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COAL MINE METHANE DEVELOPMENTS IN THE UNITED STATES
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Contents
Introduction 1
Overview of CMM Emissions in the United States 2
Overview of U.S. CMM Utilization and Destruction Projects 4
CMM Project Profiles 5
Market and Policy Incentives for CMM Capture and Utilization 6
Voluntary Carbon Markets 6
Compliance Carbon Markets 7
Alternative and Renewable Energy Incentives for CMM 8
CMM Data from the U.S. Greenhouse Gas Reporting Program Subpart FF 8
Greenhouse Gas Reporting Program Overview 8
Coal Mine Reporting Requirements 9
Results of 2011-2016 Data Collection 9
Conclusions 10
Appendix A: Overview of State Renewable Energy Incentive Programs A-l
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Introduction
Methane (CH4) accounted for 10 percent of all U.S. greenhouse gas (GHG) emissions in 2015, and has a
shorter atmospheric life span than carbon dioxide (C02). Coal seams often contain significant quantities
of methane that are released to the atmosphere from gassy underground mines during coal extraction.
Coal mine methane (CMM) refers to methane from surface or underground coal mines and abandoned
underground coal mines that is released to the atmosphere or captured in advance of, during, orfollowing
physical coal mining activities. The release of CMM from active and abandoned mining operations is a
major type of GHG emission, accounting for about 9 percent of anthropogenic methane emissions.1
CMM emissions management is importantfor several reasons, including enhanced mine safety, mitigation
of GHG emissions, and the potential supply of a local clean energy source. The recovery and use of CMM
can lead to improved worker safety and mine profitability, as well as reduced GHG emissions. Most CMM
projects recover and use methane from coal mine gas drainage systems, which include pre-mine
degasification, in-mine horizontal boreholes, and post-mining gob gas recovery. In 2015, nearly 60 percent
of all U.S. CMM emissions were released through underground mine ventilation fans. The concentration
of ventilation air methane (VAM) is extremely low, typically below 1 percent. This has been a barrier to
VAM recovery and destruction/utilization in the past, but recent technological advancements with
oxidation equipment and the growth of carbon markets have made it possible to deploy profitable VAM
mitigation projects.
Coal mines around the world have recognized that methane is a clean energy resource that can be
captured and used productively, with both economic and safety benefits. CMM is used for power
generation, natural gas pipeline injection, vehicle fuel, industrial process feed stocks, onsite mine boilers,
mine heating, and home heating distribution systems. Upgrading mine degasification systems can often
improve gas quality and create favorable project economics.
The United States has been a leader in CMM recovery and use since the 1990s. There are now 15 CMM
projects at active U.S. underground mines, as well as 18 abandoned mine methane (AMM) projects that
recover methane from 40 abandoned coal mines. U.S. CMM and AMM recovery and use projects reduced
methane emissions by about 1.1 billion cubic meters (BCM) in 2015. The first commercial-scale VAM
mitigation project, at the Marshall County Mine in West Virginia, has been operational since September
2012. Ventilation air contains dilute concentrations of methane, making it more technically and
economically challenging to recover; VAM comprises the largest source of methane emitted from coal
mines. This project reduced methane emissions by 17 million cubic meters (MCM) in 2015.
As part of the U.S. Greenhouse Gas Reporting Program (GHGRP), actual data on methane emissions from
underground coal mines has been reported to the U.S. Environmental Protection Agency (EPA) each year
since 2012. This data has helped inform stakeholders, particularly the underground coal mining industry,
of the magnitude of CMM emissions on public and private lands. It also sheds light on the specific sources
of methane from active underground coal mines and highlights both VAM and CMM recovery
opportunities for the U.S. coal industry.
This document provides an overview of U.S. CMM emissions, U.S. CMM use and destruction projects,
federal policies and state incentives for CMM capture and utilization, and CMM emissions data from the
1 EPA. 2017. Greenhouse Gas Emissions: Overview of Greenhouse Gases, https://www.epa.gov/ghgemissions/overview-greenhouse-gases.
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U.S. Greenhouse Gas Reporting Program, Subpart FF. It also discusses other developments, including the
emergence of compliance carbon markets.
Overview of CMM Emissions in the United States
The U.S. coal emissions inventory consists of five different sub-source categories:
Methane released through underground mine ventilation fans (VAM).
Gas drainage systems at underground coal mines that use vertical and/or horizontal wells (CMM).
Fugitive emissions from abandoned coal mines (abandoned mine methane or AMM).
Coal seams exposed to the atmosphere through surface mining (surface mine methane or SMM).
Post-mine emissions (surface and underground) released in handling and transporting coal after
mining.
Figure 1 breaks down each sub-source category by emissions. U.S. coal mines emitted 3,974 million cubic
meters (MCM) of methane in 2015.
Post Mining (Surface),
111 MCM
3%
Abandoned (UG)
Vented
377 MCM
„9%
Surface Mining
511 MCM
13%
Post Mining (UG)
339 MCM
9%
Degasification (UG)
Vented
250 MCM
6%
Ventilation Emissions
(UG)
2,387 MCM
60%
Figure 1. 2015 U.S. CMM Emissions (MCM)2
Most emissions from coal mining are attributed to underground operations. In 2015, EPA estimates these
operations accounted for about 75 percent (or 2,976 MCM) of methane emissions associated with coal
mining. Most of the emissions (2,387 MCM) originate from VAM; post-mining operations and
degasification systems are also significant sources. To maintain safe working environments in
underground coal mines, particularly gassy mines, use methane degasification systems are used to
supplement ventilation fans. In 2015, about 80 percent of the methane from degasification systems was
recovered and used.
Emissions from surface coal mining are small compared to emissions from underground coal mining. Coal
seams that are mined near the surface contain less in situ methane than deeper coal seams, typically
2 EPA. 2017. Inventory of U.S. Greenhouse Gas Emissions and Sinks: 1990-2015. https://www.epa.gov/ghgemissions/inventorv-us-greenhouse-
gas-emissions-and-sinks.
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mined in underground coal mines. Surface mines also contribute to methane emissions from overburden
piles and release emissions through uncontrolled combustion and low-temperature oxidation. About 16
percent of 2015 emissions from coal mining were attributable to surface mining and post-surface mining
operations.
Figure 2 below shows active underground coal mine production and CMM emissions in the United States
from 2000 to 2015. Underground coal production has steadily declined or remained flat since 2000—
production in 2015 was 18 percent lower than in 2000. The amount of CMM liberated from underground
mines does not closely correlate with coal production: it increased significantly from 2008 to 2011 before
falling in 2015 to a level 4 percent lower than in 2000. This trend reflects the closure of less gassy mines
and the increased gas contents of the coal being mined in deeper seams. In 2000, U.S. underground coal
mines produced about 338 million metric tons of coal and liberated 3.8 BCM of methane. In 2015,
underground coal production declined to 278 million metric tons of coal, and underground mines
liberated 3.6 BCM of methane. The recovery and use of methane liberated from coal mine degasification
systems has averaged 83 percent since 2000. This is due primarily to the deployment of large-scale CMM
pipeline injection projects throughout the Appalachian coal basins. The CMM is vented to the atmosphere
and accounts for the 250 MCM presented in Figure 1 for degasification emissions.
Total CMM Liberated
Ventilation Air Methane
Degas Liberated
Recovered & Used
•Underground Coal Production
7,000
6,000
a 5.000
4,000
3.000
£ 2,000
Figure 2. Active Underground Coal Mine Production and CMM Emissions in the United States, 2000-2015
Emissions at U.S. surface coal mines have declined 18 percent from 2000 to 2015, primarily due to lower
coal production (16 percent) over that period. The last methane drainage project at a surface mine was
decommissioned in 2011.
Many underground coal mines closed in the 1990s, so AMM emissions were near a historical peak in 2000
(see Figure 3). They then declined steadily until 2008, when they leveled off due to an increase in the
number of mines closed each year. (Methane emissions can continue for a long time after operations have
ceased and a mine has been sealed, due to cracks and fissures in overlying geological layers, boreholes,
and vent pipes. Exceptions include mines that are completely flooded, wherein emissions drop to zero
after about 15 years.)
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Meanwhile, AMM recovery peaked in 2007-2008, following the closure of two large underground coal
mines with pre-existing methane recovery projects. Methane vented to the atmosphere from abandoned
mines has remained relatively flat since that time, with new abandoned mines offsetting the natural
overall decline in AMM emissions.
700
500
400
S
o
300
Methane Liberated
Metliane Vented
Emissions Avoided
g
200
V
Year
Figure 3. Methane Emissions from Abandoned Mines
Overview of U.S. CMM Utilization and Destruction Projects
As a primary constituent of natural gas, methane can be an important energy source. Efforts to recover
and use methane emissions from coal mines can provide economic, environmental, and energy benefits
and improve worker safety. CMM recovery and use peaked in 2010 (at an estimated 1,573 MCM) and
reached 1,088 MCM in 2015, which is 10 percent below the CMM volume recovered and used in 2000 and
32 percent below the 2010 peak recovery and use volume. CMM utilization and destruction projects
involve six project types in the United States: pipeline sales, electric generation, heater, boiler/dryer,
flaring, degasification pumps, and VAM oxidation. Several mines have multiple project types.
Injection of CMM and AMM into pipelines is the most common project type. Pipeline projects are feasible
for mines with nearby pipelines that can handle the quantity of gas expected to be produced. Methane
from a coal mine must also meet pipeline standards to be injected, which may involve upgrading the
methane gas to natural gas pipeline specifications.
CMM or AMM can be used as a fuel, generating electricity to meet onsite needs or be sold to utilities.
Unlike pipeline injection, CMM for power generation does not require high-quality methane. U.S. projects
are typically in the 1- to 3-megawatt range. Electric power generation projects are less common than
pipeline projects. The other non-pipeline project located at an active mine uses methane to fuel mine air
heaters.
Flaring of CMM or AMM—in open or enclosed systems—converts the methane to carbon dioxide. CMM
flare projects have been implemented to reduce methane emissions and thus earn carbon offset credits.
Currently, the United States has three flare projects, all working in conjunction with other project
destruction devices.
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Methane is explosive at concentrations ranging from 5 to 15 percent in air. Federal mine safety regulations
require gassy underground coal mines to keep methane concentrations well below the lower explosive
limit. For safety, fresh air is circulated through underground coal mines using ventilation systems to dilute
methane to levels typically ranging from 0.1 to 1.0 percent. VAM represents about 60 percent of all coal
mining emissions in the United States and is vented to the atmosphere at all mines but one. VAM
technologies oxidize the methane in mine exhaust air and destroy it before it is released to the
atmosphere. The most commonly used VAM technology is thermal oxidation.
In 2015, there were 15 active mines operating 20 methane recovery and use projects in the United States.
Thirteen of the projects involve upgrading methane for injection into a commercial pipeline. However,
the projects include four types of other end use and methane destruction via flares and thermal oxidizers.
Table 1 summarizes the various end uses deployed at the mines. The latest projects to be deployed in the
United States were the Elk Creek Mine and Marshall County Mine CMM projects in 2012.
In 2015, there were 18 AMM projects operating at 40 abandoned mines in the United States. Most of
these are east of the Mississippi River, in the Central Appalachian, Northern Appalachian, Illinois, and
Warrior coal basins; the two western mines are in Colorado and Utah. One project (the Corinth project in
southern Illinois) recovers methane from 14 mines that were abandoned between 1926 and 1998.
Table 1. Summary of U.S. Mine Methane Recovery and Destruction Projects
Number of
Number of
Projects
End Uses
Type of Mine
Mines with
Projects
Pipeline
Electric
Generation
Heater
Boiler/
Dryer
Flare
VAM
Active
underground
15
20
13
1
2
1
2
1
Abandoned
underground
40
18
15
2
0
0
1
0
CMM Project Profiles
The Elk Creek Coal Mine project, at Oxbow's Elk Creek
Mine in Gunnison County, Colorado, was the latest
active underground coal mine in the United States to
generate electricity from CMM, and the first at a
western coal mine. The Elk Creek mine was abandoned
in 2016; however, the project transitioned to a multi-
mine AMM project that included four adjacent
abandoned mines. The 3-megawatt plant continues to
operate in conjunction with an enclosed flaring system.
In addition to selling electricity to a local utility, the
project has generated offset credits in voluntary and
compliance carbon markets in the United States.
Elk Creek CMM Electric Power Project
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The VAM project at Murray Energy's Marshall County
Mine in West Virginia began destroying methane in
May 2012 and as of 2017; is the only operating VAM
project in the United States. It consists of three
regenerative thermal oxidizers that convert methane
to carbon dioxide and water vapor. During the start-up
phase, the ceramic medium bed in the oxidizer is
heated with a propane burner. VAM is then forced
through the bed, methane is oxidized, the released
heat is recovered by the ceramic bed medium, and the
air flow is reversed. The heat recovered from the first
cycle heats the incoming VAM and the process repeats.
The methane concentration in the VAM ranges
between 0.6 and 1.5 percent. The project has also
generated offset credits in voluntary and compliance carbon markets in the United States.
Market and Policy Incentives for CMM Capture and Utilization
Several voluntary carbon markets in the United States provide opportunities for CMM offset projects to
generate carbon credits. Whether a CMM project is eligible for carbon credits depends on specifics such
as its start-up date, end use technology (electricity generation vs. pipeline sales), and origin of methane
(e.g., active vs. abandoned mines, surface vs. underground mines). In addition, each GHG registry has its
own rules governing project eligibility, additionality, and registration. Voluntary carbon markets include
the Verified Carbon Standard (VCS), Climate Action Reserve (CAR), and the American Carbon Registry
(ACR). During 2015 and 2016, seven of the nine projects, or nearly 80 percent of those registered with
voluntary carbon markets, transitioned to the California Air Resources Board (CARB) compliance offset
program because of the increased value for the offset credits.
Voluntary Carbon Markets
The CAR, a non-profit registry and trading system based in California, was launched in 2008. The Coal Mine
Methane Project Protocol Version 1.1, issued on October 26, 2012, covers projects that use CMM for
electricity generation and flaring and projects destroying VAM. As of December 2012, CAR had four CMM
projects registered, all at active mines: two CMM utilization and flaring projects and two VAM projects.
One of the VAM projects was decommissioned in 2013; the other three projects have transitioned to CARB.
The VCS began in 2005 and currently manages a portfolio of programs and initiatives including: VCS
Program (allows projects to register and sell carbon credits) and VCS California Offset Project Registry
(helps administer the registration of carbon credits for California's cap-and-trade program). VCS follows
the Clean Development Mechanism (CDM) methodologies and tools for CMM projects, namely CDM
methodology ACM0008. VCS developed a surface mine methane (SMM) protocol in 2009 (VMR0001) and
an AMM protocol in 2010 (VMR0002). As of December 2011, VCS had five CMM projects registered: two
SMM gas pipeline projects and three AMM gas pipeline projects. Although decommissioned in 2011, the
two SMM projects received early action credits from CARB. Two of the AMM projects received early action
credits; one of those two has transitioned to CARB (the other expects to transition in 2017). The last AMM
project was decommissioned in 2014, but never received early action credits or transitioned to CARB.
The ACR, launched in 1996, was the first private voluntary GHG registry in the United States before
becoming an enterprise of Winrock International in 2007. ACR considers methodologies from other GHG
program standards that are consistent with the ACR Technical Standard, including CDM, VCS, and CAR.
Marshall County VAM Project
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Acting as an offset program registry for CARB, ACR has accepted CMM projects into its system beginning
in 2015. No voluntary CMM projects have been registered in ACR.
Compliance Carbon Markets
Since 2011, CARB has operated a compliance offset program as part of its GHG cap-and-trade regulation.
In 2014, CARB adopted the Mine Methane Capture (MMC) Protocol allowing CMM projects other than
natural gas pipeline sales to qualify as Compliance Offset Projects. CARB then allows covered entities to
purchase and trade these ARB Offset Credits from CMM projects anywhere in the United States. The MMC
Protocol has renewed interest in CMM projects, particularly VAM destruction projects and projects that
use drained gas for power production, flaring, and liquified natural gas or compressed natural gas
production.
As of August 2017, CMM projects have been issued credits for 1.5 million metric tons C02e reductions in
the CARB offset program, representing 3.4 percent of total compliance offset credits issued by CARB
(Table 2).
Table 2. Registered Mine Methane Capture Projects in the CARB Offset Program (as of 2017)3
Project Name
Project
Type
Location
Credit Type
Credits Issued
Start Date
End Date
Verdeo Marshall County VAM
Abatement Project
VAM
WV
Early action
197,411
5/4/2012
10/31/2013
Compliance
504,705
11/1/2013
12/31/2015
Vamox® Demonstration Project
at JWR Shaft No. 4-9
AL
Early action
80,766
3/6/2009
2/28/2013
Elk Creek Coal Mine Methane
Destruction and Utilization
Project
CMM
CO
Early action
432,609
1/1/2014
12/31/2014
Compliance
266,263
1/1/2015
1/31/2016
Solvay Chemicals, Inc. Waste
Mine Methane Project
WY
Early action
498,654
8/13/2010
12/31/2014
Compliance
424,076
1/1/2015
12/31/2016
Cambria 33 Abandoned Mine
Methane Capture and Use
Project
AMM
PA
Early action
107,064
1/1/2011
12/31/2014
Corinth Abandoned Mine
Methane Recovery Project
IL
Early action
490,456
1/1/2010
12/31/2014
Compliance
298,891
1/1/2015
12/31/2016
Baker Mine AMM Project
KY
Compliance
2,236
4/4/2016
10/4/2016
North Antelope Rochelle Coal
Mine Project
SMM
WY
Early action
1,072,724
3/28/2006
3/31/2009
Total CARB credits issued for MMC
Early action
2,879,684
3/6/2009
12/31/2014
Compliance
1,496,171
1/1/2013
12/31/2016
Total
4,375,855
3 California Air Resources Board. 2017. ARB Offset Credits Issued.
https://www.arb.ca.gov/cc/capandtrade/offsets/issuance/arb offset credit issuance table.pdf.
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Alternative and Renewable Energy Incentives for CMM
CMM is considered an increasingly important alternative or renewable energy resource to help states
meet renewable energy portfolio standards (RPS). Many U.S. states have developed RPS that direct
electricity providers to generate or obtain minimum percentages of their power from "eligible energy
resources" by certain dates. Out of the top 15 coal-producing states in 2015/4 five—Pennsylvania, Ohio,
Utah, Indiana, and Colorado—currently include CMM in their renewable or alternative energy standards.
In those states RPSs, CMM is considered "similar" to landfill gas, in that methane is released over time
during industrial-type operations, and efforts to capture and use or destroy CMM are technically similar
to measures used to collect and dispose of landfill gas.
Pennsylvania and Ohio each designate CMM as an "alternative" energy resource rather than a "renewable"
energy resource. Generally, the term "renewable energy" resources refers to sources such as solar-electric,
solar thermal energy, wind power, hydropower, geothermal energy, fuel cells, and certain biomass energy
and biologically derived fuels. However, the designation of alternative energy sources varies from state
to state and may include sources such as waste coal, demand-side management or energy improvement
projects, and solid waste conversion technologies. Where CMM is included as part of a state's renewable
or alternative energy portfolio standards, other state-level alternative energy incentives for development
can also exist. Table 3 provides a summary of state CMM incentives and complete details regarding states'
incentive programs can be found in Appendix A.
Table 3. Summary of State CMM Incentives
State
Definition of CMM
Incentives and Programs
Pennsylvania
CMM is an alternative energy resource
Alternative Energy Portfolio Standard
• Alternative energy credits
Ohio
CMM is an advanced energy resource;
AMM is a renewable energy resource
Alternative Energy Resource Standard
• Renewable energy certificates (RECs)
Advanced Energy Program
• Forgivable and non-forgivable loans
Colorado
CMM is a renewable energy resource if it is
GHG-neutral electricity; determined on a case-
by-case basis
Renewable Energy Standard
• RECs
Utah
CMM is a renewable energy resource
Renewable Portfolio Standard
• RECs
Indiana
CBM (coalbed methane) is defined as an
alternative energy source and clean energy
resource
Voluntary Clean Energy Portfolio Standard
• Incentives to help pay for compliance
projects
CMM Data from the U.S. Greenhouse Gas Reporting Program Subpart FF
Greenhouse Gas Reporting Program Overview
In 2009, the U.S. EPA issued the Mandatory Reporting of Greenhouse Gases Rule, which requires reporting
of GHG data and other relevant information from large sources and suppliers throughout the United
States. Since 2010, the information gathered by the rule has given EPA a better understanding of the
"Alabama, Ohio, Pennsylvania, Illinois, Indiana, West Virginia, Virginia, North Dakota, Kentucky, Texas, Colorado, Wyoming, Utah, Montana, and
New Mexico.
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relative emissions of specific industries and of individual facilities within those industries. In general,
facilities that emit 25,000 metric tons or more per year of GHGs are required to submit annual reports to
EPA. In the case of underground coal mines (Subpart FF), facilities that liberate 36.5 million cubic feet of
methane per year (17,525 metric tons C02e (1,033,700 cubic meters of methane) or more per year must
report.
The first reporting year for underground coal mines was 2011. Reports are submitted annually by the end
of March in the year following the reporting year and become available to the public in October. EPA
publishes current year and prior year data through its interactive Facility Level Information on Greenhouse
Gases Tool (FLIGHT)5 and EPA's Envirofacts6 data portal.
Coal Mine Reporting Requirements
The GHG Reporting Rule requires underground coal mines subject to the rule to report methane liberated
through ventilation streams and degasification systems. The mines report the net ventilation and drainage
flows along with the portion of that flow that is emitted and the portion recovered for use or flaring. If
the recovered methane is combusted without energy recovery (e.g., flared or oxidized), the C02 from
methane destruction is also reported. Use of methane in an engine or other useful combustion device
requires that the facility report C02 emissions under the subpart covering combustion devices, if it is a
size and type that fits the subpart requirements.
The GHG Reporting Rule allows mines to use one of three approaches to calculating emissions from mine
ventilation systems: they may measure flow rates and emission concentrations directly by taking grab
samples or using Continuous Emissions Monitoring (CEMS) to calculate total emissions, or they may use
the air sampling results from MSHA's quarterly inspections. MSHA regulates in-mine concentrations of
ventilation air using well-defined procedures to ensure that the methane is well below explosive levels.
Mines can access that data for use in calculating overall emissions. To calculate emissions from
degasification systems, mines must use either grab samples or CEMS.
Results of 2011-2016 Data Collection
In 2016, 94 underground coal mines reported to the GHGRP; their emissions totaled 1,559,644 metric
tons of methane. A majority of reporting mines (70 percent) that year used quarterly MSHA
measurements as the basis of their emissions report rather than their own samples (Table 4). Methane
emissions decreased by 5 percent from 2011 to 2016.
Table 4. GHGRP Subpart FF Reporting: 2011 - 2016
2011
2012
2013
2014
2015
2016
GHGRP Underground Mines Reporting
117
118
131
130
124
94
Active U.S. Underground Mines*
508
488
395
345
305
253
GHGRP Share
Percent of Underground Coal Mines
Percent of Underground Coal Production
23%
84%
24%
87%
33%
89%
38%
89%
41%
88%
37%
77%
* EIA (2012-2017) Annual Coal Reports 2012-2017. Table 1. Energy Information Administration, U.S. Department of Energy.
5 https://ghgdata.epa.gOv/ghgp/main.do#
6 https://www3.epa.gov/enviro/
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Conclusions
CMM accounts for about 9 percent of total U.S. anthropogenic methane emissions. Managing CMM
emissions improves worker safety and mine profitability. Since 2000, the recovery and use of CMM from
coal mine degasification systems has ranged from 77 to 88 percent annually. The first VAM recovery and
destruction project in the United States started in 2012. California's compliance offset program has
provided meaningful incentives for U.S. projects, with most eligible projects transitioning from voluntary
GHG registries over the past two years. The anticipated increase in price for offsets and the extension of
the program to 2030 might incentivize additional CMM, AMM, and VAM projects in the near future. CMM
is also increasingly being considered an important alternative or renewable energy resource by individual
states, with eligible projects now located in three states. The Greenhouse Gas Reporting Program provides
a rich source of information on methane emissions from underground coal mines.
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Appendix A: Overview of State Renewable Energy Incentive Programs
Colorado
Colorado became the first state to adopt an RPS by ballot initiative when voters approved Amendment
37, the "Colorado Renewable Energy Requirement Initiative/' to create the state's Renewable Energy
Standard (RES) in November 2004. More recently, the passing of SB 13-252 in 2013 added CMM as an
eligible energy resource for utility providers. As a requirement under the RES, electricity generated from
CMM must also be shown to be greenhouse gas neutral over a five-year period. The RPS requires utilities
to generate different percentages of power from eligible energy resources, based on their sector type. By
2020, each sector must generate electricity from eligible energy sources in the following proportions of
their retail sales: 30 percent for investor-owned utilities, 20 percent for electric cooperatives serving
100,000 or more meters, 10 percent for electric cooperatives serving fewer than 100,000 meters, and 10
percent for municipal utilities serving more than 40,000 meters.
Utilities comply with the RPS by obtaining and retiring RECs. One REC is issued per one megawatt-hour of
electricity generated by a renewable energy source. RECs are good until the end of the fifth calendar year
following the year in which it was generated, and a utility can buy, sell, or trade RECs given that it obtains
and retires enough RECs to comply with the RES requirements.
Since November 2012, Colorado's Elk Creek Mine Project in Gunnison County is generating 3 megawatts
of electricity which is bought by Holy Cross Energy. The project is operated by Vessels Coal Gas, Inc.
Indiana
Indiana passed its Clean Energy Law in May 2011, which established the Clean Energy Portfolio Standard,
also known as the Comprehensive Hoosier Option to Incentivize Cleaner Energy (CHOICE) program.
Regulated by the Indiana Utility Regulatory Commission (IURC), the program creates incentives for the
state's utilities to voluntarily increase the amount of clean energy resources in their electricity portfolios
and is open to electricity suppliers approved by the IURC. The voluntary goal set forth by the CHOICE
program requires that 10 percent of electricity produced is generated from qualifying clean energy
sources by 2025. The Clean Energy Law names 21 clean energy sources qualifying under the standard,
including CBM.
Electricity suppliers choosing to participate in CHOICE must apply to and be approved by the IURC, and
submit a plan to meet the goals, including a detailed business plan and identification of specific projects
and resources, as well as proof of compliance to the program's requirements. Similar to Utah, the state
lets utilities meet this target by producing electricity from an eligible form of renewable energy or by
purchasing clean energy credits, which are defined as one megawatt-hour of clean energy or 3,412,000
British thermal units (BTU).
Hoosier Energy, an electricity and generating cooperative, constructed a 13-megawatt-hour CBM power
generating facility in Sullivan County. This is a first-of-its-kind facility, the only one solely operating on
CBM. The project is unique because the methane is collected, processed, and converted to electricity
entirely onsite, and began operations in May 2013. The project eliminates approximately 390,000 metric
tons C02e.
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Ohio
Ohio's Alternative Energy Resource Standard (AERS) was created by S.B. 221 in May 2008. The AERS
combines renewable energy resources and advanced energy resources into one category, "alternative
energy resources." In its current form, the AERS applies to electric utilities and electric service companies
serving customers in Ohio and requires utilities to provide 12.5 percent of their retail electricity supply
from alternative energy sources by 2026.
In July 2009, legislators amended the original law with Sub H.B. 1, to include methane gas emitted from
abandoned coal mines as well as methane from operating coal mines as an alternative energy resource.
The law was also amended to include projects with technologies, products, activities, and management
practices or strategies that facilitate the generation or use of energy that supports reduced energy
consumption or production of clean renewable energy. Thus, CMM pipeline sales projects could qualify
under the revised law. In May 2014, S.B. 310 changed the original standards set forth by S.B. 221, by
freezing the ramp-up schedule of renewable percentage benchmarks for two years, removing the in-state
requirement for renewable energy procurement, and pushing back the final renewable benchmark from
25 percent to 12.5 percent from 2024 to 2026. Ohio was the first state to freeze its multi-year alternative
energy ramp-up schedule, but as of January 1, 2017, the AERS was mandatory again. Ohio's House of
Representatives voted in March 2017 to turn the AERS into a voluntary standard. The bill now goes to the
Ohio Senate, where there is no similar legislation.
AERS compliance is achieved by earning or purchasing qualified renewable energy certificates (RECs),
which are good for five years after acquisition. One REC is issued per one megawatt-hour of electricity
generated by a renewable energy source. At least 50 percent of the renewable energy requirement must
be met by in-state facilities, and the remaining 50 percent can be provided from renewable energy
resources shown to be deliverable into the state. Only RECs generated after July 31, 2008, from facilities
with a capacity of more than 6 kilowatts may be used for compliance. To qualify under the AERS, an
alternative energy and renewable energy facility must have a placed-in-service date of January 1, 1998,
or later and must be a member in good standing of the PJM (a regional transmission organization), MISO
(the regional electric power market), or other credible tracking system.
CBM Ohio LLC operates an AMM project and is receiving RECs for its methane-to-pipeline sales in Harrison
County, Ohio. It is currently managing exploration and production of over 20,000 acres of abandoned coal
mines in the state. In 2013, CMM accounted for 1.4 percent of the total REC retirements in the state.
Pennsylvania
Pennsylvania was the first state to define CMM as an alternative energy fuel in its Alternative Energy
Portfolio Standard (AEPS), signed into law November 30, 2004. The AEPS does not distinguish between
renewable and alternative energy resources; it designates all sources as alternative energy. Eligible
technologies include demand-side management, waste coal, CMM, and coal gasification. The AEPS
requires each electric distribution company that sells electricity to customers in Pennsylvania to supply
18 percent of its electricity from alternative energy resources by 2021, with at least 8 percent from "Tier
I" resources (which includes CMM) by May 31, 2021. The Pennsylvania Public Utility Commission is
responsible for carrying out and enforcing the requirements of this law.
Compliance with the AEPS requires alternative energy credits (AECs). One AEC is equal to one megawatt-
hour of alternative energy generated and is good for three years from the date it was created. If a utility
cannot produce the required AECs for one year, they must make alternative compliance payments to
offset the deficit. AECs are similar to traditional renewable energy credits, except that they include both
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renewable energy resources and Pennsylvania-specific alternative resources. Energy derived from
alternative energy sources inside Pennsylvania or within the PJM Service Territory outside the state (the
regional transmission group) is eligible to meet the AEPS requirements.
Utah
Utah established a renewable portfolio goal in the "Energy Resource and Carbon Emission Reduction
Initiative/' enacted in March 2008 (similar to renewable portfolio standards in other states). Under this
law, to the extent that it is cost-effective to do so, each electrical corporation and municipal electric
utility's retail electric sales must consist of "qualifying electricity" or RECs, equal to 20 percent of its
adjusted retail electricity sales. Unlike other state RPS policies, Utah's does not include any interim targets
and the first compliance year is 2025.
In early 2010, the Utah legislature passed H.B. 192 "Renewable Energy—Methane Gas," which amended
the definition of "renewable energy source" to include "methane gas from an abandoned coal mine or a
coal degassing operation associated with a state-approved mine permit" as part of waste gas or waste
heat captured or recovered for use as an energy source for an electric generation facility. Initially, the bill
included methane gas from abandoned and working coal mines; however, the Senate Transportation and
Public Utilities and Technology Committee's proposed Amendment 01 put the term "working" in front of
"coal mines" as a potential methane gas resource that might qualify as renewable energy. The Senate and
House approved the amendment, effective May 11, 2010.
Utilities may meet targets by producing electricity with an eligible form of renewable energy or by
purchasing RECs. RECs issued under the program do not expire.
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