EPA/600/R-19/092 | September 2019 | www.epa.gov/research
The Federal LCA Commons Elementary Flow
List: Background, Approach, Description and
Recommendations for Use
FEDERAL
COMMONS
Flowable
Context
Unit
Flow UUID
Phorate
emission/water/brackish water
kg
8b3da12-bebd-3b2 9
Flubendiamide
eml 3 a i on/ ground/ human-dominate
kg
31f4fldb-58be-30cl
Chlorantranil
emission/water/fresh water
kg
4cS0S58e-5ae4-3abc
Qcthilinone
emission/ground/terrestrial/sh
kg
a39674aa-8df2-3add
Acetamiprid
emission/water/saline water
kg
083667b&-5 813-3cf7
Imazaquin,
emission/air
kg
73c40d5-35ef-3f74
<2E)-2-Hepten
emission/air/troposphere/rural
kg
fd88fl8-2dcd-3a0
N-Benzyladeni
emission/air/troposphere/urban
kg
9c711all-eb3a-32b5
Flavone
emi33ion/water/subterranean/br
kg
2a30bd9e-ddb5-3a81
Caprolactam
emission/water/subterranean/br
kg
ece4afa4-331f-3135
Boron
emission/ground/terrestrial/ba
kg
6c8e4b09-3dfl-3e5
Benzene,
emission/air/troposphere/very
kg
ffd48773-a713-3ce4
Poly (iminoimi
emission/water/fresh water
kg
fc8722d-4215-343
Naphthalene,
emission/air/troposphere/urban
kg
35335a0a-S2a3-3afl
Hethylanthrac
emission/air/troposphere/urban
kg
d3b9d53f-ba88-3fd8
Furans,
emis3ion/water
kg
bed8d84c-3984-3c5b
Ethylene
emission/air/stratosphere
kg
e650clc0-4e37-3f5f
2,4-Dichlorca
emission/air/troposphere/rural
kg
3af8b87a-bc9a-31ff
c/EPA
United States
Environmental Protection
Agency
Office of Research and Development
National Risk Management Research Laboratory
Land and Materials Management Division
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Federal LCA Commons Elementary
Flow List:
Background, Approach, Description
and Recommendations for Use
by
Ashley Edelen, Troy Hottle, Sarah Cashman
Eastern Research Group
Wesley Ingwersen
U.S. EPA/National Risk Management Research Laboratory/
Land and Materials Management Division
ii
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Notice/Disclaimer
Although the U.S. Environmental Protection Agency, through its Office of Research and
Development, funded and conducted the research described herein under an approved Quality
Assurance Project Plan (Quality Assurance Identification Number G-LMMD-0031522-QP-1-0),
with the support of Eastern Research Group, Inc. through EPA Contract Number EP-C-16-015, it
does not necessarily reflect the views of the Agency, and no official endorsement should be
inferred. Mention of trade names or commercial products does not constitute endorsement or
recommendation for use.
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Foreword
The U.S. Environmental Protection Agency (U.S. EPA) is charged by Congress with protecting
the Nation's land, air, and water resources. Under a mandate of national environmental laws, the
Agency strives to formulate and implement actions leading to a compatible balance between
human activities and the ability of natural systems to support and nurture life. To meet this
mandate, U.S. EPA's research program is providing data and technical support for solving
environmental problems today and building a science knowledge base necessary to manage our
ecological resources wisely, understand how pollutants affect our health, and prevent or reduce
environmental risks in the future.
The National Risk Management Research Laboratory (NRMRL) within the Office of Research
and Development (ORD) is the Agency's center for investigation of technological and
management approaches for preventing and reducing risks from pollution that threaten human
health and the environment. The focus of the Laboratory's research program is on methods and
their cost-effectiveness for prevention and control of pollution to air, land, water, and subsurface
resources; protection of water quality in public water systems; remediation of contaminated sites,
sediments and ground water; prevention and control of indoor air pollution; and restoration of
ecosystems. NRMRL collaborates with both public and private sector partners to foster
technologies that reduce the cost of compliance and to anticipate emerging problems. NRMRL's
research provides solutions to environmental problems by: developing and promoting
technologies that protect and improve the environment; advancing scientific and engineering
information to support regulatory and policy decisions; and providing the technical support and
information transfer to ensure implementation of environmental regulations and strategies at the
national, state, and community levels.
Alice Gilliland, Acting Director
National Risk Management Research Laboratory
iv
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Abstract
Elementary flows are a foundational component of the life cycle assessment data model, used to
represent resources and emissions that are used or released in human and industrial activities.
They enable the development of life cycle inventories and the subsequent application of life
cycle impact assessment methods to model potential impacts associated with product systems.
This report describes the development of a standardized elementary flow list (FEDEFL) for the
Federal LCA Commons. Introduction and Background sections describe relevant history of
elementary flows in life cycle data, the purpose of a FEDEFL, and a technical background on
elementary flows. An Approach section describes the steps toward creating the FEDEFL and
mapping files to convert flows from other sources to FEDEFL flows. It includes the definition of
flow classes and flow components - flowables, contexts, and units - and describes the assembly
of the components into a flow list using a new Python package,fedelemflowlist. fedelemflowlist
also provides the FEDEFL and mappings to Python users and creates a version of the list for use
in openLCA software. A brief summary of the resulting vl.O of the FEDEFL is provided in a
Summary section, followed by general and flow class specific Recommendations for Use. Flows
are anticipated to be regularly added to the FEDEFL to cover emerging life cycle data needs, and
its functionality periodically enhanced as LCA modeling needs and capabilities continue to
evolve. A system for updating the FEDEFL has been developed through GitHub and is described
in Future Work and Contributing. Related files and resources including the FEDEFL on the
Federal LCA Commons, the fedelemflowlist package and associated Wiki, and documentation of
usage of the mapping files in openLCA software, are briefly described and links are provided.
The FEDEFL will play a critical role in enabling interoperability between life cycle datasets
created by federal agencies and can also serve as a standard for elementary flows for a broader
community.
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Acknowledgements
This report was developed as a part of the Federal LCA Commons Technical Working Group.
This work included the consultation of different federal agency LCA subject matter experts and
their support contractors.
Ezra Khan from the National Agricultural Library, USD A supported the development of
'Biological' flows with the National Agricultural Library glossary. Richard Bergman and ORISE
Fellow Sveda Alanya-Rosenbaum at the US Forestry Service were also consulted on 'Biological'
flows concerning the development of wood and forestry products.
In the development of the 'Geological' flows related fuels and 'Energy' terms, relationships and
definitions, Michele Mutchek and Michelle Krynock, Key Logic contractors to DOE's National
Energy Technology Laboratory (NETL) provided valuable feedback and support for the
development of the conversion factors and alternate units. In addition, Graham Lederer from
USGS provided support for the structuring and development of non-fuel based 'Geological'
terminology.
Jane Bare and Briana Niblick from the U.S. EPA along with Andrew Henderson as contract
support for the DOD provided support for the structuring and development of the secondary flow
context metadata that is supported by the TRACI 2.1 impact assessment method. Jane Bare also
provided guidance and support for the structuring of the 'Other' flow class.
Ranjani Theregowanda as an ORISE Fellow with the U.S. EPA provided support for the
structuring of the 'Water' flow class, primary flow context information associated with water
environmental media and secondary flow class information associated with water bodies and
aquatic features.
Other members of the Technical Working Group provided feedback related to use of earlier
versions of the flow list in the LCA context, including Rebe Feraldi as contract support for
DOE's National Renewable Energy Laboratory, Michelle Krynock as contract support for NETL
and Troy Hawkins from Argonne National Laboratory. Rebe Feraldi and Michelle Krynock also
completed a thorough review of this report.
vi
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e of Contents
1 Introduction 11
1.1 Elementary flows in the global and U.S. contexts 11
1.2 Purpose 13
1.3 Relationship to other documents/resources 13
2 Background 14
2.1 Flow components 14
2.2 Flow classes 15
2.3 Flow nomenclature 16
2.4 Use in life cycle data and software 17
3 Approach to Creation of the Flow List and Mappings 18
3.1 Flow components 18
3.2 Flow classes 18
3.3 Flow contexts 19
3.4 Flow units 21
3.4.1 Flow unit conversions 22
3.5 Flow nomenclature 22
3.5.1 Context nomenclature 23
3.6 Flowables 23
3.6.1 Element or Compound and Groups of Chemicals 24
3.6.2 Biological 25
3.6.3 Energy 26
3.6.4 Geological 26
3.6.5 Land 26
3.6.6 Other 27
3.6.7 Water 27
3.7 Flow mapping 27
3.8 Flow preference 29
3.9 Flow list assembly 29
4 Summary of the Flow List, vl.O 31
5 Recommendations for Use 32
5.1 General guidance 32
5.1.1 General guidance for new life cycle data 32
5.1.2 General guidance for existing LCA data 33
5.2 Class specific usage 34
5.2.1 Biological 34
5.2.2 Element or Compound 34
vii
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e of Contents (Continued)
5.2.3 Energy 35
5.2.4 Geological 35
5.2.5 Groups of Chemicals 36
5.2.6 Land 37
5.2.7 Other 37
5.2.8 Water 37
6 Future Work and Contributing 38
7 References 39
Appendix A - Supporting Tables
viii
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List of Figures
Figure 1. Compartment classification of primary and secondary flow context 20
Figure 2. Defining the nomenclature type of flow components 23
Li lies
Table 1. Flow Class System from Edelen et. al (2018) 16
Table 2. FEDEFL Flow Classification System 18
Table 3. Flowable Mapping with Match Condition Examples 28
Table 4. Flowable Summary for FEDEFL vl.O 31
Table 5. Flow Summary for FEDEFL vl.O 31
Table 6. Guidance for Common Associated Minerals 35
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Acronyms and Abbreviations
CAS
CEC
DADQ
DMR
DOE
ECO
EF
FEDEFL
GLAD
HHV
ISO
LCA
LCI
LCIA
NALCMS
NEI
NETL
NPDES
NREL
UNEP
USD A
ORISE
RCRA
SRS
StEWI
TRACI
TRI
TWG
UNEP/SETAC
USEPA
USGS
UUID
VOC
Chemical Abstracts Service
Commission for Environmental Cooperation
Data Availability and Data Quality
Discharge Monitoring Report
United States Department of Energy
Earthster Core Ontology
Elementary Flow
Federal LCA Commons Elementary Flow List
Global LCA Data Access initiative
Higher Heating Value
International Organization for Standardization
Life Cycle Assessment
Life Cycle Inventory
Life Cycle Impact Assessment
North American Land Change Monitoring System
National Emissions Inventory
National Energy Technology Laboratory
National Pollution Discharge Elimination System
National Renewable Energy Laboratory
United Nations Environment Programme
United States Department of Agriculture
Oak Ridge Institute for Science and Education
Resource Conservation and Recovery Act
Substance Registry Services
Standardized Emissions and Waste Inventory
Tool for Reduction and Assessment of Chemicals and other environmental
Impacts
Toxic Release Inventory
Technical Working Group on Federal LCA Data Interoperability
United Nations Environment Programme/Society of Environmental Toxicology
US Environmental Protection Agency
United States Geological Survey
Universally Unique Identifier
Volatile Organic Compounds
Chemical Symbols
C02
N2O
Carbon dioxide
Dinitrogen oxide
x
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1 Jin
Organizations increasingly need to understand the environmental impacts of their products and
processes so they can effectively target efforts to minimize environmental burdens and maximize
resources. Life cycle assessment (LCA) provides a comprehensive 'cradle-to-grave' modeling
method to determine the environmental impacts of goods or services. LCA is often used by
organizations to compare environmental impacts of alternative product options on an equivalent
basis and to ensure impacts are not simply shifted to upstream or downstream life cycle stages.
While LCA can be a very powerful tool, it is data intensive and standardized methods are needed
to combine data from multiple sources. Sources that LCA models are built from generally
include a mix of existing databases and datasets that provide background life cycle inventory
(LCI) data on energy, transportation and commodity materials coupled with primary data
collected by the study team. Data sharing and exchange are also common practices in the LCA
field, and standardized data formats are required to ensure no content is lost and no existing
models are adversely affected during this transition. Significant efforts on LCA data sharing and
interoperability have been made by the international community through the United Nations
Environment Programme (UNEP) Life Cycle Initiative. Within the U.S., there are joint efforts
between federal agencies such as the Federal LCA Commons to improve LCA data
interoperability, while maintaining user autonomy through developments in database platform
architecture and guidance for data quality management, metadata descriptors, and nomenclature
(further described in Section 1.1). The objective of this project is to provide guidance on
standard LCA nomenclature and its associated structure.
'Flows' are the essential components of data used for LCA. Flows may be of two broad types:
elementary flows (EFs) or intermediate (known as "technosphere") flows according to the
International Organization for Standardization (ISO) 14044 (ISO14044, 2006). EFs may be
defined as materials, energy, or space that are taken directly from the environment or released
directly back into the environment. EFs are the key flows in calculating final LCA results
because they are the basis for impact assessment, while intermediate flows are used to connect
flows within the full LCA model for the end goal of determining aggregate life cycle EF values
per stage. Various conventions exist for naming (nomenclature), categorization, using, and
storing EFs in LCA data, which causes inconsistencies in use and implementation of EFs when
using data from multiple sources. This is both a problem for human readability and use, as well
as a problem for machine management of these data in LCA software and databases, both of
which are critical to LCA data interoperability. The focus of this work is, therefore, to develop a
standardized EF structure and guidance for using this structure in LCA modeling across federal
agencies.
if 11 t If'"-Eli'*iit-iie ' flow* in fh ',.L ball airii'' f f.',« contexts
The development of LCA methods and guidance materials and the information architecture
supporting LCA has been driven by both international and national communities. This section
11
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offers a brief history of work related to EFs to better describe the historical developments that
influenced the EF framework proposed in this guidance.
In 2002, the launching of the UNEP Life Cycle Initiative created an international platform under
which organizations, scientists and government entities could cooperate to further contribute to
LCA development. The publication the following year in 2003 of the Code of Life-Cycle
Inventory Practice (de Beaufort-Langeveld, et al., 2003) distributed the collaborative guidance
by five working groups. This included a recommended list of flows by the Data Availability and
Data Quality (DADQ) working group. Desiring to preserve the autonomy of the user, the DADQ
working group opted to provide a list of parameters with the preferred nomenclature. They also
proposed a hierarchical concept for capturing additional flow information, or what this guidance
calls flow context information (de Beaufort-Langeveld, et al., 2003). ISO has also guided the
development of LCA through the ISO 14000 series. The ISO 14048 standard provides LCA
nomenclature (ISO/TS 14048, 2002). In the 2000's, large LCI databases emerged, multiple LCA
software tools were spawned, and LCI A methods proliferated, generally each using their own EF
lists. Thus, despite the earlier guidance and international standards, a common universal flow list
did not emerge.
In 2014, an intergovernmental group meeting regularly on LCA cooperation launched an
initiative to create a global LCA network, called the Global LCA Data Access (GLAD) initiative.
Data interoperability and exchange were established needs of GLAD. Three technical working
groups were established as a part of the GLAD initiative: Network Architecture and Technology,
Nomenclature, and Metadata Descriptors. As a part of the Nomenclature working group, a
critical review of current EF usage was conducted and the resulting recommendations by Edelen
et. al (2018) have been used as the foundation for this work. The analysis of EFs by Edelen et. al
(2018) shows that there is still a need for further EF standardization to have machine readable,
harmonized interoperable data for LCA.
On a parallel track, at the federal level within the U.S., there have also been significant
developments within LCA. In 2014, technical LCA experts at federal agencies formed the
Technical Working Group (TWG) on Federal LCA Data Interoperability to further discuss and
collaborate on harmonization of LCA data and practice among U.S. government agencies. The
group steers an initiative called the Federal LCA Commons, whose primary goal is to provide
interoperable LCA data developed or sponsored by Federal agencies via a common data portal
(US Department of Agriculture, US Environmental Protection Agency and US Department of
Energy, 2018). The TWG is referred to herein as the Federal LCA Commons TWG or just TWG.
The Federal LCA Commons portal1 is now available and continues to grow and evolve
(McCarthy & Cooper, 2012). The TWG tested whether LCI data from U.S. federal sources could
be used together within standard LCA software. These tests revealed issues such as lack of
common EFs that need to be overcome before federal LCI data is truly interoperable (Ingwersen,
W.W., 2015). The TWG, defined as part of its annual work plan in 2017 and 2018 the
1 Available at: http://www.tcaeonimons.eov/lca-coHaboration (Accessed 8/2/19).
12
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development of a common EF list to provide greater standardization and interoperability for
federal LCA data.
1.2 Purpose
The main purpose of this report is to describe the creation of a common EF list for use in federal
LCI and LCI A data (henceforth referred to as "FEDEFL"). The FEDEFL:
Covers all elementary flows currently used and expected to be used in LCI and LCIA
data for the Federal LCA Commons
Uses terms and lists defined or adopted by authoritative U.S. or international sources
Addresses problematic issues with existing EFs identified in Edelen et al. (2018)
Structures and defines every term used
Functions for use in the LCA software currently underlying the Federal LCA
Commons data portal, openLCA
Facilitates usage with existing LCA data through mappings from external source
flows to FEDEFL flows
Is created using a software package such that it can be regularly updated at intervals
determined by the Federal LCA Commons technical working group
1.3 Relatior _ documents/resources
This document is supported by the following online repositories and documents:
1. A repository2 for the fedelemflowlist Python package, management of the FEDEFL,
and a documentation Wiki. fedelemflowlist is a Python 3.x package for generating the
FEDEFL from the various input files and the flow mapping files described in this
report and exporting those into a .zip archive of openLCA JSON-LD format files. The
module allows Python users to access the FEDEFL and flow mappings for use in
dynamic applications. The Federal LCA Commons community will use the GitHub
functionalities associated with the repository to manage the FEDEFL, including
providing updates and review of the input files, and creating releases for updates. See
the Wild2 for more information.
2. The preferred flows are available via the Federal LCA. Commons Data Portal1 as part
of the Federal LCA Commons Core Database. Instructions on how to use the
FEDEFL to prepare LCA data for the Federal LCA Commons are included in the
Data Submission Guidelines.
2 U.S. EPA GitHub Federal LCA Commons Elementary Flow List Repository. Available at:
https://githnb.com/USEPA/Federal-LCA-Commons-Elementare-Flow-List/wiki (Accessed 8/2/19).
13
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3. All terms found within the FEDEFL are defined within a vocabulary made available
via the 'erminology Services3 (U.S. EPA, 2019a) or within the U.S. EPA's
Substance Registry Services4 (U.S. EPA, 2019b).
4. The FEDEFL and mappings can be used in the open-source openLCA software5
(GreenDelta, 2018). New functionality has been added in openLCA vl.9 to use the
flow mappings to convert flows originally from other sources to the FEDEFL flows,
if the user has source flows present in an openLCA database. A separate document6
describes the use of this new functionality in openLCA.
5. The Iciafmt7 Python package can create LCIA methods that use the FEDEFL flows
and write them to a .zip archive of openLCA JSON-LD for use in LCA software. As
of finalization of this report, this package is still in development.
2
This section provides a technical background on EF components, classification, nomenclature,
and usage in LCA data and software.
2.1 Flow components
EFs must have three components to identify them (Edelen, et al., 2018):
1. Flowable - The name of the material, energy, or space (e.g., "Carbon dioxide" or
"freshwater") that comes from or goes to the biosphere. This is commonly called
"substance" or "flow name" but this term is too limited and the term "flowable" from
the Earthster Core Ontology (ECO) is used in this report and in the FEDEFL
(McBride & Norris, 2010).
2. Context - A set of environmental media/compartments that describe the flow origin
or destination (e.g., "air"). Although the term compartment is sometimes used in
LCA, the FEDEFL uses the term context to provide a broader meaning that includes
the directionality (e.g. "resource" from biosphere or "emission" to biosphere),
environmental media (e.g. "air", "water", "ground" and "biotic"), and additional
context information that is further described in Section 3.3.
3 U.S. EPA Terminology Services. Available at:
https://iaspub.epa.gov/sor interne t/registrv/termreg/searchandretrieve/termsandacronvms/search.do (Accessed
8/2/19).
4 U.S. EPA Substance Registry Services. Available at:
https://iaspnb.epa.gov/sor interne t/registrv/substreg/LandingPage.do (Accessed 8/2/19).
5 openLCA software. Available at: http://www.openlca.org (Accessed 8/2/19).
7 LCIA formatter. https://githnb.com/nsepa/LCIAfonnatter
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3. Unit - Flow units may be associated with conversion factors that can be used to
convert between different units within a flow property (e.g., kg to lbs.) or even
between flow properties (e.g., kg to m3).
Each of these individual flow components may be associated with more information, or
metadata, in part dependent on what type of flow it is. For instance: flowables, if chemicals, may
have a Chemical Abstracts Service number (CAS No.) and be associated with various other
intrinsic properties. Other types of flows, like land use or energy inputs, may not have this
additional information. Flows at a minimum should have a flowable, context and unit, and the
unique combination of these components may be considered a unique flow, but whether or not it
is unique has in practice been determined by the system in which it is used, such as the specific
LCA software. Within LCA software, ID numbers are used to track unique flows and flow
components. Such IDs are critical elements for identifying flows when incorporating them in
LCA software. A universally unique identifier (UUID) is a common form of ID used in LCA
data such as the Ecoinvent and GaBi databases and LCA software such as openLCA
(GreenDelta, 2018).
2.2 Flow classes
Edelen et. al (2018) developed flow classes as an additional piece of flow metadata to improve
the structure used to organize flows. Flow classes are a way to group EFs by their flowable type.
Classes may have sets of contexts and units that distinguish them from flows in other classes.
Table 1 is the original flow classification created by Edelen et. al (2018).
15
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Table 1. Flow Class System from Edelen et. al (2018)
Input/
Type
Output
Definition
Example Name(s)
Element or
Output
A unique chemical element or
1,1,2,2-Tetrachloroethane
compound
compound
Group of chemicals
Output
A group or mixture of chemicals
Volatile organic compounds,
unspecified
Mineral, metal or
Input
A mineral or metal in an ore or
Copper, 0.52% in sulfide, Cu 0.27%
aggregate
aggregate material extracted for use or
refining
and Mo 8.2E-3% in crude ore, in
ground
Biological
Input
Biomass or organic matter
Wood, hard, standing
Land
Input
Occupation of transformation of land
Occupation, arable, non-irrigated,
diverse-intensive
Transformation, from forest
Water
Both
Water
Water, well, in ground
Fossil or Nuclear
Input
A fuel source
Coal, hard, 20 MJ/kg
Fuels
Energy
Input
Energy input not associated with
materials
Energy, from geothermal
Other
Both
None of the above. May include water
quality parameters; waste heat; solid
waste; noise
Heat, waste
BOD
Solid waste
2.3 Flow nomenclature
Use of a common or easily shared nomenclature is a systematic way to provide consistent
descriptors in scientific fields or other fields where data are organized and shared. A
nomenclature is a system for naming entities within a realm of knowledge (Universty Press
Oxford, 2016). Codified methods for the naming of flowables and contexts may be considered
EF nomenclatures. Ideally, this common nomenclature would be used by all LCA data sources so
names for flowables and contexts would be harmonized and easily corresponded across datasets.
The ISO 14048 standard provides LCA nomenclature guidance that also applies to EFs. ISO
14048 establishes three types of nomenclature: exclusive, inclusive, or user-defined (ISO/TS
14048, 2002). Exclusive nomenclature cannot be expanded by users as only specific terms are
valid. ISO 14048 requires exclusive nomenclature for the directionality and receiving
environment (compartment) for flows. Inclusive nomenclature may be expanded by the user
when necessary for a specific application. ISO 14048 recommends that further receiving
environment specification information be an inclusive nomenclature. User-defined nomenclature
may be adapted as the user sees fit. The United Nations Environment Programme/Society of
Environmental Toxicology (UNEP/SETAC) recommended list of parameters can be viewed as a
user-defined nomenclature with guidelines (de Beaufort-Langeveld, et al., 2003).
A review of current EF nomenclature revealed that current guidance has been inadequate in
addressing several types of challenges that contribute to duplicate and/or extraneous flows
16
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(Edelen, et al., 2018). There may be discrepancies in application of the nomenclature resulting in
differences in the names and contexts and minor differences such as extra spaces or commas.
Lack of harmonization in application of a nomenclature causes disconnect between flows. As an
example, one dataset may contain the use of a flow with the flowable "Nitrous oxide (N2O)"
while another may have a flowable with the name "Nitrous oxide", with otherwise the same
contexts, units and metadata. These flowables refer to the same chemical (N2O) but LCA
software would interpret these as two independent flows. Furthermore, even "CO2" and "C02
may be identified as different entities due to use (or non-use) of subscripts.
2.4 Us ta and software
There are two main subparts of the LCA data model where EFs are used, LCI and life cycle
impact assessment (LCIA). EFs are used in LCI to represent what is being exchanged between
the biosphere and technosphere such as a raw resource (e.g., groundwater) consumed in a
process and exchanges between the technosphere and biosphere with a process such as emissions
of pollutants and other materials into the environment. LCIA methods enable the translation of
uses of resources or releases in the environment into estimation of potential environmental
impacts. EFs appear in LCIA method data, where flows are associated with characterization
factors (units of impact per unit of flow) for estimating the potential impact of a given unit of a
particular EF. The calculation of impact assessment results using data from an LCI (the
fundamental accounting of a product system's EFs) and characterization factors from an LCIA
method requires that the EFs in these LCA data model subparts correspond or match.
As data for LCI and LCIA are generally created by independent providers and LCA software
developers create software to accommodate multiple LCI and LCIA sources, LCA software
developers may develop their own lists of EFs, resulting in different sets of EFs being present in
in all sources. EF matching between LCI and LCIA datasets in LCA software is not guaranteed.
The responsibility for this EF matching across data sources within LCA software has been the
unsaid responsibility of software providers, without external oversight or requirements for any
documentation of validation of this flow matching and harmonization (Lesage, 2015).
The differences in EFs from these sources can create issues for LCA data exchange. If EFs are
not identified by an authoritative ID that is used to identify an EF across all sources, and/or data
exchange methods do not capture and use these unique IDs along with flow metadata, then EF
identities or information will be lost in the data exchange.
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3 Approach to Creation of the Flow List and Mappings
The approach to the creation of the FEDEFL builds on the recommendations of the GLAD
network critical review Edelen et. al (2018), and incorporates the anticipated modeling needs of
federal agencies participating in the Federal LCA Commons TWG. The steps for creating the
FEDEFL include defining flow list components, creation of flow classes, definition of a flow
nomenclature, development of flow contexts and units, selection of flowables, identification of
preferred flows, and defining a method of flow list assembly. Experts were consulted throughout
the process in order to obtain discipline-specific insight to structuring and naming flows for each
flow class.
3.1 Flow components
A common list of flow list components and associated metadata was defined. Flowables,
contexts, and units are the primary components of each flow. Flows are organized into classes. A
flow as a whole may have an external reference like a URL, and must have a unique ID number.
The development of these components is described in depth in the following sections.
3.2 Flow classes
The classification of flows allows for a more systematic approach to the creation of the FEDEFL.
The initial classification system proposed by Edelen et. al (2018) was modified and a re-
organization of the flows based on the newly proposed classification system is shown in Table 2.
The flow classes proposed by Edelen et. al (2018) are used with a minor change, the removal of
the 'Fuels' class. It is the position of this guidance that classifications by the activity, such as a
'Fuels' class, should not be used and the nine-class system proposed by Edelen et. al (2018) has
been updated to the following eight-class system.
Table 2. FEDEFL Flow Classification System
Example Name(s)
Input
Common
or
flow
Flow Class
Output
Definition
properties
Element or
Compound
Both
A unique chemical element or
compound
Mass
1,1,2,2-Tetrachloroethane
Groups of
Chemicals
Output
A group or mixture of chemicals
Mass
Volatile organic compounds
Geological
Both
A mineral or metal in an ore or
aggregate material extracted for use
or refining3
Mass or
Energy
Anthracite
Biological
Both
Input: Biomass or organic matter3
Mass
Hardwood
Output: biological matter (e.g.
microorganisms, animal dander,
house dust, mites and pollen)
Mass
Bacillus Subtilis
18
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Flow Class
Input
or
Output
Definition
Common
flow
properties
Example Name(s)
Land use
Input
Land types
Area*time
Forest
Water
Both
Water3
Mass
Water, fresh
Energy
Input
Energy input NOT associated with
consumed materials including heat
Energy
Energy, Geothermal
Other
Both
None of the above. May include
water quality parameters; solid
waste
Biological Oxygen Demand
Total Organic Carbon
a All materials that can be used as fuels, such as crude oil. coal, wood, biomass, etc. and water flows include a default
conversion factor for an alternate unit (i.e., 'Anthracite' has a default conversion factor from mass to energy or
'Freshwater' has a conversion factor mass to volume). Further recommendations for appropriate usage of conversion
factors within LCA can be found in section
3.3 Flow contexts
Flow context is divided into two parts, primary and secondary. Primary context information
includes the flow directionality (resource or emission) and environmental media (air, water,
ground or biotic). A flow is required to have both primary context compartment classes to be
included into the FEDEFL. Secondary context information consists of eight compartment classes
arranged in the following hierarchical structure (See Figure 1). Human-dominated and Terrestrial
are also considered compartment classes even though they exist under the Land class. Secondary
context information is not applicable to all flow classes; however, recommended or preferred
secondary flow context information has been established for each of the different flow classes.
Secondary flow context information by compartment is shown for each flow class + primary
flow context (directionality + environmental media). Each flow class + primary flow context can
have more than one preferred set of secondary context information. For example, chemical
emissions to air have secondary primary context information for outdoor emissions and indoor
emissions. Initially, the environmental media compartment was limited to three compartments;
air, water and ground. However, when discussing 'Biological' flows the environmental media
from which these types of flow originate is not adequately addressed by these terms and the term
biotic was included as an environmental media.
Flow Class
Flowable
Flow Context (Primary)
Biological
Hardwood
Resource, biotic
Biological
Biomass
Resource, biotic
19
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"" Primarv Context
r
Directionality
Environmental
Media
I 1 I I I L
Resource ¦ Emission
Water
Ground
r
Secondarv Context
Vertical Strata
Population
Density
Stratosphere Troposphere Surface Subterraneanl | Terrestrial I |wSy|"i Ind°0r |outdOOr| Urban Rural
Unconfined
Aquifer
>
n r
Low I High I Very High
j
Figure 1. Compartment classification of primary and secondary flow context.
20
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Previously, the environmental media compartments were used not only to refer to the
environmental media, but also the vertical strata of a flow. For example, a resource flow from a
groundwater well would have conventionally had ground as the media. However, ground more
accurately describes the vertical strata from which the resource is extracted, while the
environmental media from which the resource is flowing is water. Therefore, in the FEDEFL the
terms air, water and ground refer to the media, while another compartment class is used to
describe the vertical strata. This is the first time these two compartment classes are used to
clarify the difference between environmental media and vertical strata. Primary context
information is not detailed enough to adequately capture the necessary information to connect
LCI data to LCIA methods; therefore, based on LCA practitioner feedback, the secondary
context information was developed.
A new approach for the secondary context information was used for the classification of land
use. The nomenclature of land use context is based on the North American Land Change
Monitoring System (NALCMS), but simplified for LCA use as some terms were overly specific
and not applicable to current LCA data. This system was chosen because it uses land cover in
development of the nomenclature. The structure of the land use compartment class provides
additional clarity by distinguishing water body types from land use types, as waterbodies are not
land. Land use compartment classes are separated by human dominated and natural land cover
types. In addition, the novel concept of addressing waterbody types by salinity is introduced.
Vertical strata as a compartment class is introduced to further clarify the difference between
environmental medias and vertical strata. Also, the new atmospheric terms in the vertical strata
compartment class allow for LCA emissions outside of the troposphere to be included. Any
emissions not assigned a specific vertical stratum are by default considered to be emissions at the
earth's surface level.
The release height compartment class is based on LCIA nomenclature specifying the height of
emissions to air within the troposphere. Stack heights are defined as <25m, >25 to 150m, and
>150m for low, high, and very high, respectively (Humbert, et al., 2011) (U.S. GAO, 2011). The
indoor compartment class consists of only one compartment, while all other emissions not
assigned the indoor compartment are assumed to be outdoors. The default release height is
ground-level and the release height compartment should only be used for situations where stack
height is known.
The population density compartment class is based on the population per square mile found in
(Humbert, et al., 2011). 'Urban' is defined as an area with a population density of >390 people
per square kilometer or >1000 people per square mile, and 'rural' as areas with lower population
density. Users should be aware that the definitions offered by Humbert, et al. (2011) differ from
those used by the U.S. Census Bureau (US Census Bureau, 2018).
¦ * It k riftli
A reference unit is defined for each flowable. SI units are used exclusively for all units. As a
source of units, the FEDEFL uses a more recent list of units in openLCA software (GreenDelta,
21
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2018). For those flowables that may have more than one property (e.g. 'Mass', 'Volume'), an
alternate flow unit is declared, along with a default conversion factors in the form of alternate
unit per reference unit.
3.4.1 Flow unit conversions
As stated above, certain flows may have more than one property, which requires flow unit
conversion. For example, geological flowables that are used as fuels require a conversion factor
from mass to energy or water flowables may need to be converted from mass to volume
depending on use. Default conversion factors are sourced from federal data sources or other data
sources when federal reference values are not available.
" t low nomencf .n-r
This work used the nomenclature framework established by ISO 14048, Section 7.1, to build the
proposed EF nomenclature found within this guidance (ISO/TS 14048, 2002).
The FEDEFL master list increases the clarity of the individual flow and metadata components
associated with a flow by not only clearly defining the components, but also by applying the ISO
14048 series types of nomenclature to each of the flow and metadata components. As described
previously, there are three types of nomenclature; exclusive, inclusive and user defined. The
nomenclature type of flow components in the FEDEFL is defined in Figure 2.
The CAS No. and the chemical formula are defined and maintained by an external source and
thus considered an externally-defined inclusive nomenclature. The FEDEFL framework applies
the concept of exclusive nomenclature to the flow class, flow property, primary context, and
corresponding UUIDs. For each of these components a predetermined and defined set of terms
has been provided. For example, the directionality of a flow can only be 'Resource' or
'Emission' no other terms are acceptable. Due to the exclusive nature of the flow class, flow
property and primary context the UUIDs for each of these components are also exclusive. The
elementary flowables, the secondary context, and unit converters are all considered inclusive
nomenclature that will be managed by the Federal LCA Commons. The flow list version
identifier will also be an inclusive nomenclature managed by the Federal LCA Commons. The
description and synonyms are not structured or controlled at this time and are therefore, user
defined nomenclatures.
22
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Flow
Clarifier
Primary Context
Property
Secondary Context
Identifier
Unit Converter
General Information
Flowable (Name)
PM10
Alternative Unit
NA
Conversion Factor
NA
Class
Group of Chemicals
Unit
Synonyms
NA
CAS No.
NA
Formula
NA
Flow List Version Identifier
v1.0
Description
NA
Directionality
Emission
Environmental Media
Federal LCA Commons
Elementary Flow Master
List, v1.0
Vertical Strata
Troposphere
Land Use
NA
Indoor
NA
Population Density
Urban
Release Height
High
Federal Commons
Exclusive
Nomenclature
Federal Commons
Inclusive
Nomenclature
Externally defined
Inclusive
Nomenclature
User defined
Flowable Universal Unique Identifier (UUID)
asdf
Unit UUID
asdf
Primary Context UUID*
Directionality -
Environmental Media -
Secondary Context UUID*
Vertical Strata -
Population Density-
Release Height -
Figure 2. Defining the nomenclature type of flow components.
3.5.1 Context nomenclature
Flow class, flow context directionality and environmental media are defined as exclusive
nomenclatures and are therefore limited to the terms as described in Section 3.3. However,
additional flow context information is considered an inclusive nomenclature and is expected to
be adapted over time as new developments within LCIA methods occur and new terms are
needed.
3.6 Flowables
Edelen et. al (2018) showed that 'Elements or Compounds' or 'Groups of Chemicals' make up
the majority of EFs. The flow list classification revealed a major design difference in the
'Elements or Compounds' and 'Groups of Chemicals' classes versus the other six flow classes. It
was decided that a different approach would be taken for the creation of the 'Elements or
Chemicals' and 'Groups of Chemicals' flowables. Flows classified as non-chemicals were
derived from the data collected from the Edelen et. al (2018) critical review. These flows were
used as a guideline for the determination of flowables for the non-chemical classes and includes
flowables from different LCI, LCIA and LCA software resources. Subject matter experts across
relevant federal agencies were also consulted when generating the non-chemical flowables list.
As described in the subsequent section, relevant EPA data sources were used to generate the
flowables list for 'Elements or Compounds' or 'Groups of Chemicals'.
23
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Additional metadata are used to provide additional information on each flowable. These include
CAS No., chemical formulas and synonyms. Not all metadata are relevant for all flow classes;
these metadata are valid for Chemicals and Groups of Chemicals, but only synonyms are
relevant for the remaining flow classes.
3.6 1 Element or Compound and Groups of Chemicals
To eliminate duplication of 'Element or Compound' (aka 'Chemicals') and 'Groups of
Chemicals' a systematic approach was taken to collect flowable names from federal emission
and LCA sources. The following sources were utilized to collect chemical names:
TRI - Toxic Release Inventory. The TRI is a publicly available emission data for
industrial facilities that are either from a specific industry (all federal facilities must
report if they meet the other two criteria), employ 10 or more full-time employees;
manufactures, processes or otherwise uses a TRI-listed chemical8 (U.S. EPA, 2019c).
NEI - National Emissions Inventory. The NEI9 (U.S. EPA, 2019d) is an estimate of
criteria pollutants, criteria precursors, and hazardous air pollutants built using the
Emissions Inventory System10 (U.S. EPA, 2019e) to collect and blend data from
State, Local, and Tribal air agencies and updated every three years.
RCRA - Resource Conservation and Recovery Act. RCRA is a EPA reporting
program to track non-hazardous solid waste11 (U.S. EPA, 2019f) and hazardous solid
waste12 (U.S. EPA, 2019g) from 'cradle-to-grave' that requires large quantity
generators to report every two years.
DMR- Discharge Monitoring Report. The National Pollution Discharge Elimination
System13 (U.S. EPA, 2019h) (NPDES) permit for point source discharges to water
sources, that provide publicly accessible data. DMR is the periodic (monthly,
seasonally or semi-annual) water pollution reports submitted to NPDES by industries,
municipalities, and facilities that discharge to surface waters.
eGRID - Emissions & Generation Resource Integrated Database14 is a data source
for air emissions and generation of electrical power in the U.S. (U.S. EPA, 2019i).
8 U.S. EPA Toxic Release Inventory. Available at: https://www.epa.gov/toxies-release-inventorv-tri-program/tri-
tisted-cfaemicals (Accessed 8/2/19).
9 U.S. EPA National Emissions Inventory. Available at: littps://www3.epa.gov/enviro/facts/nei/ (Accessed 8/2/19).
10 U.S. EPA Emissions Inventory System: https://www.epa.gov/air-eniissions-inventories/eniissions-inventorv-
svstem-eis-gatewav (Accessed 8/2/19).
11 U.S. EPA Resource Conservation and Recovery Act Non-Hazardous Waste. Available at:
https://www.epa.gOv/rcra/resource-conservation-and-recoverv-act-rcra-regulations#nonhaz (Accessed 8/2/19).
12 U.S. EPA Resource Conservation and Recovery Act Hazardous Waste, https://www.epa.gov/rera/resonree-
conservation-and-recoverv'-act-rera-regniations#haz (Accessed 8/2/19).
13 U.S. EPA National Pollutant Discharge Elimination System. Available at: https://www.epa.gov/npdes (Accessed
8/2/19).
14 U.S. EPA Emissions & Generation Resource integrated Database. Available at:
https://www.epa.gov/energv/emissions-generation-resonrce-integrated-database-egrid (Accessed 8/2/19).
24
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TRAGI - Tool for Reduction and Assessment of Chemicals and other environmental
Impacts15 (TRACI) is an environmental impact assessment tool for characterization of
life cycle data (Bare, 2011).
openLCA - is a free open source life cycle assessment software developed by
GreenDelta (GreenDelta, 2018).
The automated StEWI module developed by EPA was used to generate lists of flows used in
U.S. EPA datasets (U.S. EPA, 2018). Once chemicals were collected from these sources,
chemicals were defined using two U.S. EPA chemical databases, the Substance Registry
Services (SRS)16 and the Chemistry Dashboard17. SRS is the EPA's authoritative resource on
chemicals, biological organism and other substances tracked and regulated by EPA. The
Chemistry Dashboard is a database for chemistry, toxicity and exposure information for over
760,000 chemicals. The EPA chemical databases were used to match chemical names, CAS No.,
and chemical formulas. SRS names are used in preference over chemistry dashboard naming. A
common naming system for flows, allows for the removal of duplicates and the correspondence
of many sources of flowables and contexts to the FEDEFL.
Additionally, EPA sources are used for defining what chemicals are included in each of the
'Groups of Chemicals'. Any 'Groups of Chemicals' flowables that were unidentifiable or non-
chemicals, such as, 'Panthalium' or 'Triorganostannate', were removed from the list. 'Groups of
Chemicals' are further curated by splitting the list into preferred and non-preferred. Preferred
'Groups of Chemicals' are flowables that are linked to impacts from the TRACI 2.1, ReCiPe
(Huijbregts, 2016) or ImpactWorld+ (Bulle, 2019) LCIA methods or the openLCA software
(GreenDelta, 2018).
biological
The 'Biological' flow class addresses three types of flowables: biological materials most often
used as fuels, wood and biomass, raw resources for forestry products (e.g. wood) and biological
emissions such as microorganisms. Wood flowables in LCA are used for two main purposes, to
describe wood that will eventually be used as fuel and wood that will be used as forestry
products like flooring and/or construction material and each of these activities requires different
information about the wood. Wood flowables that are used to describe wood for fuel requires
information about the energy content of the wood and are much less concerned with the type of
wood. Therefore, a default conversion factor for wood is provided to convert between the default
15 U.S. EPA Tool for Reduction and Assessment of Chemicals and Other Environmental Impacts. Available at:
https://www.epa.gov/cheniical-researcIi/tool-rednction-and-assessment-cheniicals-and-other-environ.mental-impacts-
traci (Accessed 8/2/19).
16 U.S. EPA Substance Registry Services. Available at:
https://ofmpnb.epa.gov/sor interne t/registrv/substreg/LandingPage.do (Accessed 8/2/19).
17 U.S. EPA Chemistry Dashboard. Available at: https://comptox.epa.gov/cbishboard (Accessed 8/2/19).
25
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units in mass (kg) to energy (MJ). Based on feedback from the U.S. Forestry Services, flowables
for forestry products are most often classified as 'softwood' or 'hardwood'.
Biomass has two main activities associated with its use, fuel and soil amendment/fertilizer.
Biomass' association with fuel activities has a default conversion factor for the flowable. This
conversion factor is an average higher heating value (HHV) of the energy content of three types
of biomass, forest residue (dry basis), 15.40 MJ/kg; herbaceous biomass, 17.21 MJ/kg; and corn
stover 16.37 MJ/kg (Argonne National Laboratory, 2010).
The U.S. Department of Agriculture (USD A) LCI includes the flowables for microorganism
emissions to soil and therefore these flowables are included in the FEDEFL.
3.8.3 Energy
The 'Energy' type is defined as energy inputs not associated with a consumed material (e.g.
solar, geothermal, wind and hydropower) and energy emissions to the environment in the form of
heat. Therefore, for energy to be considered an EF resource, it must be from a renewable source.
There are different types of hydropower, including that derived from rivers and offshore sources
such as tidal (below surface and driven by the gravitational pull of the moon) and wave (on the
surface derived from the wind blowing across the surface of the ocean). However, naming of the
flowables is not affected by the activity used to collect the energy. Any additional information on
the type of collection can be included in the general information of the flow.
3.6.4 Geological
'Geological' flowables refer to substances that come from the earth's crust. This class includes
minerals, ores, rocks and aggregates, and non-renewable fuels (e.g. natural gas, coal, methane,
etc.). 'Geological' have a unit of 'kg' except for the fuels, which have a default value of 'MJ'.
The fuels also contain conversion factors between 'MJ' and 'kg'. The conversion factors utilize
the HHV of fuels.
3.6.5 Land
To simplify and clarify land use flowables, a single term 'land use' is used as the flowable and
all additional information about the land cover is addressed using the secondary context
information.
The critical review by Edelen et. al (2018) revealed two main types of 'Land' flowables, land
occupation and land transformation. Current usage of land transformation flows provides
incomplete information as it describes either the land before transformation or the land after
transformation, but never both. For example, 'transformation to cropland', only describes the
product of the transformation, but not the original land. It is the perspective of the authors that
land transformation is not a flow, but rather an activity and land flowables should describe the
land cover.
26
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To simplify the land flowables, all land cover types are used as part of the flow context
information. Therefore, the 'Land' class contains only one flowable, 'land use'.
3.6.6 Other
The 'Other' class consists of a variety of flowables that do not easily fit within the definitions of
the other seven flow classes. For the FEDEFL vl .0, only water quality parameters (e.g.,
Biological oxygen demand, Total organic carbon) are included in this category
3.6.7 Water
The critical review by Edelen et. al (2018) revealed that the water nomenclature is inconsistent.
The first step to providing a consistent nomenclature was to organize and structure the important
water properties. Five properties emerged from the study; salinity (e.g. freshwater, brackish or
saline), water feature (e.g. lake, river, ocean, etc.), vertical strata (e.g. ground, surface or
atmospheric), location and activity (e.g. drinking, municipal, irrigation, etc.). As previously
stated, activities should not be captured as a part of a flowable as they are not inherent properties
of a flow but describe how the flow is utilized within a process. The location is also a property of
a process and not an individual flow. Therefore, there are three main properties of water that are
needed to be captured by a flow in the FEDEFL. The FEDEFL captures the water feature and
vertical strata within the flow context, and the nomenclature for 'Water' flowables are based
solely on the salinity.
ow mapping
The uniform naming convention of the flowables enables the tracking and translation of flowable
characteristics from disparate databases through a consistent and reproducible process. Utilizing
the databases referenced in Section 3.6, flowables were mapped to the two primary compartment
classes, directionality and environmental media.
Directionality specifies whether flowables interact with the environment as a 'resource' being
extracted, 'emission' being released, or both. Flowables present in LCIA methods were assumed
to be emissions while those present in LCI or other datasets had to be evaluated for eligibility in
the 'resource' and 'emission' categories. All of the flowables in the Chemicals, Groups, and
Other classes were designated 'emission', while the flow classes, 'Geological' and 'Land'
contain only 'resource' flowables. The remaining flow classes, 'Biological', 'Energy', and
'Water' include flowables for both designations.
The flowables were also associated with the environmental media they flow to or from. The
options for environmental media are 'air', 'ground', 'water', and 'biotic', which are the primary
context categories (see Section 3.3). This context mapping is based on the scope of the source
database. For the federal datasets, NEI and eGRID flows are only associated with the
'emission/air' context, which is mapped in parallel with the flowables. TRI enables reporting of
emissions to all three primary contexts (air, water, and ground) and the flowables combined with
the relevant context are mapped together. TRACI 2.1, which is an aggregation of impact
27
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assessment calculations for chemical flows, uses a two-step approach. First the list of all the
FEDEFL flowables were mapped back to TRACI (where applicable) to ensure full
correspondence. The FEDEFL contexts are designed to enable nested contextual hierarchies
allowing for the mapping of TRACI and other LCIA methods. The context mapping file assigned
all compartment combination possibilities to the flowables within TRACI. Each flowable and
context combination within the completed FEDEFL list is assigned a unique UUID.
The records from the reference datasets were assigned a match condition based on the
relationship between the source datasets and the condensed, uniform list of FEDEFL flowables.
Most dataset entries had a direct correspondence to the flowables in FEDEFL were designated as
such. However, for some records only a portion of the potential flowable and are set as '<' the
FEDEFL flowable. Likewise, some dataset records are aggregated compared to the FEDEFL
flowables and were designated as '>' relative to the flowable specified in the FEDEFL.
As a product of the Federal LCA Commons TWG, the development of mapping files is focused
on providing mappings from Federal sources including NEI, TRI, TRACI, and eGRID to the
FEDEFL.
Mappings are designed to match flows using the match conditions. Match conditions may be
'equal to', 'a superset of, 'a subset of, or 'a proxy for'.
Narrower match conditions may be used in situations where sources use a group flowable when
the FEDEFL would recommend the use of individual flowables, such as with chemical mixtures
as seen in Table 3. Broader match conditions are used when source flowable names contain
overly specific information that do not map to an impact characterization and therefore are
mapped to broader terms, as seen in Table 3.
Table 3. Flowable Mapping with Match Condition Examples
Source Flowable
Match Condition
Target Flowable
Iron mixt. with manganese
>
Manganese
Iron mixt. with manganese
>
Iron
Pentane, perfluoro-, mixt with
>
Perfluoropentane
perfluorohexane
Pentane, perfluoro-, mixt with
>
Perfluorohexane
perfluorohexane
PM25-Primary from certain diesel
<
Particulate matter - PM2.5
engines
Mappings include not only flowable mappings, but mappings of the flow units and flow context
information. Mappings are required for units if sources units differ from the FEDEFL default
units. Unless flow context nomenclature is the same as that used by the FEDEFL, flow context
mapping is also required.
28
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ow |preference
Recalling the first purpose of the FEDEFL (to cover all elementary flows), the lists of flowables
and contexts are designed to be comprehensive. While flowables are intended to be unique and
should not be duplicated in the FEDEFL, they are not all defined with the same authority, or may
be less desirable to use in LCA data because they are by nature less precisely defined. For
examples, groups of chemicals in general do not define the chemical constituents and percentage
composition. In general, preferred flowables are those with more precise definitions.
The contexts, on the other hand, include intentional redundancies, with varying levels of
environmental context specification. For example, a content may exist with only a primary
context, like 'emission/air', and another context with the same primary context but with
secondary context compartments, like 'emission/air/ troposphere/low'. The same flowable may
appear in both of these contexts, as well as additional contexts with the same primary context
and perhaps some of the same secondary context compartments. In general, preferred contexts
are those with more precise environmental compartment information in the secondary context.
For these reasons, the FEDEFL may have a number of flows with redundant information,
although in totality, each flow will be unique. To provide more direction in selection of flows,
the term 'preferred flow' is used to describe flows within the FEDEFL that have both preferred
flowable and preferred context information. This flow designation has implications for flow
presence in releases and flow usage, which are discussed later. The full list of flows FEDEFL is
also referred to as the 'Master' list.
ow list assembly
To construct the FEDEFL, flowable, contexts, units, and supporting metadata were compiled into
standardized tables to be used as inputs. Standard formats were defined for Flowables,
FlowablePrimaryContexts, and FlowableAltUnits to be populated for each class of flows, as well
as for SecondaryContextMembership and Contexts, of which one table of each is created for the
FEDEFL. The standard formats are all defined in the github repository under format specs.
The Contexts data list all possible contexts for flows. The SecondaryContextMembership file
defines which context patterns are to be associated with flows based on their class and primary
contexts. A context pattern is hierarchical set of the primary and secondary context classes. For
any given context pattern, there are one or more contexts defined.
The input data are assembled into a list by combining each Flowable file with
FlowablePrimaryContexts to create records for each Flowable and PrimaryContext
combinations. Alternate units were added to the records when present for a flowable in
FlowableAltUnits. SecondaryContextMembership is used to then assign a list of all context
patterns to each Flowable and PrimaryContext combination. Flows are then created for each
Flowable and Primary Context using all Contexts matching the context pattern assigned to that
Flowable and PrimaryContext combination. UUIDs are then assigned as unique IDs to each
flow. If the Flowable is marked as preferred in Flowables, and the Context pattern in
29
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SecondaryContextMembership is marked as preferred for that flow class and Flowable and
PrimaryContext combination, then the flow is designated as a Preferred Flow.
These data were used as inputs into Python scripts that combine these input files to assemble the
master flow list. The assemble script (flowlist.py) and supporting script (contexts.py), as well as
the flow list default variables (in globals.py), are incorporated into the fedelemflowlist Python
package, fedelemflowlist allows a Python user to retrieve the flow list and mapping files in the
standard formats, and writes selected flows and mappings out to a .zip archive of JSON-LD file
matching the openLCA schema. More information can be found in the README file and the
Wild. Installation instructions for the fedelemflowlist Python module are available on the GitHub
repository. The fedelemflowlist can export files conforming to the JSON-LD openLCA schema.
LCA practitioners can then use the FEDEFL directly within the openLCA software. OpenLCA
also allows for flows to be exported in other common formats used by different software
programs such as ILCD and Ecospold.
A series of pass/fail style test scripts were created to validate the input and outputs of
fedelemflowlist. A test script was created to check that all input files are compliant with the input
format specifications, the flow list specification, and to assure that flowables are unique.
Additional tests were created to validate the created flow list and the flow mapping files. Another
script tests that valid JSON-LD files are created from a flow list and mapping files. Each of these
tests were run and 100% of tests passed before creation of vl.O of the FEDEFL.
30
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4 Summary of the Flow List, v1.0
Version 1.0 of the FEDEFL was generated using the fedelemflowlist Python package using input
files created using the methods described in the previous section. The overall structure of vl.O of
the FEDEFL as it will appear to users within an LCA software package is based on the flow
classification previously defined in Figure 1. This section provides an overview of vl.O of the
FEDEFL.
Counts of unique flowables in the FEDEFL are presented in Table 4. All contexts present in the
FEDEFL are listed in Table A-l in Appendix A. There are 114 unique contexts, 63 for emissions
and 51 for resources.
Table 4. Flowable Summary for FEDEFL vl.O
Class
No. of Flowables
Percent of Flowables
Biological
9
0.18%
Chemicals
4395
85.86%
Energy
5
0.10%
Geological
460
8.99%
Groups
241
4.71%
Land
1
0.02%
Other
4
0.08%
Water
4
0.08%
TOTAL
5,119
A summary of the flows - which are a combination of the flowables and the context designated
for that flowable - in the FEDEFL vl.O is provided in Table 5. The total number of flows in the
list is 238,485. Approximately half of those flows are preferred flows.
Table 5. Flow Summary for FEDEFL vl.O.
Class
No. of Flows
No. of Preferred Flows
Percent of Flows
Biological
9
7
0.00%
Chemicals
227,895
129,378
95.56%
Energy
7
7
0.00%
Geological
947
679
0.40%
Groups
9,273
1,728
3.89%
Land
31
20
0.01%
Other
5
5
0.00%
Water
318
128
0.13%
TOTAL
238,485
131,952
31
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r II commendation r- e U
The FEDEFL was developed to serve as the standardized elementary flow list for the Federal
LCA Commons. The FEDEFL is publicly available and can also be used more widely by LCA
practitioners, LCI data developers, and LCIA modelers with an interest in employing a
systematic approach to LCA nomenclature. The following section provides general guidance on
how to utilize the FEDEFL.
sneral guidance
Usage of the FEDEFL can be applied to new LCI unit processes or LCIA methods. The FEDEFL
can also be implemented in existing LCI and LCIA data.
This guidance document does not specify the scope of LCI or LCIA datasets. However, when the
scope is defined in a way that involves modeling of exchanges between the biosphere and
technosphere and the intention is to use the FEDEFL, some or all of these recommendations
apply, depending on what types of exchanges are modeled (e.g. land use, energy flows, pollutant
emissions) and the corresponding elementary flow classes that are used.
For LCA modeling where the FEDEFL is used in LCI, the use of LCIA methods that have been
mapped to the FEDEFL is recommended. Combined use of the FEDEFL common nomenclature
in LCI unit processes and LCIA methods will ensure LCI flows are not inadvertently left out of
LCIA results that should be capturing these flows. For a tool that can generate LCIA methods
with the FEDEFL flow, see the Iciajmt in Relationship to other documents/resources. For LCI
modeling, practitioners should ensure the FEDEFL is applied consistently across all unit
processes in the product life cycle model.
The subsequent sections provide more detail on usage of the FEDEFL for new or existing LCA
data. If data are being developed to comply with the Federal LCA Commons Data Submission
Guidelines, defer to those guidelines for application of the FEDEFL.
5,1,1 General guidance for new life cycle data
In developing new LCI and LCIA data, selecting flows from among the preferred flows (see
Flow preference for an explanation of preferred flows) is recommended. The flow
description specifies whether the flow is preferred or not.
The flowables included in the preferred flows may serve as a guideline to the types of
materials, energy, and occupation of space information to be collected when beginning to
construct an LCA model. The preferred flows indicate the flowable reference unit.
Alternative units with standardized conversion factors are also available for flowables where
data may be collected on different unit bases. For example, geological flowable inputs to the
LCI can be collected on either a mass or energy basis.
32
-------�
The contexts of the preferred flows can also be used as a suggested guideline for the
collection of elementary flow data during the inventory development. For example, as
'emission/ground/human-dominated/agricultural/rural' is a preferred context for chemical
releases to ground, inventory data should ideally be collected with this full context
information that includes this land use, as opposed to using only the "emission/ground'
context. Preferred contexts should also be used for determining the contexts for which LCIA
factors need to be developed. Using the contexts of preferred flows from the FEDEFL at the
onset of LCI or LCIA data collection and data development will help to ensure that an
appropriate level of detail is captured by the LCA practitioner when building the model. It
will also ensure that the level of detail between LCI and LCIA correspond.
If users are developing LCI or LCIA within LCA software, the users should have the
preferred flows loaded into the LCA software before creating the LCI, to be sure they are
using the elementary flow objects from the FEDEFL. If using the FEDEFL within
openLCA, users should load the FEDEFL into a new database that contains units and flow
properties, but not complete reference data. Note that attempting to manually recreate the
elementary flows in the FEDEFL in the LCA software will not result in flows matching
those in the list.
For LCI creation, it is important that users adhere to the strict definition of elementary flows
versus product flows18, as an elementary flow must transition from or to the biosphere
without any additional treatment or transformation. If any treatment or transformation
occurs, this should be represented by one or more additional processes. This general rule still
presents some limitations. The FEDEFL does not include waste material flows that escape
the treatment process (litter). More research is required to model these flows effectively in
LCA and these flows cannot be modeled as elementary flows with vl.O of the FEDEFL. The
FEDEFL is also not intended to provide guidance on product flow nomenclature.
Elementary flows in the FEDEFL do not have specific locations associated with them, like
states, countries, or watersheds. Location data should be part of LCI process inventory data,
as process metadata, and not part of the elementary flow. If LCIA factors are developed for
specific locations for elementary flows, LCA software can group elementary flows in LCI
by location and apply selected impact factors, as is done in openLCA.19
5,12 General guidance for existing LCA data
For existing LCA datasets, the recommended approach is to use or develop a flow mapping to
the FEDEFL and apply that mapping. New mappings can be developed within the
fedelemflowlist package (See Flow list assembly for a description of this package/ See Future
Work and Contributing for a link to instructions on how to create mappings. Once these
mappings are present within the fedelemflowlist package, they can be written to JSON-LD along
18 See ISO 14044 (2006), 4.2.3.3.2.
19 See Regionalized LCIA in openLCA. http://www.openlca.org/wp-content/uploads/2016/08/Regionalized-LCIA-in-
openLCA. pdf
33
-------�
with the corresponding flows, and imported into openLCA software, where they can be applied
to existing LCA data in an openLCA database. See the Relationship to other
documents/resources for a link to documentation describing this procedure. For application of
the mappings to LCI being generated in an automated manner that can use the fedelemflowlist
Python package, the mappings can be applied to convert flows more directly. It should be noted
that FEDEFL flows that are mapped to in flow mappings may not be preferred flows because the
source flows do not have the flowable or context detail that corresponds to a preferred flow.
5.2 Class specific usage
This section provides guidance on the structure of the eight classes within the FEDEFL.
5.2.1 Biological
'Biological' flows are used to represent all living organisms that are extracted from the biosphere
(i.e., resources) or bacteria and viruses emitted to the biosphere (i.e., emission). The terms
recommended for this flow class exclude the usage of specific wood species. It is recommended
that if a specific species of wood is necessary, that the use of The Wood Database20 Wood Finder
be used, and the common names captured in the flowable synonyms (Meier, 2008-2019). Use of
more specific 'Biological' flows such as hardwood or softwood are preferred over a more
generic flow such as wood or biomass. Biomass is considered by the FEDEFL as a group since
biomass materials are comprised of aggregated organic components such as cellulose,
hemicellulose, and lignin. It is important for users of the term biomass to be aware of the great
variations in content with biomass. If biomass is used to represent an energy source, it is
recommended that the default conversion factors provided in the FEDEFL are used and users
provide scenario specific energy content when necessary. It is also recommended that users
exercise caution when using the term biomass as a soil amendment or fertilizer because the
nutrient content of biomass is variable based on material type. This class is not intended to
represent biological waste material flows.
5.2.2 Element or Compound (aka 'Chemicals')
'Element or Compound' flowables are chemical emissions to air, water or ground. It is important
to note that unless a chemical name is identifiable it cannot properly connect with an LCIA
method. When using chemicals, it is important to collect additional metadata on the chemicals
you wish to include in your LCI or LCIA in order to identify corresponding flows in the
FEDEFL. Particularly the CAS number can be used for identification, as CAS are available for
most Element or Compound flowables in the FEDEFL. Chemicals should not be used as inputs
unless they occur naturally and are directly extracted from the biosphere without further
processing.
20 The Wood Database. Available at: https://www.wood-database.com/woi3d-finder/ (Accessed 8/2/19).
34
-------�
5.2.3 Energy
All energy sources associated with materials are addressed under either the 'Geological' type,
such as anthracite coal or the 'Biological' type, such as wood. The term 'Energy' is used in
combination with the source (e.g. Energy, geothermal). This class includes energy directly
extracted from the biosphere such as solar, wind, geothermal and hydro energy. Heat is only
considered an energy emission. Heat generated from power is not an elementary flow but rather a
technosphere flow (i.e. product flow). The flowable geothermal energy should be used to
represent heat from the earth as a resource.
5.2.4 Geological
'Geological' flows can be classified as resources and emissions. However, for emissions, it is
preferred to use chemical names and not mineral names to improve LCIA. Non-fuel 'Geological'
terms are defined using the mineral database, mindata.org (Hudson Institute of Mineralogy,
2019). This database provides information on the minerals including appearance, associated
minerals, and common locations of occurrence. Often in LCIs, terms such as 'aluminum ore' are
used. These non-specific descriptions are discouraged. To help users avoid using generic 'ore',
guidance on associated minerals is provided in Table 6. The selection of individual flows with
the associated minerals as flowables is recommended in this case. Metadata on the 'Geological'
flows is available within the FEDEFL, including the CAS No., chemical formula, and synonyms
as applicable.
Table 6. Guidance for Common Associated Minerals
Ores
Associated Mineral
Associated
Mineral 2
Associated
Mineral 3
Associated
Mineral 4
Associated
Mineral 5
Associated
Mineral 6
Aluminum ore
Bauxite
Arsenic ore
Arsenopyrite
Bismuth ore
Bismite
Bismuthinite
Cadmium ore
Greenockite
Smithsonite
Sphalerite
Caesium ore
Pollucite
Chromium ore
Chromite
Magnesiochro
mite
Cobalt ore
Carroll ite
Heterogenite
Erythrite
Glaucodot
Cobaltite
Cobalt ore
Linnaeite
Safflorite
Skutterudite
Azurite
Born ite
Copper ore
Chalcocite
Chalcopyrite
Covellite
Cuprite
Copper
Malachite
Copper ore
Tennantite
Tenorite
Tetrahedrite
Copper carbonate ore
Azurite
Malachite
Copper oxide ore
Cuprite
Tenorite
Copper sulfide ore
Born ite
Tetrahedrite
Chalcopyrite
Covellite
Tennantite
Chalcocite
Gold ore
Gold
Iron ore
Goethite
Hematite
Limonite
Maghemite
Magnetite
Marcasite
Iron ore
Pyrite
Siderite
35
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Ores
Associated Mineral
Associated
Mineral 2
Associated
Mineral 3
Associated
Mineral 4
Associated
Mineral 5
Associated
Mineral 6
Iron oxide ore
Goethite
Hematite
Magnetite
Iron sulfide ore
Marcasite
Pyrite
Pyrrhotite
Lead ore
Anglesite
Cerussite
Galena
Lithium ore
Lithium salt ore
Lithium
silicate ore
Lithium salt ore
Lithium silicate ore
Hectorite
Lepidolite
Petalite
Spodumene
Mercury ore
Mercury
Cinnabar
Calomel
Nickel ore
Nickel laterite
Nickel sulfide
ore
Nickel laterite
Nickel sulfide ore
Silver ore
Silver
Galena
Acathite
Sulfide ore
Nickel sulfide ore
Copper sulfide
ore
Iron sulfide
ore
Tin ore
Users should be cautious when using conversion factors for fuels. The conversion factors can be
based on the HHV of the refined fuel and not be a true reflection of the energy content of the raw
material at extraction. Applying a heating value for a fuel that is a reflection of the combustion
ready material can miss the mass loss that occurs between during the refining process between
extraction and combustion of a fuel. If a HHV of the refined fuel is used and there is a mass loss
between extraction and combustion then it is recommended that a -5-10% (estimated average)
loss of energy be accounted for in order to have an accurate cumulative energy demand. This
loss does not apply to fuels where there is no mass loss from extraction to combustion.
5.2.5 Groups of Chemicals
It is recommended that when dealing with mixtures of chemicals, the individual chemicals or
compounds are used in combination within a unit process to improve the reliability of impact
results. 'Element or Compound' flowables are, therefore, recommended over 'Groups of
Chemicals' whenever possible as several 'Groups of Chemicals' names do not correspond to
LCIA methods. In the absence of more specific information on the individual chemical
constituents, the FEDEFL provides elementary flows to capture such groups. Certain group
emissions such as Particulate matter, > 2.5[j,m and < 10[j,m, nitrogen oxides, volatile organic
compounds (VOCs), and phosphorus compounds are accounted for in LCIA methods. If a user
knows the total amount of, for example, VOCs, and only a portion of the speciated VOC
chemicals, it is recommended for the user to first use the speciated VOCs from the chemicals list
and then only the VOC group to represent any of the mass of VOCs not accounted for by the
speciated chemicals.
36
-------�
5,2:6 Land
'Land' flowables should be used in conjunction with a land product flow to represent land
transformations. A land product flow should consist of the 'Land' flowable representing the
original land cover (as a positive input) and the 'Land' flowable representing the final land cover
(as a negative input). A carbon dioxide emission can account for the carbon dioxide release
associated with the land change. The process model should include any materials, energy, or
transportation required during the land transformation process as well. There is only one 'Land'
flowable in vl.O of the FEDEFL, 'land use', which has a unit of m2*a (square meters*years),
while the land cover types are included as context information
5.27 Other
Similar to 'Groups', flows in the 'Other' class should only be used when more detailed
information on chemical composition is unknown. It is recommended that specific chemicals are
used to specify emissions when available, rather than water quality measures. As mentioned in
the previous section, vl.O of the FEDEFL does not include waste material flows that escape the
treatment process (litter).
5.28 Water
The 'Water' class should be used to represent the physical flow of water by weight (preferred) or
by volume into (resource) or out of (emission) a unit process. It is recommended that the user
pick a water flow with specific characteristics such as fresh, brackish, and saline. A more generic
water flow is provided if such details are unavailable for the flow. Properties of water are
different than 'Water' flows. In the FEDEFL water properties such as biological or chemical
oxygen demand are categorized in the 'Other' flow class (see Other). It is also important to avoid
terms such as 'moisture.' The water class flows are not designed for modeling moisture in
biomass or other flows.
37
-------�
8 I ributing
The FEDEFL is intended to be a living list that is improved upon over time as it is used by
developers of data for the Federal LCA Commons and more widely by LCA practitioners. The
list is open to contributions from all members of the LCA community. More information on the
submission guidelines for additions to the FEDEFL are found in the Contributing section of the
GitHub repository wiki. Users can recommend additions to the FEDEFL. The two primary
manners of contributing to the FEDEFL are by adding to the flow list and creating and editing
flow mapping files.
Aside from adding to or editing the FEDEFL flows and flow mappings, functional enhancements
may be needed in the future to accommodate new functionality in LCA modeling. Enhancements
that could be made include defining nested substances for flows. For example, the 'Wood' flow
could further be defined by the cellulose, hemicellulose, and lignin content. Alternatively, the
group flow 'Particulate matter, <2.5 |im' could be speciated to its chemical constituents based
on sector profiles. Developing a more granular flow list will only practically matter for LCA
modeling if this level of detail is also implemented in LCI and LCIA modeling as well as in LCA
software. These different components of LCA modeling need to continue to evolve in parallel to
ensure full interoperability of datasets between federal agencies and the FEDEFL will serve as a
platform to enable those linkages with respect to elementary flows in LCA data.
38
-------�
7 References
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McBride, B., & Norris, G. (2010). Earthster Core Ontology: Description and Rationale. Version
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40
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41
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Appendix A - Supporting Tables
Table A-l. Contexts in FEDEFL and indication of use for flows by class.
Context
Biological
Chemicals
Energy
Geological
Groups
Land
Other
Water
emission/a
r
0
1
1
0
1
0
0
1
emission/a
r/indoor
0
1
0
0
1
0
0
1
emission/a
r/stratosphere
0
1
0
0
1
0
0
1
emission/a
r/subterranean
0
1
0
0
1
0
0
1
emission/a
r/troposphere/ground-level
0
1
0
0
1
0
0
1
emission/a
r/troposphere/high
0
1
0
0
1
0
0
1
emission/a
r/troposphere/low
0
1
0
0
1
0
0
1
emission/a
r/troposphere/rural
0
1
0
0
1
0
0
1
emission/a
r/troposphere/rural/ground-level
0
1
0
0
1
0
0
1
emission/a
r/troposphere/rural/high
0
1
0
0
1
0
0
1
emission/a
r/troposphere/rural/low
0
1
0
0
1
0
0
1
emission/ai
r/troposphere/rural/very high
0
1
0
0
1
0
0
1
emission/ai
r/troposphere/urban
0
1
0
0
1
0
0
1
emission/ai
r/troposphere/urban/ground-level
0
1
0
0
1
0
0
1
emission/ai
r/troposphere/urban/high
0
1
0
0
1
0
0
1
emission/ai
r/troposphere/urban/low
0
1
0
0
1
0
0
1
emission/ai
r/troposphere/urban/very high
0
1
0
0
1
0
0
1
emission/ai
r/troposphere/very high
0
1
0
0
1
0
0
1
emission/ground
1
1
1
1
1
0
1
1
A-l
-------�
Context
Biological
Chemicals
Energy
Geological
Groups
Land
Other
Water
emission/ground/human-dominated
0
1
0
0
1
0
0
1
emission/ground/human-dominated/agricultural
0
1
0
0
1
0
0
1
emission/ground/human-dominated/agricultural/rural
0
1
0
0
1
0
0
1
emission/ground/human-
dominated/agricultural/urban
0
1
0
0
1
0
0
1
emission/ground/human-dominated/commercial
0
1
0
0
1
0
0
1
emission/ground/human-dominated/commercial/rural
0
1
0
0
1
0
0
1
emission/ground/human-
dominated/commercial/urban
0
1
0
0
1
0
0
1
emission/ground/human-dominated/industrial
0
1
0
0
1
0
0
1
emission/ground/human-dominated/industrial/rural
0
1
0
0
1
0
0
1
emission/ground/human-dominated/industrial/urban
0
1
0
0
1
0
0
1
emission/ground/human-dominated/residential
0
1
0
0
1
0
0
1
emission/ground/human-dominated/residential/rural
0
1
0
0
1
0
0
1
emission/ground/human-dominated/residential/urban
0
1
0
0
1
0
0
1
emission/ground/subterranean
0
1
0
1
1
0
0
1
emission/ground/terrestrial/barren land
0
1
0
0
1
0
0
1
emission/ground/terrestrial/forest
0
1
0
0
1
0
0
1
emission/ground/terrestrial/grassland
0
1
0
0
1
0
0
1
emission/ground/terrestrial/shrubland
0
1
0
0
1
0
0
1
emission/ground/terrestrial/snow and ice
0
1
0
0
1
0
0
1
emission/ground/terrestrial/wetland
0
1
0
0
1
0
0
1
emission/water
0
1
1
1
1
0
1
1
emission/water/brackish water body
0
1
0
0
1
0
0
1
A-2
-------�
Context
Biological
Chemicals
Energy
Geological
Groups
Land
Other
Water
emission/water/brackish water body/lake
0
1
0
0
1
0
0
1
emission/water/brackish water body/lake/rural
0
1
0
0
1
0
0
1
emission/water/brackish water body/lake/urban
0
1
0
0
1
0
0
1
emission/water/fresh water body
0
1
0
0
1
0
0
1
emission/water/fresh water body/lake
0
1
0
0
1
0
0
1
emission/water/fresh water body/lake/rural
0
1
0
0
1
0
0
1
emission/water/fresh water body/lake/urban
0
1
0
0
1
0
0
1
emission/water/fresh water body/river
0
1
0
0
1
0
0
1
emission/water/fresh water body/river/rural
0
1
0
0
1
0
0
1
emission/water/fresh water body/river/urban
0
1
0
0
1
0
0
1
emission/water/saline water body
0
1
0
0
1
0
0
1
emission/water/saline water body/ocean
0
1
0
0
1
0
0
1
emission/water/subterranean
0
1
0
1
1
0
0
1
emission/water/subterranean/brackish water body
0
1
0
0
1
0
0
1
emission/water/subterranean/brackish water
body/confined aquifer
0
1
0
0
1
0
0
1
emission/water/subterranean/brackish water
body/unconfined aquifer
0
1
0
0
1
0
0
1
emission/water/subterranean/fresh water body
0
1
0
0
1
0
0
1
emission/water/subterranean/fresh water
body/confined aquifer
0
1
0
0
1
0
0
1
emission/water/subterranean/fresh water
body/unconfined aquifer
0
1
0
0
1
0
0
1
emission/water/subterranean/saline water body
0
1
0
0
1
0
0
1
emission/water/subterranean/saline water
body/confined aquifer
0
1
0
0
1
0
0
1
A-3
-------�
Context
Biological
Chemicals
Energy
Geological
Groups
Land
Other
Water
emission/water/subterranean/saline water
body/unconfined aquifer
0
1
0
0
1
0
0
1
resource/air
0
0
1
1
0
0
0
1
resource/air/subterranean
0
0
0
1
0
0
0
1
resource/air/troposphere
0
0
0
1
0
0
0
1
resource/biotic
1
0
0
0
0
0
0
0
resource/ground
0
0
1
1
0
0
0
0
resource/ground/human-dominated
0
0
0
0
0
1
0
0
resource/ground/human-dominated/agricultural
0
0
0
0
0
1
0
0
resource/ground/human-dominated/agricultural/rural
0
0
0
0
0
1
0
0
resource/ground/human-
dominated/agricultural/urban
0
0
0
0
0
1
0
0
resource/ground/human-dominated/commercial
0
0
0
0
0
1
0
0
resource/ground/human-dominated/commercial/rural
0
0
0
0
0
1
0
0
resource/ground/human-
dominated/commercial/urban
0
0
0
0
0
1
0
0
resource/ground/human-dominated/industrial
0
0
0
0
0
1
0
0
resource/ground/human-dominated/industrial/rural
0
0
0
0
0
1
0
0
resource/ground/human-dominated/industrial/urban
0
0
0
0
0
1
0
0
resource/ground/human-dominated/residential
0
0
0
0
0
1
0
0
resource/ground/human-dominated/residential/rural
0
0
0
0
0
1
0
0
resource/ground/human-dominated/residential/urban
0
0
0
0
0
1
0
0
resource/ground/human-dominated/rural
0
0
0
0
0
1
0
0
resource/ground/human-dominated/urban
0
0
0
0
0
1
0
0
resource/ground/subterranean
0
0
0
1
0
0
0
0
A-4
-------�
Context
Biological
Chemicals
Energy
Geological
Groups
Land
Other
Water
resource/ground/terrestrial/barren land
0
0
0
0
0
1
0
0
resource/ground/terrestrial/forest
0
0
0
0
0
1
0
0
resource/ground/terrestrial/grassland
0
0
0
0
0
1
0
0
resource/ground/terrestrial/shrubland
0
0
0
0
0
1
0
0
resource/ground/terrestrial/snow and ice
0
0
0
0
0
1
0
0
resource/ground/terrestrial/wetland
0
0
0
0
0
1
0
0
resource/water
0
0
1
1
0
0
1
resource/water/brackish water body
0
0
0
0
0
0
1
resource/water/brackish water body/lake
0
0
0
0
0
1
0
1
resource/water/brackish water body/lake/rural
0
0
0
0
0
1
0
1
resource/water/brackish water body/lake/urban
0
0
0
0
0
1
0
1
resource/water/fresh water body
0
0
0
0
0
0
1
resource/water/fresh water body/lake
0
0
0
0
0
1
0
1
resource/water/fresh water body/lake/rural
0
0
0
0
0
1
0
1
resource/water/fresh water body/lake/urban
0
0
0
0
0
1
0
1
resource/water/fresh water body/river
0
0
0
0
0
1
0
1
resource/water/fresh water body/river/rural
0
0
0
0
0
1
0
1
resource/water/fresh water body/river/urban
0
0
0
0
0
1
0
1
resource/water/saline water body
0
0
0
0
0
0
0
1
resource/water/saline water body/ocean
0
0
0
0
0
1
0
1
resource/water/subterranean
0
0
0
1
0
0
0
1
resource/water/subterranean/brackish water body
0
0
0
0
0
0
0
1
resource/water/subterranean/brackish water
body/confined aquifer
0
0
0
0
0
0
0
1
A-5
-------�
Context
Biological
Chemicals
Energy
Geological
Groups
Land
Other
Water
resource/water/subterranean/brackish water
body/unconfined aquifer
0
0
0
0
0
0
0
1
resource/water/subterranean/fresh water body
0
0
0
0
0
0
0
1
resource/water/subterranean/fresh water
body/confined aquifer
0
0
0
0
0
0
0
1
resource/water/subterranean/fresh water
body/unconfined aquifer
0
0
0
0
0
0
0
1
resource/water/subterranean/saline water body
0
0
0
0
0
0
0
1
resource/water/subterranean/saline water
body/confined aquifer
0
0
0
0
0
0
0
1
resource/water/subterranean/saline water
body/unconfined aquifer
0
0
0
0
0
0
0
1
A-6
-------�
PERMIT NO. G-35
United States
Environmental Protection
Agency
Office of Research
and Development
(8101R)
Washington, DC
20460
Offal Business
Penalty for Private Use$300
-------� |