

643,794

16,875

660,670

44,070

10,274

54,344

1,920

272

2,192

Maine

2,349

1,003

3,352

222

70

291

271

115

386

Maryland

11,953

1,961

13,914

564

181

745

186

60

246

Massachusetts

80

368

449

7

2

9

83

45

128

Michigan

34,644

4,827

39,471

1,970

722

2,692

1,203

395

1,598

Minnesota

157,607

9,578

167,185

8,968

5,640

14,608

1,518

1,312

2,831

Mississippi

513,094

20,878

533,972

19,508

3,225

22,732

826

97

922

Missouri

801,412

17,989

819,402

77,657

13,261

90,918

4,624

899

5,523

Montana

133,191

1,056,885

1,190,076

7,942

4,769

12,712

133,093

58,425

191,518

Nebraska

163,474

875

164,348

7,395

1,667

9,062

91

24

115

Nevada

12,836

1,151,120

1,163,955

233

80

314

17,563

1,375

18,938

5-20

-------
56

603

,725

399

,094

627

354

,846

,739

381

	7_

,451

,643

365

,486

,946

12

,274

,804

,161

196

,625

,233

2,282
19,893
91,479
7,491
182,685

140
6,159
172,643
1,525
37,267

2,422
26,052
264,122
9,016
219,953

221
1,175
2,070
574
7,006

71
313
1,043
142
1,708

292
1,487
3,113
716
8,715

41
487
10,950
322
3,551

157,283

13,461

170,744

5,435

2,808

8,243

516

20,800

1,481

22,280

1,539

603

2,142

304

1,079,262

501,268

1,580,530

44,799

6,142

50,942

36,015

203,293

615,390

818,683

16,835

9,465

26,300

151,873

25,551

1,567

27,118

2,295

613

2,908

322

303

31

334

26

29

417,008

13,808

430,816

16,299

4,258

20,556

1,290

82,349

77,052

159,401

4,059

1,136

5,196

12,861

183,020

1,500

184,520

12,901

2,214

15,114

322

1,562,103

711,212

2,273,315

47,970

7,185

55,154

19,796

11,193

240,773

251,966

526

227

753

18,477

1,473

46

1,519

89

32

120

10

140,941

8,006

148,947

7,719

1,776

9,495

1,960

128,978

425,330

554,308

2,420

2,420

83,296

44,206

6,187

50,393

4,246

1,218

5,465

1,813

67,153

738

67,891

3,890

1,013

4,903

145

60,190

104,883

165,072

3,619

1,301

4,920

4,373

14,575,658

9,319,469

23,895,127

665,841

139,466

805,307

1,144,579

5-21

-------
DRAFT

Figure 5-9 and Error! Reference source not found, show 2017 total area (acres) burned and PM2.5 emissions by
state, respectively. It summarizes the data in Table 5-11 in map format. The Southeast states are seen to be
dominated by prescribed fires and the western states by wildfires. This is a typical pattern we see from NEI-to-
NEI. In addition, for acres burned, KS is seen to dominate and for PM2.5 emissions, CA (in the lower 48) is seen
to be dominant.

Figure 5-9: Total 2017 NEI area burned by state

5-22

-------
DRAFT

Figure 5-10: Total 2017 NEI PM2.5 emissions by state

£



Total PM2.5 Emissions

CD	Fire Type

¦	Prescribed tons

H	Wildfire tons

^	50000 tons

PM2.5 emissions per square mile are shown in Figure 5-lland acres burned per square mile are shown in Figure
5-12. The patterns seen correspond to the other graphics and tables shown in this section and are fairly typical
of a given NEI for WLFs.

Figure 5-11: 2017NEI county PM2 e emissions in tons per square mile

2017 NEI Wildland Fire PM2.5 Emissions

tons	per square mile

I	0.000-0.050

H	0.050-0.500

¦I	0.500- 2.000

¦I	2.000- 5.000

¦	5.000 - 10.000

¦	10.000-60.000

-------
DRAFT

Figure 5-12: 2017NEI county area burned in acres per square mile

2017 NEI Wildland Fire Area Burned

acres per square mile

cz

0.00 - 0.05
0.05 - 2.00
2.00 - 5.00
5.00 - 20.00
20.00 - 50.00
50.00 - 375.00

5.6 References

1.	US EPA, 2019. 2016 Emissions Inventory development for Modeling Platform work, 2014-2016 Version 7 Air

Emissions Modeling Platforms

2.	Larkin, N.K., S. M. Raffuse, S. Huang, N. Pavlovic, and V.Rao, The Comprehensive Fire Information Reconciled
Emissions (CFIRE) Inventory: Wildland Fire Emissions Developed for the 2011 and 2014 U.S. National
Emissions Inventory, submitted to JAWMA, Dec 2019.

3.	Larkin, N.K., S.M. O'Neill, R. Solomon, C. Krull, S. Raffuse, M. Rorig, J. Peterson, and S.A. Ferguson. 2009. The
BlueSky smoke modeling framework. International Journal of Wildland Fire, 18, 906-920

4.	Urbanski S.P. (2014) Wildland fire emissions, carbon, and climate:: emissions factors. Forest Ecology and
Management, 317, 51-60.

5-24

-------