November 2014
Economic Analysis: Proposed
Revisions to the Health and
Environmental Protection
Standards for Uranium and
Thorium Mill Tailings Rule
(40CFRPart 192)
Draft Report
U.S. Environmental Protection Agency
Office of Radiation and Indoor Air
Radiation Protection Division
1200 Pennsylvania Avenue
Washington, DC 20460
EPA 402-R-14-003
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RTI Project Number
0212979.003.017
Economic Analysis: Proposed
Revisions to the Health and
Environmental Protection
Standards for Uranium and
Thorium Mill Tailings Rule
(40CFRPart 192)
November 2014
Draft Report
Valentine (Val) T. Anoma
U.S. Environmental Protection Agency
Office of Radiation and Indoor Air
1200 Pennsylvania Avenue
Washington, DC 20460
Prepared by
RTI International
3040 E. Cornwallis Road
Research Triangle Park, NC 27709
RTI International is a trade name of Research Triangle Institute.
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CONTENTS
Section Page
1 Introduction 1-1
1.1 Background for the Proposed Rule 1-1
1.2 Statement of Need for Policy Action 1-2
1.2.1 Protection of Human Health and the Environment 1-2
1.2.2 Need for Regulatory Intervention Because of Market Failure 1-2
1.3 Organization of the Report 1-3
2 Profile of the Affected Industry: Uranium Extraction and Processing 2-1
2.1 Introduction 2-1
2.1.1 Uranium Extraction and Processing Sector, NAICS 212291 2-1
2.1.2 Uranium Shipments 2-2
2.2 Supply of Uranium 2-2
2.2.1 Production Process 2-5
2.2.2 Inputs Used in ISR Uranium Production 2-8
2.2.3 Production Costs 2-8
2.2.4 Pollution Control 2-9
2.3 Demand for Uranium 2-10
2.3.1 Characteristics of the Product (Yellowcake) 2-10
2.3.2 Uses and Consumers 2-11
2.3.3 Substitutes 2-12
2.4 Industry Organization 2-12
2.4.1 Market Structure 2-12
2.4.2 Small Businesses 2-14
2.5 Market for U3O8 2-15
2.5.1 U.S. Consumption 2-15
2.5.2 U.S. Uranium Production 2-17
2.5.3 International Trade 2-19
in
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2.5.4 Market Prices 2-20
2.5.5 Industry Trends 2-22
2.5.6 Projections 2-22
3 The Proposed Rule and its Estimated Costs 3-1
3.1 Description of Proposed Regulation 3-1
3.1.1 Groundwater Protection Standards 3-1
3.1.2 Monitoring Requirements 3-2
3.1.3 Other Regulatory Alternatives for Long-Term Monitoring
Considered but Rejected 3-5
3.2 Estimated Incremental Costs of Compliance with Proposed Rule 3-6
3.2.1 Technical Approach: Conceptual Site Model Facility 3-7
3.3 Estimated National Costs of Proposed Rule 3-24
3.4 Uncertainties and Limitations 3-27
4 Benefits Analysis 4-1
4.1 Conceptual Framework and Methods for Valuing Groundwater Resources
and Groundwater Protection 4-1
4.2 The Benefits of Proposed Changes in Monitoring Requirements 4-4
4.2.1 Reducing Potential Human Health Risks Associated with
Contaminant Exposures 4-5
4.2.2 Protecting Groundwater Resources for Future Generations 4-6
4.2.3 Avoiding Potential Future Remediation Costs 4-7
4.3 Setting Groundwater Protective Standards 4-10
4.4 Comparison of Benefits and Costs of the Proposed Rule 4-11
4.5 Caveats and Uncertainties 4-11
5 Economic Impact Analysis 5-1
5.1 National Costs 5-1
5.2 Market Impact Assessment 5-2
5.2.1 Market Simulation Model 5-3
IV
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5.2.2 Characteristics of Market Demand for Uranium 5-4
5.2.3 Characteristics of Market Supply 5-5
5.2.4 Impacts of the Proposed Rule 5-6
5.3 Summary of Economic Impact Results 5-6
5.4 Employment Impacts of the Proposed Rule 5-7
5.5 Impacts on Small Entities 5-8
5.6 Uncertainties 5-10
6 Statutory and Executive Order Reviews 6-1
6.1 Synopsis 6-1
6.2 Executive Order 12866: Regulatory Planning and Review and Executive
Order 13563: Improving Regulation and Regulatory Review 6-1
6.3 Paperwork Reduction Act 6-4
6.4 Regulatory Flexibility Act 6-4
6.5 Unfunded Mandates Reform Act (UMRA) 6-6
6.6 Executive Order 13132: Federalism 6-6
6.7 Executive Order 13175: Consultation and Coordination with Indian Tribal
Governments 6-6
6.8 Executive Order 13045: Protection of Children from Environmental
Health Risks and Safety Risks 6-6
6.9 Executive Order 13211: Actions Concerning Regulations That
Significantly Affect Energy Supply, Distribution or Use 6-7
6.10 National Technology Transfer and Advancement Act 6-7
6.11 Executive Order 12898: Federal Actions to Address Environmental Justice
in Minority Populations and Low-Income Populations 6-8
7 Conclusions 7-1
References 1
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Appendixes
A Unit Costs for Wells and Borings A-l
B Summary of Unit Costs for Sampling and Analysis B-l
C Simulation of Remobilized Uranium from a Restored ISRMine C-l
D Sensitivity Analysis: Estimated Costs and Economic Impacts D-l
VI
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LIST OF FIGURES
Number
2-1 Diagram of ISR Uranium Operation 2-6
2-2 Schematic Diagram of a Wellfield Showing Typical Injection/Production Well
Patterns, Monitoring Wells, Manifold Buildings, and Pipelines 2-7
2-3 Location of ISR Uranium Production 2-18
3-1 ISL/ISR Conceptual Site Model Applicable to Current Practice and 30-Year
Monitoring 3-8
3-2 ISL/ISR Conceptual Site Model Applicable to Geochemical Modeling Scenario 3-9
4-1 Main Components of the Total Economic Value (TEV) of Groundwater
Resources 4-2
5-1 Market Equilibrium Without and With Regulations 5-4
vn
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LIST OF TABLES
Number
2-1 U.S. U3O8 Shipments (Million Pounds) 2-3
2-2 Total U.S. Amount of U3O8 Produced (Million Pounds U3O8) 2-4
2-3 Domestic Uranium Industry Production Expenditures ($Million) 2-11
2-4 Owner Companies for ISR Facilities: Existing and Planned 2-14
2-5 Uranium Purchased by U.S. COOs, 1994-2013 (Million Pounds U3O8
Equivalent) 2-16
2-6 Total Amount U3O8 Produced in the United States (Thousand Pounds U3O8) 2-17
2-7 In situ Recovery Plants in the United States, and Status (2013) 2-19
2-8 Weighted-Average Price of Uranium Purchased by U.S. COOs Based on
Contract Type 2-21
3-1 1 to Subpart F of Part 192Maximum Concentration of Constituents for
Groundwater Protection at ISRFacility Sites 3-2
3-2 ISR Conceptual Mine Unit: Current Practice 3-12
3-3 ISR Conceptual Mine Unit: 30-Year Stability Shortened with Geochemical
Modeling 3-14
3-4 ISR Conceptual Mine Unit: 30-Year Stability with No Provision to Shorten 3-17
3-5 ISR Conceptual Mine Unit: Annual Monitoring Cost by Scenario and Phase
(Thousand $2011) 3-21
3-6 ISR Conceptual Mine Unit: Annualized Monitoring and Capital Costs for
Current Practice and Each Regulatory Scenario (Thousand $2011) 3-23
3-7 Estimated Total Acreage of All Wellfields at ISR Sites 3-25
3-8 Total Average Annualized Incremental Costs for Individual ISR Operations
(Thousand 2011$) 3-26
3-9 Estimated Average National Incremental Cost Summary (Thousand 2011$) 3-27
3-10 Incremental Total Capital Costs (Thousand 2011$) 3-27
4-1 Summary of Avoided Remediation Cost Estimates for Model Facility with Post-
restoration Groundwater Contamination (million 2011 $) 4-10
5-1 Projected U.S. Uranium Market Conditions, 2015 5-3
5-2 Market Impacts of Proposed Rule based on Average Costs, 2014 5-7
5-3 Estimated Impacts of the Proposed Rule on Small Entities 5-9
7-1 Comparison of Costs of Complying with the Proposed Rule and Costs of
Remediating Contaminated Groundwater (Million 2011$) 7-4
Vlll
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EXECUTIVE SUMMARY
Section 206 of the Uranium Mill Tailings Radiation Control Act of 1978 (UMTRCA)
requires the U.S. Environmental Protection Agency (EPA) to develop health and environmental
standards for both Title 1 sites (inactive uranium mills) administered by the U.S. Department of
Energy and Title II sites (present and future operations) licensed by the U.S. Nuclear Regulatory
Commission (NRC) or its Agreement States. EPA is proposing revisions to its regulations at 40
CFR Part 192 for in situ recovery/in situ leaching (ISR) facilities that produce uranium by
injecting and extracting a solution that dissolves the uranium from the porous minerals in which
it is found. ISR uranium production represents an increasing share of uranium production and
poses special groundwater protection challenges compared with conventional uranium
production abroad and particularly in the United States, because it solubilizes and mobilizes
uranium and other constituents and changes the geochemistry within the aquifer containing the
uranium deposit. If geochemistry and groundwater conditions are not restored after ISR
operations cease and the restoration is not stable over time, the groundwater in aquifers
surrounding the wellfield may become contaminated with uranium and other constituents.
Currently, facilities monitor groundwater for only a year or two after the restoration effort is
complete before decommissioning the site. This duration of monitoring may not be long enough
to detect instability or trends in constituent concentrations over time, which poses a risk of
contaminating groundwater resources and potentially exposing human or ecological receptors to
hazardous constituents. Accordingly, EPA is proposing to add a new subpart to 40 CFR Part 192,
establishing additional monitoring requirements during all phases at an ISR facility:
Pre-operational monitoring: measuring background groundwater concentrations and
establishing initial regulatory approved restoration goals
Operational monitoring: monitoring to detect any excursions of contaminated
groundwater to adjacent aquifers, either beside, above, or below the exempted aquifer
Restoration monitoring: monitoring to document the progress of restoration through
groundwater sampling
Post-restoration stability monitoring, which has two parts:
Stability monitoring: monitoring, conducted after restoration efforts have ended to
establish that wellfield groundwater characteristics are stable and meet restoration
goals (at least 3 years)
- Long-term stability monitoring: monitoring and statistical analyses to show that
the concentration of each monitored constituent is not increasing with time and
that the concentration is not statistically different from the restoration goals
ES-1
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EPA's proposed rule requires careful pre-operational monitoring to ensure that
restoration goals are set appropriately, taking into account seasonal and other variability in
analyte concentrations. The proposed rule also identifies the minimum 13 constituents that
should be monitored and causes the standards to update automatically if standards under the Safe
Drinking Water Act or the Resource Conservation and Recovery Act are updated.1 Probably the
most significant requirements in the proposed rule pertain to post-restoration stability
monitoring. As noted above, currently ISR facilities monitor groundwater for periods of 6
months to 2 years before beginning the decommissioning process. EPA's proposed rule requires
stability monitoring sufficient to demonstrate statistically with 95% confidence that wellfield
conditions are stable and then continued long-term stability monitoring for 30 years, with
provisions for shortening the monitoring duration based on geochemical modeling. EPA is
proposing a provision that would allow the regulatory agency to shorten the monitoring period if
the operator can both demonstrate geochemical stability through monitoring and support a
conclusion of long-term stability through geochemical modeling. Geochemical modeling has the
potential to provide confidence that a geochemical mechanism exists to prevent uranium and
other constituents from remobilizing and migrating to aquifer locations that may be used for
drinking water and, thus, provides additional assurance beyond that provided by longer
monitoring periods and statistical modeling. Throughout this document, EPA uses the term
"proposed rule" to refer to this set of monitoring requirements, along with other requirements
such as corrective action in the event that an excursion is detected and more comprehensive
monitoring at the preoperational phase. EPA also considered two other regulatory options for
long-term stability monitoring:
30 years of long-term stability monitoring with no potential to change the duration
a narrative standard with no fixed monitoring period
EPA chose to propose the standard that includes geochemical modeling because it has the
potential to demonstrate that groundwater conditions will remain stable; the other two
alternatives do not. Because the uranium deposits for which ISR methods are appropriate were
created initially due to chemically reducing geological conditions, EPA considers it likely that
many ISR facilities will be able to demonstrate, through geochemical modeling and monitoring,
the existence of geochemical conditions that would promote long-term stability. However, EPA
recognizes that in some cases, sampling and geochemical modeling will reveal that geological
1 Once an ISR facility is licensed and permitted, standards existing at the time of licensing are applied to the facility,
but new license applications would be subject to the updated standards.
ES-2
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conditions would not guarantee long-term stability. In those cases, the regulatory agency may
refuse to grant a license to conduct ISR operations; alternatively, the regulatory agency would
likely require additional restoration and/or a 30-year monitoring period to demonstrate that
conditions are stable. EPA estimated the costs that would be incurred should the owner/operator
be required to monitor for 30 years in addition to conducting geochemical analyses.2
EPA examined the costs that could be incurred by ISR facilities to comply with two
regulatory options, the proposed rule and the option characterized by 30 years of long-term
stability monitoring with no potential to shorten the duration, under a variety of costing scenarios
(see Appendix D for details on the range of costs). In addition, EPA estimated costs for a "worst
case" scenario, under which post-operational geochemical modeling does not provide assurance
that conditions would remain stable over time; in this case, EPA assumes that the facility would
be required to continue long-term stability monitoring for 30 years to ensure that conditions
remain stable. For reasons explained in Section 3, however, EPA believes this situation would be
unlikely to arise; thus, the impacts of this third scenario are presented only in Appendix D. EPA
did not estimate costs for the narrative standard with no fixed monitoring period because the
specific compliance requirements and costs would be defined on a case-by-case basis and are,
thus, too uncertain to model.
To estimate the incremental costs of compliance under each option considered, EPA used
a model facility approach and developed a conceptual mine unit (CMU) derived from a section
of one wellfield at an existing ISR facility. EPA then estimated the monitoring that such a mine
unit would undertake under current practice and under each of the regulatory alternatives. The
incremental costs for the CMU (computed as the costs under a regulatory alternative minus the
costs under current practice) were then scaled up to costs that would be incurred by actual ISR
facilities based on relative total acreage of wellfields at actual facilities to the acreage of the
CMU. Total annualized costs for each regulatory option and cost scenario considered, annualized
at 7%, are shown in Table ES-1. EPA presents low, average, and high monitoring cost estimates
for each regulatory alternative. EPA computed estimated facility costs as if all wellfield acreage
at ISR facilities in the country were simultaneously affected. EPA recognizes the fact that at
: In tables such as ES-1 and throughout this report, the regulatory alternatives are described in terms of the required
long-term stability monitoring; in fact, EPA expects that compliance requirements of the preoperational,
operational, restoration, and stability monitoring may differ among the alternatives as well. The long-term
stability monitoring requirements are used as a shorthand description of the regulatory alternative. The assumed
requirements of each alternative are described in detail, along with the baseline regulatory requirements typically
in practice at ISR facilities in the absence of the rule, and are presented in Tables 3-1 through 3-4, and the
estimated costs under each alternative for the CMU are shown in Table 3-5.
ES-3
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many ISR facilities, there are wellfields in all stages of ISR operations from planning to
decommissioned, so monitoring activities would not typically be required at every wellfield
simultaneously. Thus, EPA's costs are believed to overestimate costs that would be incurred by
actual facilities. Further, EPA's analysis defines these costs as incremental to the costs of current
practice at ISR facilities; because many of the compliance requirements may already be
embodied in license requirements, this may overestimate the incremental costs of the rule.
However, EPA has chosen to analyze the costs and economic impacts under these conservatively
high costing assumptions. As shown in Table ES-1, EPA estimates that nationally the cost of the
proposed regulatory alternative ranges from $11.6 million to $17.9 million per year, depending
on the cost scenario.
Table ES-1. Estimated Range of National Compliance Costs by Regulatory Alternative and
Costing Scenario (Million 2011$)
Regulatory Alternative
30 years with geochemical modeling to shorten
30 years with no shortening
Low
11.631
12.865
Average
13.465
15.072
High
15.226
17.901
EPA then examined the potential impact of the proposed rule on the market for uranium.
Uranium is relatively homogeneous, so buyers do not care which mine or ISR facility produced
it; the market for uranium is an international market, with suppliers and demanders in many
countries. The United States has historically been the largest user of uranium for electricity
production but has generally produced only a small share of the uranium it consumes, and
foreign suppliers have provided the remaining 80% to 90%. Going forward, the U.S. Energy
Information Administration (EIA) projects that the worldwide demand for uranium will grow
substantially over the next 20 years, due largely to increased demand from China and India;
prices are also projected to increase to approximately $64 per pound UsOg by 2018. Owners and
operators of U.S. civilian nuclear power reactors ("civilian owner/operators" or "COOs")
purchased a total of 57.4 million pounds of uranium during 2013 at a weighted-average price of
$51.99 per pound UsOg. Seventeen percent of the UsOg delivered in 2013 was U.S.-origin
uranium at a weighted-average price of $56.3 per pound (EIA, 2014b). EPA projects the 2015
U.S. price of uranium will be $57.00.
The proposed rule would increase the cost of producing uranium at ISR facilities by
between $1.30 and $2.00 per pound, depending on the alternative and whether low, average, or
high costs of compliance are considered. Because domestically produced uranium is a small
ES-4
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share of the total U.S. supply (about 17% in 2013) and ISR operations are not the only suppliers
of domestic uranium, ISR facility operators would have only a limited ability to pass these costs
along to their customers. As a result, EPA estimates that the price of uranium is likely to increase
by between $0.21 and $0.32 per pound as a result of the proposed rule.
EPA estimated the impact of the proposed rule on the market for uranium using a
simplified model of the U.S. market for uranium in 2015, the base effective date for the proposed
rule. The model estimated, based on the unit cost of the proposed rule and characteristics of the
supply and demand for uranium in the United States, changes in the quantity of uranium
purchased by U.S. COOs of nuclear power plants, changes in the domestic sales of uranium and
imports, and changes in the market price for uranium. EPA found that overall the market
quantity of uranium purchased for use in electric generation would decline by less than 0.1% and
the market price would increase by approximately 0.5%. Domestic ISR facilities would decrease
their production by approximately 3% to 6%, and imports of uranium would increase by less
than 1%. Because the cost of uranium is a very small share of the cost of electricity, EPA
estimates that the cost of generating electricity would increase by less than 0.1%. Table ES-2
summarizes the estimated market impacts based on the unit cost of the proposed rule under low-
cost and higher cost sets of assumptions. As expected, the low-cost assumptions have a smaller
impact on the market for uranium than the average-cost assumptions, while the high-cost
assumptions have a greater effect on the market.
Although the national total annual cost of the proposed rule (approximately $13.5 million
to $15.1 million based on average costs) is well below the $100 million threshold that is one of
the criteria used to identify a significant regulatory action, the industry has only a small number
of companies operating a small number of ISR operations. EPA used existing ISR operations and
the companies that own them as models for the types of facilities and companies that would
potentially be affected by the proposed rule. EPA thus estimated the ISR facilities would incur
annual costs of compliance between $262,000 and $12.7 million, depending on the scale of the
operation, the alternative, and the costing assumption used. For small firms owning ISR
facilities, EPA estimated cost-to-sales ratios between 0.6% and 2.2%, which would likely not be
significant based on the criteria for significance in EPA's final Regulatory Flexibility Act
(RFA)/Small Business Regulatory Enforcement Fairness Act (SBREFA) guidance (EPA, 2006).
Because EPA estimates that compliance costs would not cause a significant impact and because
only a few small businesses (10 or fewer, based on current information) would be affected by the
proposed rule, EPA concluded that the rule would not have a significant impact on a substantial
number of small entities.
ES-5
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Table ES-2. Estimated Impacts on the U.S. Market for Uranium, 2014a
Baseline
Supply (million pounds) 57,630
U.S. origin 9,451
Foreign origin 48, 179
Price $57.00
Change in price
Percentage changes
Market quantity
U.S. origin
Foreign origin
Price
Incremental cost per pound of uranium
Low
57,616
9,089
48,527
57.21
$ 0.21
-0.02%
-3.8%
0.7%
0.4%
$1.30
With Proposed
Average
57,614
9,032
48,582
57.24
$ 0.24 $
-0.03%
-4.4%
0.8%
0.4%
$1.50
Rule
High
57,612
8,977
48,635
57.27
0.27
-0.03%
-5.0%
0.9%
0.5%
$1.70
aCosts and economic impacts are based on the proposed rule (30-year stability with geochemical modeling to
shorten), and low, average, and high monitoring cost estimates. Market impacts based on other costing
assumptions are provided in Appendix D.
EPA's qualitative benefits assessment presents a discussion of the expected effects of the
proposed rule on human and environmental health. EPA expects that the improved monitoring
program proposed will reduce the risk of contaminating valuable groundwater resources, thus
also reducing potential exposure to radiological and nonradiological contaminants in
groundwater and potentially in surface water to which affected aquifers discharge. Because the
major risk of exposure to radiological constituents is cancer, the proposed rule has the potential
to reduce cancer risks.
If uranium and other constituents remobilize in groundwater over time, and if monitoring
ends too soon and sites are prematurely decommissioned, it is possible that groundwater in
surrounding aquifers could be contaminated, and it might be many years before the
contamination is detected. EPA simulated groundwater contamination using its CMU model
facility under varying assumptions and estimated the costs of corrective action to remediate the
groundwater contamination. Based on these simulations, the cost of remediation would far
exceed the costs of complying with the proposed rule, both on an annual and total basis. For the
model facility simulations, this subset of benefits (avoided remediation costs) exceeded the costs
of complying with the proposed rule. Further, if contamination were detected after
decommissioning, the costs of remediation could be borne by the taxpayer or the land owner
ES-6
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rather than the uranium company owner/operator (if, for example, the company no longer exists
or so much time has passed that the association is not made between the contamination and the
former ISR operation). EPA was unable, however, to estimate potential avoided costs of
remediation on a national scale and thus was unable to quantify the rule's net benefits
nationwide.
ES-7
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Section 1
INTRODUCTION
1.1 Background for the Proposed Rule
In accordance with Section 206 of the Uranium Mill Tailings Radiation Control Act of
1978 (UMTRCA) Section 206, the U.S. Environmental Protection Agency (EPA) is authorized
to develop generally applicable standards for the protection of public health, safety, and the
environment from radiological and nonradiological hazards associated with the processing,
possession, transfer, and disposal of by-product material (tailings or wastes) at sites where ores
are processed primarily for their uranium content. In 1983, EPA promulgated regulations at 40
CFR Part 192, Health and Environmental Protection Standards for Uranium and Thorium Mill
Tailings, in response to the statutory requirements of UMTRCA. When the Agency promulgated
40 CFR Part 192, uranium recovery from ore was based almost exclusively on the conventional
milling process, where a few pounds of uranium were recovered for each ton of ore mined and
processed, and large quantities of radioactive by-product material, or "tailings," accumulated in
impoundments at the mill site. Concern that these impoundments would be a continuing source
of radiation exposure unless properly reclaimed was the driving force behind the passage of
UMTRCA, which mandated how they should be managed to avoid releases of radioactive
material or other hazardous constituents to ground or surface water.
EPA last revised its regulations for uranium and thorium milling in 1995. Since 40 CFR
Part 192 was promulgated, there has been a shift in uranium recovery technology from
conventional mining and milling to in situ recovery (ISR) where, in a sense, a portion of the
milling process is conducted underground within the ore body. In the ISR process (sometimes
referred to as in situ leaching [ISL]),3 oxidizing chemical solutions called lixiviants are pumped
underground through an array of wells into the ore body, where the uranium is dissolved in
place. The uranium-rich solutions are pumped to the surface where the uranium is extracted
(EPA, 2012b).
EPA has reviewed the existing 40 CFR Part 192 standards to determine if the
requirements are appropriate for ISR. As a result of this review, EPA determined that the
requirements should be revised and is proposing a new subpart that establishes groundwater
restoration goals and monitoring requirements at ISR facilities.
3 Throughout the rest of this report, the abbreviation ISR is used for simplicity; ISL is another widely used
abbreviation for this uranium extraction and processing method.
1-1
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1.2 Statement of Need for Policy Action
1.2.1 Protection of Human Health and the Environment
EPA has concluded, after reviewing the current language in 40 CFR Part 192, that Part
192 needs to be revised to specifically address the environmental risks posed by ISR uranium
operations. The ISR process directly alters groundwater chemistry through injecting the aquifer
in which the uranium is found with mobilizing agents. Mobilizing uranium in the formation can
also liberate other elements, potentially contaminating surrounding aquifers. If such
contamination occurs, the contaminants have the potential to move with the groundwater,
reducing the quality of valuable groundwater resources and possibly ultimately reaching drinking
water wells or surface water. To ensure that public health, safety, and the environment are
protected, EPA must ensure that groundwater restoration is adequate after ISR operations cease;
this is particularly important because current Nuclear Regulatory Commission (NRC) regulations
allow ISR operators to terminate their licenses soon after restoration is complete (sometimes less
than 1 year), essentially ending oversight of the site. After that, they may either sell the property
or, if leased, return it to its owners. EPA's research (U.S. EPA, 2012a) indicates that there is a
risk that the groundwater may once again become contaminated with uranium or other
constituents after restoration and stability monitoring ends. For example a U.S. Geological
Survey case study of pilot ISR projects documented that some constituent concentrations
increased after the end of stability monitoring. (USGS, 2009) More recently, research conducted
by U.S. Department of Energy's Office of Legacy Management found that groundwater flushing
at UMTRCA sites is slower and more complex than originally thought. (Shafer et al., 2014)
Depending on the exposure pathways, contaminated groundwater may pose a risk to human
health, livestock health, or the environment. Thus, EPA has concluded that current standards in
40 CFR Part 192 should be revised to require, among other things, an adequate post-restoration
monitoring period.
1.2.2 Need for Regulatory Intervention Because of Market Failure
In general, regulatory intervention is required only when markets fail to allocate
resources efficiently. For markets to allocate resources efficiently, both buyers and sellers must
have access to full information about the transaction; there must be many buyers and sellers so
that neither buyers nor sellers have power to control prices; and the market must impose all the
social costs of the transaction on the buyers and sellers in the market. In some situations,
however, these conditions do not occur, and markets fail to allocate resources efficiently. One
such market failure occurs in cases where a production or consumption activity imposes an
external cost on members of society who are neither buyers nor sellers in the market for the good
1-2
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or service produced. In cases of external costs, or "externalities," some costs are imposed on
members of society who are not part of the market. Because the market is not affected by these
costs, it fails to allocate resources efficiently, and government must intervene to make the
outcome more efficient. Environmental pollution that results from a production process is an
example of an external cost borne by members of society who are neither producers nor
consumers of the good whose production is generating the pollution.
In the case of ISR uranium operations, a key market failure that requires regulatory
intervention is the potential for operations to contaminate groundwater aquifers. If groundwater
quality is not adequately restored and adequately monitored during and after the operating
period, the ISR operations have the potential to degrade groundwater resources and to expose
humans and ecological receptors to contaminated groundwater or surface water, imposing costs
on members of society who are neither buyers nor sellers in the market for uranium. Further, if
the contamination is discovered after an operation is decommissioned and its license terminated,
and perhaps after the company that owned it is out of business, the costs of remediating the
contamination may be incurred by the landowner or the taxpayer of the state in which the mine
was located, rather than by the mine owners and operators, a violation of the "polluter pays"
principal generally used to "internalize" the external costs of a polluting activity.
In the proposed rule, EPA is proposing to establish groundwater monitoring requirements
for several phases of an ISR operation, including pre-operational monitoring to establish baseline
groundwater conditions, ISR operation, wellfield restoration, and post-restoration stability
monitoring to establish that restored groundwater quality is stable. In addition, if contamination
is identified during the monitoring, the proposed rule requires the ISR facility owners and
operators to undertake corrective action to correct the contamination and then to monitor to
demonstrate that it has been successfully corrected.
1.3 Organization of the Report
The remainder of this economic analysis is organized as follows:
Section 2 presents a profile of the uranium production industry.
Section 3 describes the proposed rule and the estimated costs of complying with it.
Section 4 presents a qualitative discussion of the benefits of the proposed rule.
Section 5 describes the estimated economic impacts of the proposed rule.
1-3
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Section 6 describes analyses EPA conducted to assess impacts of statutes and
Executive Orders.
Section 7 presents EPA's conclusions.
1-4
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Section 2
PROFILE OF THE AFFECTED INDUSTRY: URANIUM EXTRACTION AND
PROCESSING
This section describes the uranium extraction and processing industry, with particular
emphasis on ISR producers. The section provides background information that supports EPA's
economic impact assessment and also EPA's assessment of possible impacts on small entities
under the Regulatory Flexibility Act and the Small Business Regulatory Enforcement Fairness
Act (RFA/SBREFA).
The section is organized as follows. Section 2.1 provides a brief introduction to the
domestic uranium extraction and processing industry. Section 2.2 describes processes involved
in extracting and processing uranium using the ISR process. Section 2.3 describes the products
and users of finished uranium oxide concentrate or yellowcake (UsOg) products. Section 2.4
discusses the organization of the industry as a whole, including facility- and company-level data.
Within this section, small businesses are identified so that EPA can evaluate the impact of the
proposed rule on these businesses under the requirements of SBREFA. Section 2.5 assesses
market-level data on quantities and prices. The section discusses projections and trends within
the uranium production industry.
2.1 Introduction
This section examines the market for uranium, including an examination of the
production processes, production costs, and quantities or uranium supplied. In addition, this
section examines the demand for uranium. The uranium extraction and processing sector
produces uranium which, after undergoing conversion and enrichment, can be used as fuel in
nuclear reactors. The industry being examined includes facilities that extract uranium using a
variety of technologies and facilities that process the raw uranium into UsOg, or "yellowcake,"
which is then shipped to uranium conversion, enrichment, and fuel fabrication facilities. The
main users (demanders) of uranium are utilities that operate nuclear reactors. Both supply and
demand for uranium are discussed below.
2.1.1 Uranium Extraction and Processing Sector, NAICS 212291
Establishments engaged in the extraction and processing of uranium to produce fuel for
electricity generation form the core of the industry. Fuel for nuclear power plants is the primary
commercial use for uranium (EIA, 2014a). The U.S. industry falls under the North American
Industry Classification System (NAICS) code of uranium-radium-vanadium mining (212291)
(NAICS, 2012). Facilities in this industry extract uranium from uranium deposits and process it,
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producing uranium oxide concentrate or yellowcake, with the chemical formula
According to the 2009 Statistics of U.S. Businesses, a total of 28 establishments were operating
under this NAICS code (Census, 2011).
2.1.2 Uranium Shipments
In 2013, a total of 4.7 million pounds of uranium concentrate were shipped in the U.S.
industry, which is 0.8 million pounds more than in 2012 (Table 2-1). Shipments of uranium
concentrate have fluctuated widely over the last 21 years for a variety of reasons, including
changes in international demand for and supply of uranium.
2.2 Supply of Uranium
Uranium can be produced using conventional mining methods (underground or open-pit
mining), coupled with either conventional milling or heap leaching. Conventional milling entails
grinding the ore, placing it in a tank, and exposing it to an acid or alkaline solution to leach the
uranium out of the ore. Heap leaching entails placing a pile of the ground ore on a pad and
pouring the leaching solution over it. The uranium, in the form of UsOg or "yellowcake," is then
physically separated from the other materials in the ore, chemically extracted, precipitated out of
the solution, concentrated, dried, and packaged for shipment.
Alternatively, instead of conventional mining and milling, uranium can be produced
using the ISR process. Some uranium ore bodies are located within porous material such as
gravel or sandstone that is saturated in groundwater. The ore is accessible through mobilizing the
uranium and pumping it out (World Nuclear Association [WNA], 2012a). Where the ore body is
amenable to use of the ISR technology, uranium can be recovered economically without the
extensive surface facilities, ore pads, large waste volumes, or expectations of long-term site
maintenance associated with conventional milling. In the ISR process, oxidizing chemical
solutions called lixiviants are pumped through an array of injection wells into the ore body where
the uranium is solubilized. The uranium-rich solutions are pumped to the surface through
extraction wells, then piped or transported to a processing plant where the uranium is recovered
from the solution through an ion exchange process, and further processed prior to shipment,
similar to the processing described in the previous paragraph. The solutions are then recharged
with the lixiviant chemicals and pumped back into the ore body to recover additional uranium
(EPA, 2012b). Any waste water that is not reinjected into the ore body may be injected into a
deep well for disposal, sent to an impoundment or evaporation pond on site, or treated prior to
land disposal.
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Table 2-1. U.S. IbOs Shipments (Million Pounds)
Year Uranium Concentrate Shipments
1993 3.4
1994 6.3
1995 5.5
1996 6.0
1997 5.8
1998 4.9
1999 5.5
2000 3.2
2001 2.2
2002 3.8
E2003 1.6
2004 2.3
2005 2.7
2006 3.8
2007 4.0
2008 4.1
2009 3.6
2010 5.1
2011 4.0
2012 3.9
2013 4.7
E = Estimated data.
Note: The 2003 annual production and shipment amounts were estimated by rounding to the nearest 200,000 pounds
to avoid disclosure of individual company data.
Source: U.S. Energy Information Administration: 1993-2002-Uranium Industry Annual 2002 (May 2003), Table
HI and Table 2. 2003-2012-FormEIA-851 A, "Domestic Uranium Production Report" (2003-2014).
After extracting and processing, the final product of the ISR operation is uranium oxide
concentrate (UsOg), commonly referred to as yellowcake (U.S. NRC, 2012b). Often, the
extraction and processing are done at the ISR site. In some cases, one facility extracts the
uranium and sends it to be processed in another location. One example of this is the La
Palangana facility in Duval County, Texas, which extracts the uranium and sends it to the
Hobson Processing Plant, located about 100 miles away in Karnes County, Texas, for processing
and packaging. Section 2.2.1 provides more detail about the ISR uranium extraction process.
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Total U.S. production of uranium is the sum of uranium produced using each technology.
Table 2-2 presents historical data on quantities of UsOg produced.
Table 2-2. Total U.S. Amount of IbOs Produced (Million Pounds IbOs)
Year
1993
1994
1995
1996
1997
1998
1999
2000
2001
2002
E2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
Mine Production of Uranium
2.1
2.5
3.5
4.7
4.7
4.8
4.5
3.1
2.6
2.4
2.2
2.5
3.0
4.7
4.5
3.9
4.1
4.2
4.1
4.3
4.6
Uranium Concentrate Production
3.1
3.4
6.0
6.3
5.6
4.7
4.6
4.0
2.6
2.3
2.0
2.3
2.7
4.1
4.5
3.9
3.7
4.2
4.0
4.1
4.7
E = Estimated data.
Source: U.S. Energy Information Administration: Form EIA-851 A, "Domestic Uranium Production Report," 2003-
2014.
Production of yellowcake is the first step in a multistep process to produce nuclear fuel.
The yellowcake is shipped to conversion facilities that convert it into uranium hexafluoride
(UFe), which in turn is shipped to facilities that enrich it and fabricate it into fuel assemblies for
nuclear power plants.
Total domestic supply is a sum of the annual amount of uranium mined in the United
States and processed into yellowcake and the amount of uranium that was stockpiled in previous
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years and during the current year is converted to yellowcake. The annual amount of uranium
mined and the amount processed into UsOg do not always match; for example, in 1993 only 2.1
million pounds of uranium-equivalent was extracted, while 3.1 million pounds were actually
processed into UsOg. The discrepancy is largely due to quantities of uranium added to
inventories or taken out of inventories in response to market forces.
2.2.1 Production Process
The ISR process has been used since the 1960s in the United States for extracting
uranium from sandstone type uranium deposits that were not suitable for open pit or underground
mining. Many sandstone deposits are amenable to uranium extraction by ISR, which is now a
well-established technology that accounted for more than 28% of the world's uranium
production in 2009. The basic requirement for ISR is that the mineralization is located in water-
saturated permeable formations that allow effective confinement of mining solutions (commonly
confined between impermeable clay-rich strata) (DRET, 2010).
Figure 2-1 shows a simplified diagram of an ISR uranium operation. Uranium is
extracted by means of an acid or alkaline leaching solution (lixiviant) that is pumped down
injection wells into the permeable mineralized zone to mobilize uranium from the ore body. The
uranium-rich solution is pumped to the surface via nearby recovery wells, and the uranium is
recovered in the processing plant by hydrometallurgical processing, typically ion exchange or
solvent extraction (particularly for highly saline waters). The mining solution is regenerated and
recycled (DRET, 2010). The recovered uranium undergoes further processing and packaging and
is shipped off site in the form UsOg, or yellowcake, to a facility where it will be converted into
UFe. Next, the UFe will be enriched to increase the amount of 235U, after which it will undergo
fabrication into fuel for nuclear reactors (NRC, 2012a).
The life cycle of an ISR facility involves the following stages:
Exploration and development to establish that a commercially viable operation is
possible.
Establishment of site baseline conditions for ISR (mining) of the ore body.
Recovery of uranium from the ore body.
Restoration of the groundwater to predetermined conditions.
Demonstration that restored groundwater is stable.
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Long-term stability monitoring of the groundwater to ensure groundwater quality
remains stable.
Decommissioning of mined area and surface facilities.
Figure 2-1. Diagram of ISR Uranium Operation
Resin Transfer
(Cleaned resin stripped
of uranium)
Uranium in Solution
Spent
Eiuate sent
to Disposal
Well or
Evaporation
Pond
Washing and
Dewatermg
i
I
Source: http://www.tceq.texas.gov/assets/public/permitting/rad/insitu/in_situ_diagram.jpg
Source: DRET, 2010, p. 3.
During ISR operations, the most common injection/pumping patterns are five and seven
spot (NRC, 2003). The shape of the mineralized ore body and surface topography, however, may
give rise to other patterns (NRC, 1997). A typical five-spot pattern contains four injection wells
and one recovery well. The dimensions of the pattern vary depending on the mineralized zone,
but the injection wells are generally between 40 and 150 feet apart. To effectively recover the
uranium and also to complete the groundwater restoration, the wells are often completed so that
they can be used as either injection or recovery wells. During recovery operations, a slightly
greater volume of water will be recovered from the mineralized zone aquifer than was injected to
create a cone of depression or a flow gradient toward the recovery wells. This practice is
intended to minimize excursions of leachate outside the production area. Groundwater
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monitoring is necessary to detect any excursions of lixiviant outside the mining area during
operations. Figure 2-2 shows typical well arrangements using five- and seven-spot patterns and
illustrates a typical wellfield. Piping connecting the individual wells to the header house may be
run underground or on the surface.
Figure 2-2. Schematic Diagram of a Wellfield Showing Typical Injection/Production
Well Patterns, Monitoring Wells, Manifold Buildings, and Pipelines
* If^coif Recweiy Wcl:
_ ZIKI. Monti- 'Milt
Source: NRC, 2009
Three types of wells are present at uranium ISR facilities during the operational
(leaching) phase (see Figure 2-2), sometimes further classified by their location:
Injection wellsWells used to inject solutions into an ore-bearing aquifer to mobilize
uranium.
Extraction wellsWells used to extract uranium-enriched solutions from the ore-
bearing aquifer; also known as "production wells"; note that injection wells and
extraction wells can be converted from one use to another.
Monitoring wellsWells used to obtain water samples for the purpose of
determining the amounts, types, and distribution of constituents in the groundwater.
Wells are located in the production zone, around the perimeter of the production zone
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(horizontal excursion monitoring wells), and in overlying and underlying aquifers
(vertical excursion monitoring wells).
Some of these wells will be used to define initial baseline conditions, to monitor the
progress of restoration, and to determine whether long-term stability has been achieved. Injection
wells at ISR facilities are defined as Class III wells and are regulated under 40 CFR Part 146
Underground Injection Control Program: Criteria and Standards. Part 146 establishes
construction, operating, and monitoring requirements that EPA must approve.
2.2.2 Inputs Used in ISR Uranium Production
This section summarizes briefly the inputs used to produce uranium at ISR facilities.
Uranium resource. The most critical input is the uranium deposit itself; mining firms
invest heavily in exploration and discovery of potentially economically viable
uranium deposits.
Availability of skilled, well-trained engineers and workers is another critical element,
although operating an ISR facility is not labor intensive once the facility has been
constructed.
Capital equipment used to produce uranium at an ISR facility includes the production
and monitoring wells, pipelines, and a building for administration, processing and
packaging equipment, and storing the product. Additional surface facilities may
include evaporation ponds and storage tanks, as well as deep-well injection for
disposal of spent liquids. Upfront capital costs of construction can be considerable,
but according to the World Nuclear Association (WNA), they are much lower when
compared with conventional mining (WNA, 2012a).
Materials, including chemicals for the lixiviant solution, and water.
2.2.3 Production Costs
Production costs at ISR uranium facilities depend on the prices and quantities of the
inputs shown above. Although ISR facilities are expected to be the focus of the Part 192
revisions, we also looked at base costs for conventional mills and heap leach facilities. In
general, current conventional mine and mill costs per pound of yellowcake produced are higher
than ISR facility costs per pound of yellowcake. Numerous factors contribute to this range (e.g.,
capital investment requirements, ore grade, mining or recovery costs, distance to the mill or
processing facility, long-term liabilities, and milling/processing costs). The lower cost of ISR
technology per pound of uranium produced has led to its increased use over the past few
decades.
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2.2.4 Pollution Control
In addition to the cost of constructing and operating an ISR facility, additional costs are
incurred to implement pollution controls, especially groundwater protection monitoring and
remediation (where necessary).
During operations, there is a risk that the lixiviant and/or some mobilized constituent may
spread beyond the wellfield, which poses a risk of groundwater contamination outside the
facility. Monitoring wells are positioned around the production zone of the wellfield to detect
any "excursion" of constituents beyond the wellfield. If excursions are detected, the operator will
take corrective actions to remediate the excursion, such as stopping injection while continuing to
pump water out of the wells near the excursion. When mining is no longer economically viable,
the operator will stop injecting lixiviant and begin restoring the ore zone aquifer to pre-
operational conditions to the extent practicable. (Pre-operational conditions will have been
characterized by sampling the groundwater before operations begin.) The wellfield will be
flushed with clean water (consuming a substantial amount of water) and will frequently be
treated with reducing agents to attempt to restore the pre-operational geochemistry and
immobilize any remaining uranium or other constituents. Then, groundwater conditions are
monitored to ensure that they remain stable. When sufficient time has passed that the
owner/operators can demonstrate that groundwater conditions are stable, the wells are plugged
and abandoned, pipes and other infrastructure are removed, surface facilities are removed and
shipped off site for disposal, and the site is decommissioned, including termination of the
radioactive materials license.
Throughout the process, adequate monitoring is critical to protecting groundwater quality
and thus human health and the environment. The proposed rule will modify the current practice
for monitoring to more fully establish baseline conditions, monitoring to demonstrate restoration,
and monitoring to demonstrate that the restored water quality is stable. The revised provisions
and the associated costs of complying with them are described in Section 3.
Under current requirements, ISR operators must monitor groundwater conditions during
pre-operational baseline characterization, facility operations, groundwater restoration, and
stability monitoring. Provisions of the proposed rule will affect facility requirements during pre-
operational monitoring, operations, restoration, and stability monitoring. Current monitoring
practice in the industry is described below.
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Pre-operational Monitoring: To restore the groundwater to the condition it was
prior to the mining operations, ISR facility operators must collect samples to
characterize the pre-operational groundwater.
Monitoring for Excursions during Operations: During operations, as discussed
above, groundwater conditions surrounding the wellfield will be monitored for
excursions of lixiviant ingredients or mobilized constituents, using wells outside the
wellfield both horizontally and vertically.
Restoration Monitoring: During groundwater restoration, monitoring is used to
measure the progress of the restoration, as well as to demonstrate compliance with the
restoration goals. Several alternatives for demonstrating compliance have been
evaluated.
Stability Monitoring: To demonstrate that the restored groundwater will remain
stable below the restoration goals, ISR facility operators must collect groundwater
samples. Historically, stability monitoring has continued for less than a year; recently
licenses have begun to require stability monitoring of 1 year or longer (EPA, 2012a).
Table 2-3 provides summary expenditures by domestic uranium producers (including
both conventional and ISR facilities) by expenditure category for the period 2003 to 2013.
2.3 Demand for Uranium
2.3.1 Characteristics of the Product (Yellowcake)
Demand for yellowcake is derived from the demand for nuclear energy, which in turn is
derived from the demand for electricity. Yellowcake is a primary input into nuclear energy
production, which ultimately uses nuclear fuel products. The direct demanders of yellowcake are
generally conversion facilities.
Downstream processing operations must occur before the UsOg, or yellowcake, is able to
be used as a fuel. The next step in the process is termed conversion and includes the refinement
of yellowcake to eliminate impurities. The UsOg is converted to gaseous uranium hexafluoride
(UFe). At this stage in the process, UFe is extremely corrosive, particularly when moist. The
material is transferred to steel cylinders with thick walls. The cylinders are shipped to
enrichment facilities.
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Table 2-3. Domestic Uranium Industry Production Expenditures (SMillion)
Year
Drilling
Production
Total land and
other
Land
Exploration
Reclamation
Total Expenditures
2003
W
w
31.3
NA
NA
NA
W
2004
10.6
27.8
48.4
NA
NA
NA
86.9
2005
18.1
58.2
59.7
NA
NA
NA
136.0
2006
40.1
65.9
115.2
41.0
23.3
50.9
221.2
2007
67.5
90.4
178.2
77.7
50.3
50.2
336.2
2008
81.9
221.2
164.4
65.2
50.2
49.1
467.6
2009
35.4
141.0
104.0
17.3
24.2
62.4
280.5
2010
44.6
133.3
99.5
20.2
34.5
44.7
277.3
2011
53.6
168.8
96.8
19.6
43.5
33.7
319.2
2012
66.6
186.9
99.4
16.8
33.3
49.3
352.9
2013
49.9
168.2
90.6
14.6
21.6
54.4
308.7
Drilling: All expenditures directly associated with exploration and development drilling.
Production Land and Other: All expenditures for land; geological research; geochemical and geophysical surveys;
costs incurred by field personnel in the course of exploration, reclamation, and restoration work; and overhead
and administrative charges directly associated with supervising and supporting field activities. All expenditures
for mining, milling, processing of uranium, and facility expense.
NA = Not available
W = Data withheld to avoid disclosure of individual company data.
Notes: Expenditures are in nominal U.S. dollars. Totals may not equal sum of components because of independent
rounding. Expenditures refer to all U.S. uranium production, including conventional mines and mills.
Source: U.S. Energy Information Administration: Form EIA-851 A, "Domestic Uranium Production Report" (2003-
2013).
The enrichment process uses gaseous UFe as a feed. After this process is concluded, two
products are formed: the actual product that contains higher levels of 235U and the "tails" with
lower levels of 235U. The enriched 235U product is now ready to be processed and fabricated into
a reactor fuel. Uranium dioxide (UCh) powder is produced. The powder is processed and formed
into ceramic pellets. The pellets are loaded into fuel rods and pressurized with helium gas and
finally sealed (WNA, 2012c).
2.3.2 Uses and Consumers
The primary end use for uranium is as fuel for nuclear power plants. U.S. civilian nuclear
power reactors are the end users of uranium. They are also referred to as "civilian
owner/operators" or COOs (EIA, 2013c). Over the last 20 years, about 20% of the country's total
energy supply has been generated by nuclear power. The Energy Information Administration
(EIA), in its Reference case, projects that the output of nuclear power will increase, partially due
to the Energy Policy Act of 2005, which guarantees construction loans to nuclear power plants.
By 2040, the EIA projects that nuclear capacity will increase by about 10.4 gigawatts, with
approximately 9.7 gigawatts coming from new reactors and 0.7 gigawatts coming from power
uprates at existing reactors (EIA, 2014a). In February 2012, NRC voted to approve the
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Combined Operating License (COL) to build two new Westinghouse API000 reactors, Vogtle
Units 3 and 4. In March 2012, NRC voted to approve the COL to build two new AP1000
reactors, Virgil C. Summer Units 2 and 3. The Vogtle and Virgil C. Summer units are expected
to be online between 2016 and 2018. In addition to the four new API000 reactors, the Tennessee
Valley Authority anticipates completion of the construction of Watts Bar Unit 2 in late 2015.
These five reactors are the first to be constructed in the United States in over 30 years and will
account for approximately 5.5 GWe of the projected 9.7 GWe projected to be online by 2040.
Thirty-one other countries also generate nuclear power, but the largest generator remains the
United States. France is the second largest country in terms of usage, followed by Russia and
Japan.
2.3.3 Substitutes
Uranium produced by conventional mines and mills is a perfect substitute for uranium
produced by ISR facilities. Similarly, imported UsOg would be a perfect substitute for uranium
produced by ISR facilities. Imported low-enriched-uranium (LEU) and downblended LEU would
be substitutes for LEU produced using domestic uranium.4 Other fuels used to generate
electricity, and other forms of energy, are imperfect substitutes for uranium. This analysis
focuses on the market for uranium, not the market for electricity or the market for energy, so
these imperfect substitutes are not explicitly considered.
2.4 Industry Organization
This section describes the organization of the uranium mining and milling industry,
including the market structure and the characteristics of the facilities and firms producing
uranium oxide in the United States.
2.4.1 Market Structure
Market structure describes the way in which suppliers and demanders of a commodity
interact; markets may range from perfectly competitive (many sellers and buyers of a
homogeneous product, none large enough to affect market price by their actions) to monopolistic
(only one supplier who sets the price and quantity in the market to maximize his profit). The
market for grain is an example of a perfectly competitive market; individual farmers or
purchasers are "price-takers," deciding what quantity to sell or buy based on a market price they
take as given. Electric utilities are examples of regulated monopolies; only a single electric
4 See discussion of international trade in uranium and the Megatons-to-Megawatts agreement with Russia, below.
When the Megatons-to-Megawatts program ends, Russia is expected to sell the United States uranium from their
production sector.
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utility serves each geographic market, and its rates are set through negotiation with regulatory
bodies. Most markets actually fall somewhere between these two extreme examples. The market
for uranium is global, imperfectly competitive, and highly regulated.
2.4.1.1 Barriers to Entry
Globally, there are relatively few suppliers of yellowcake, and only six facilities are
currently operating in the United States. The small number of facilities indicates that firms
wishing to enter the uranium market face several barriers to entry. Barriers facing potential
entrants in the United States include the following:
They must have access to a uranium deposit, which are limited in number. Uranium is
a scarce resource, and a significant ore body must first be located, which requires
investing considerable time and money.
They must obtain a license from the NRC or an Agreement State. The NRC regulates
ISR facilities. The NRC has developed a suite of regulations to reduce threats to
human health and the environment, such as 10 CFR Part 20, 10 CFR Part 40, and
Appendix A of 10 CFR Part 40, which are based on EPA regulations at 40 CFR Part
192 (NRC, 2013). To begin extracting uranium at an ISR facility, the potential
supplier must go through many time-consuming and costly steps. The applicant must
follow NRC's regulatory guides that present guidance on various aspects of the
process, such as license applications, environmental impact statements and analyses,
calculation models, financial assurance and construction requirements. Each of these
steps is also expensive and requires substantial amounts of time. The environmental
impact statement is part of the National Environmental Policy Act process, which
may be duplicated by Bureau of Land Management requirements if the project is on
public lands.
Prior to getting a license from the NRC, the applicant must also get an aquifer
exemption from the EPA's Underground Injection Control Program, or its delegated
agency, which can be the state or the regional EPA office.
Some states have additional barriers, such as Virginia's moratorium on uranium mining
and milling5 (Virginia Statute 45.1-283). Agreement State regulations may be stricter than NRC
regulations, which can be important with respect to protecting groundwater resources.
In 1982, the Virginia General Assembly passed Statute 45.1-283, which states "permit applications for uranium
mining shall not be accepted by any agency of the Commonwealth prior to July 1, 1984, and until a program for
permitting uranium mining is established by statute."
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2.4.2 Small Businesses
The RFA as amended by SBREFA requires federal departments and agencies to evaluate
if and/or how their regulations affect small business entities. Specifically, the agency must
determine if a regulation is expected to have a significant economic impact on a substantial
number of small entities. Small entities include small businesses, small organizations, and small
governmental jurisdictions. The business is defined as the owner company, rather than the
facility; the size of the owner company determines the resources it has available to comply with
the rule.
If a rulemaking is determined to have a significant economic impact on a substantial
number of small entities, then the agency must conduct a formal regulatory flexibility analysis.
However, if the agency determines that a rulemaking does not have a significant economic
impact on a substantial number of small entities, then it makes a certification of that finding and
presents the analyses that it made to arrive at that conclusion. The ISR uranium operations fall
under the NAICS code of uranium-radium-vanadium mining (212291) (NAICS, 2012). For
NAICS 212291, the Small Business Administration (SBA) (2012) defines a small business as
one having fewer than 500 employees.
Because the proposed revisions to Part 192 do not involve conventional mills, the
economic impact analysis focuses on ISR facilities. In 2013, there were six ISR facilities in
operation (EIA, 2014b): Crow Butte and Smith Ranch-Highland-Reynolds owned by Cameco
Resources; Alta Mesa owned by Mestena Uranium, LLC; Willow Creek owned by Uranium
One, Inc.; Hobson-La Palangana owned by Uranium Energy Corp.; and Lost Creek owned by
Ur-Energy. Because they have fewer than 500 employees, Mestena Uranium, LLC, Ur-Energy,
and Uranium Energy Corp. are considered small businesses according to the criteria for NAICS
212291, while both Cameco Resources and Uranium One, Inc. are large businesses.
Table 2-4. Owner Companies for ISR Facilities: Existing and Planned
Parent Company
Cameco Corporation
Mestena Uranium
Uranium One, Inc.
Uranium Energy Corp.
Facility Name
Crow Butte, Smith Ranch-
Highland
Alta Mesa
Willow Creek, Moore Ranch,
Antelope-Jab
Hobson-La Palangana, Goliad
Number of
Employees
3,300
125
2,200
98
Annual Revenue
(Million $)
2,400
X
530.4
9.00
Small
Business?
No
Yes
No
Yes
(continued)
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Table 2-4. Owner Companies for ISR Facilities: Existing and Planned (continued)
Parent Company
Powertech Uranium Corp.
Uranerz Uranium Corp.
Strata Energy /Peninsula
Energy Ltd
Uranium Resources
Ur-Energy
Bayswater E&P
Number of Annual Revenue
Facility Name Employees (Million $)
Dewey-Burdock
Nichols Ranch
Ross
Crownpoint, Kingsville Dome,
Rosita, Vasquez, Church Rock
Lost Creek
Reno Creek
25
54
<30
37
51
X
5.04
0.00
0.85a
X
X
X
Small
Business?
Yes
Yes
Yes
Yes
Yes
Yes
x = No annual sales data
Note: ISR projects listed in italics are not currently in operation; see Table 2-7 for status. Those in regular print were
operating during the summer of 2013.
Sources: Data on total number of employees and annual sales were gathered from Hoover's, U.S. Securities and
Exchange Commission, and various company annual reports and websites (Cameco, 2013; Uranium One,
2013; Uranium Energy Corporation, 2013; Peninsula Energy Ltd, 2013;Uranerz Energy Corporation 2013;
Uranium Resources, Inc.2013, Ur-Energy 2013).
In addition to the six ISR facilities listed above, several ISR facilities are in various
stages of planning or licensing (see Table 2-4); most of these are also owned by small
businesses. Thus, of the existing or planned ISR uranium recovery facilities identified in Table 2-
4, most are owned by small businesses. Of the 10 owner companies listed in Table 2-4, 8 are
small, based on available information about their employment.
EPA recognizes that several of the small businesses have investors in some of their ISR
operations that are large businesses. Although the presence of these large company investors may
provide additional resources for complying with the rule, EPA nevertheless evaluated the potential
for small business impacts based on data for the small business that is the owner of the operation.
2.5 Market for UsOs
2.5.1 U.S. Consumption
In 2012, U.S. COOs of nuclear power plants purchased a total of 57 million metric tons
of UsOg equivalent, an increase of 0.7% from the prior year (see Table 2-5). The majority of the
UsOg equivalent (approximately 80%) was purchased through the use of short-, medium-, and
long-term contracts. Under these contract types, at least one delivery is set to occur after a year
following the date the contract was established. The remaining uranium sales were purchased
through the use of spot contracts, which are one-time deliveries, set to occur within a year of the
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contract's signing date. While the weighted-average prices of uranium purchased by U.S. COOs
dropped slightly as well, from $54.99 per pound in 2012 to $51.99 in 2012 (see Table 2-8), spot
prices have dropped since early 2011. The spot price for uranium fell to $43.83 in 2013 (Table 2-
8); for contracts signed in 2013 by U.S. COOs, the long-term contract price was approximately
$43.20 (U.S. EIA, 2014c).
Table 2-5. Uranium Purchased by U.S. COOs, 1994-2013 (Million Pounds UsOs
Equivalent)
Delivery Year
1994
1995
1996
1997
1998
1999
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
Spot Contracts
8.5
13.6
9.1
5.5
7.8
8.0
10.4
14.4
8.6
8.2
9.2
6.9
6.3
6.6
8.7
8.1
8.2
12.0
8.1
11.3
Short-, Medium-, and
Long-Term Contracts
29.8
29.8
38.3
36.5
34.9
40.0
39.1
40.0
41.4
46.7
53.3
58.8
59.4
43.7
42.8
41.0
37.9
42.3
48.9
46.1
Total Purchased
38.3
43.4
47.3
42.0
42.7
47.9
51.8
55.4
52.7
56.6
64.1
65.7
66.5
51.0
53.4
49.8
46.6
54.8
57.0
57.4
Sources: U.S. Energy Information Administration: 1994-2002-Uranium Industry Annual, Tables 10, 11 and 16.
2003-2013-FormEIA-858, "Uranium Marketing Annual Survey."
As shown in Table 2-6, domestic production of UsOg is a small share of total COO
purchases. Some comes from domestic inventories, but the majority of uranium purchased by
COOs is from foreign sources.
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Table 2-6. Total Amount IbOs Produced in the United States (Thousand Pounds IbOs)
Production
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
Total Mine Production
E2,200
2,452
3,045
4,692
4,541
3,879
4,145
4,237
4,114
4,335
4,577
Total Mines and Sources
4
6
10
11
12
17
20
9
11
12
12
E = Estimated data.
Source: U.S. Energy Information Administration: Form EIA-851 A, "Domestic Uranium Production Report" (2003-
2013).
2.5.2 U.S. Uranium Production
In the United States, uranium producers are concentrated in the West and Southwest,
including the states of Texas, New Mexico, Arizona, Utah, Colorado, Wyoming, South Dakota,
and Nebraska. Figure 2-3 shows the approximate locations of uranium production facilities
(including not only operating ISR facilities, but also those that are currently on standby or pre-
operational).
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Figure 2-3. Location of ISR Uranium Production
Source: EPA, 2012a
Table 2-7 provides a list of ISR facilities in the United States, together with their
location, capacity, and operating status. As shown in the table, there are six currently operating
or producing ISR facilities in the United States; several others are licensed or partially licensed.
Of the 23.1 million pounds capacity shown in the table, U.S. facilities have typically produced
less than 10 million pounds per year over the past 10 years.
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Table 2-7. In situ Recovery Plants in the United States, and Status (2013)
Production
Capacity (pounds
In situ Recovery Project Name
State
UsOs per year)
Status
Operating, Summer 20 13
Crow Butte
Smith Ranch-Highland
Alta Mesa
Hobson-La Palangana
Willow Creek (Christensen Ranch and
Irigaray)
Lost Creek
Nebraska
Wyoming
Texas
Texas
Wyoming
Wyoming
1,000,000
5,500,000
1,500,000
1,000,000
1,300,000
2,000,000
Operating
Operating
Operating
Operating
Operating
Operating
Not Operating, Summer 20 13
Crownpoint
Church Rock
Dewey Burdock
Ross
Kingsville Dome
Rosita
Vasquez
Nichols Ranch ISR
Goliad ISR Uranium
Antelope-Jab
Moore Ranch
Reno Creek
Total Domestic Production Capacity:
New Mexico
New Mexico
South Dakota
Wyoming
Texas
Texas
Texas
Wyoming
Texas
Wyoming
Wyoming
Wyoming
1,000,000
1,000,000
1,000,000
3,000,000
1,000,000
1,000,000
800,000
2,000,000
1,000,000
2,000,000
500,000
-
26,600,000
Partially permitted and licensed
Partially permitted and licensed
Developing
Partially permitted and licensed
Restoration
Restoration
Restoration
Under construction
Permitted and licensed
Developing
Permitted and licensed
Developing
- = No data reported.
a According to owner company (Ur-Energy, Uranium Energy Corporation) websites.
Notes: Production capacity for 2011. An operating status of "Operating" indicates the in-situ leach plant usually was
producing uranium concentrate at the end of the period. The Hobson ISR Plant processed uranium concentrate
that came from La Palangana. Hobson and La Palangana are co-owned, but not co-located, and are considered in
this analysis as one project. Christensen Ranch and Irigaray are part of the Willow Creek Project.
Source: U.S. Energy Information Administration: Form EIA-851 A, "Domestic Uranium Production Report" (2007-
2013).
2.5.3 International Trade
Uranium is a relatively homogeneous commodity that is valued for its energy content,
and the market for uranium is genuinely an international market. Uranium produced in the
United States may be sold abroad or sent abroad for processing and then returned to the United
States. Typically, domestic-origin uranium has been a relatively small share of total uranium
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purchased in the United States. In addition to uranium mined abroad, low-enriched uranium for
use in fuel fabrication facilities is also imported, especially from Russia.
In 1993, the United States and Russia entered into a government-industry agreement
whereby Russian nuclear weapons containing HEU are dismantled and converted to LEU for use
as fuel in nuclear power reactors domestically (United States Enrichment Corporation [USEC],
2012). A commercial company, USEC, has acted on behalf of the U.S. government.
Techsnabexport (TENEX) is the commercial agent for the Russian government. Since the
program's inception, -12,380 metric tons of HEU have been converted. In 2013, purchases
under the program ended (USEC, 2014).
In 2013, TENEX will begin to supply LEU under a new contract with USEC. The new
amount that will be supplied will increase until it reaches approximately one-half the currently
supplied levels (under the Megatons to Megawatts Program) in 2015. Within the agreement,
there is an option to scale up to the currently supplied levels through the year 2022. Under the
new contract, Russia will be supplying commercially enriched uranium instead of uranium from
dismantled weapons (World Nuclear News, 2011; Pravda, 2012).
2.5.3.1 Imports
Most of the uranium used by COOs domestically is purchased from foreign suppliers. In
2012, the 9.8 million pounds of UsOg produced in the United States amounted to only 17.0% of
the total 57.5 million pounds of UsOg purchased. Kazakhstan, Russia, and Uzbekistan comprised
40% of total deliveries. The share of uranium that is of foreign origin has fluctuated over time
(EIA, 2013c).
2.5.3.2 Exports
In addition to imports of uranium into the United States, the NRC licenses exports of
processed uranium from the United States. In 2012, of 18.0 million pounds delivered to foreign
suppliers and utilities, only 4.8 million pounds of the uranium exported was of U.S. origin. The
remaining 13.2 million pounds exported were of foreign-origin uranium6 (EIA, 2013c).
2.5.4 Market Prices
Uranium is traded under various contractual arrangements, including spot contracts and
short-, medium-, and long-term contracts. Contract prices and spot prices vary, with spot prices
Note that data provided for production, imports, exports, and purchases in a given year appear inconsistent. This
occurs because some production may go into inventory, and some purchases may be from inventory.
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being much more volatile than contract prices. Table 2-8 presents historical data on uranium
prices. Most contracts are based not based on the spot price but rather the long-term price. It
should be noted that uranium is not traded on recognized exchanges; rather the price is set by
two independent companies based on their market research. Contract prices exhibit more
stability than spot prices. In 2007, the spot price rose to more than $88 per pound, while the
weighted average short-, medium-, and long-term contract price was less than $25 per pound. In
2011, however, the spot price and weighted average price had converged to within $2 per pound,
and in 2012 the spot price and weighted average price were within $5 per pound (EIA, 2013c). In
2013, the difference between the spot price and weighted average price increased again to
approximately $10 per pound.
Table 2-8. Weighted-Average Price of Uranium Purchased by U.S. COOs Based on
Contract Type
Delivery Year
1994
1995
1996
1997
1998
1999
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
Total Purchased
10.40
11.25
14.12
12.88
12.14
11.63
11.04
10.15
10.36
10.81
12.61
14.36
18.61
32.78
45.88
45.86
49.29
55.64
54.99
51.99
Spot Contracts
9.01
10.30
14.22
11.61
10.56
9.52
8.54
7.92
9.29
10.10
14.77
20.04
39.48
88.25
66.95
46.45
43.99
54.69
51.04
43.83
Short, Medium, and
Long-Term Contracts
NA
NA
NA
NA
NA
NA
11.70
10.96
10.58
10.94
12.24
13.70
16.38
24.45
41.59
45.74
50.43
55.90
55.65
54.00
Sources: U.S. Energy Information Administration: 1994-2002-Uranium Industry Annual, Tables 10, 11, and 16.
2003-2013-FormEIA-858, "Uranium Marketing Annual Survey."
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2.5.5 Industry Trends
In March 2011, a massive earthquake and tsunami struck the coast of Japan, causing
more than 20,000 deaths and leading to the Fukushima Daiichi nuclear power plant meltdown.
The disaster was the largest of its kind since the Chernobyl accident in 1986. In the aftermath of
the disaster, the viability and safety of nuclear power were questioned. The event led to a
comprehensive examination of energy policies throughout the world. One year later, however,
the EIA (2013b) reported that the nuclear power industry is in fact projected to expand, with
greater safeguards being established to protect from future disasters (WNA, 2012b).
Worldwide, demand for uranium is projected to grow as nations such as China and India
increase their use of nuclear power. Meanwhile, exploration for new sources of uranium is
ongoing, both in the United States and elsewhere. Several years ago, the U.S. Nuclear Waste
Technical Review Board (U.S. NWTRB, 2010) examined the supply and demand for uranium,
and noted that 2009 uranium resources were sufficient to meet 2009 levels of demand for 90
years. The overall impact on future uranium prices depends on whether demand for uranium or
supply of uranium grows more rapidly.
The largest uranium producers globally are Kazakhstan (36%), Canada (17%), and
Australia (11%) (WNA, 2012d). The United States accounts for close to 3% of world production.
2.5.6 Projections
The EIA, in its 2014 Annual Energy Outlook (EIA, 2014a), provides projections about
energy production and use through the year 2040, under a variety of assumptions about
economic growth and other future conditions. In its reference case projections, EIA projects that
energy supplied from uranium will grow over the period 2011 to 2040 from 8.26 quadrillion Btu
to 8.49 quadrillion Btu, a rate of growth of approximately 0.2% per year. Applying the reference
case rate of growth to 2012 uranium purchases, projected 2040 uranium purchases by COOs
would be approximately 65 million pounds. As noted above, increasing demand for uranium
from China and other countries is expected over the long term, in spite of recent developments
such as the Fukushima tsunami and the global economic downturn. Similarly, the price of
uranium is projected to increase over the next few years as demand increases and the Megatons
to Megawatts program ends. Under the Megatons to Megawatts program, a 20-year agreement
between USEC (representing the United States government) and Techsnabexport (TENEX,
representing the Russian government), weapons-grade highly enriched uranium from Russian
nuclear warheads (HEU) was processed and down-blended to low-enriched uranium and sold to
USEC for use as nuclear fuel. On average, The Megatons to Megawatts program supplied about
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13% of world uranium requirements during this period. The program ended in 2013. (See WNA,
2013 for more information.) Although a follow-on agreement with TENEX permits USEC to
continue to purchase uranium from Russia, future uranium purchased will be from conventional
supplies and the expected quantity will be smaller. Assuming that the global economy recovers
from its recession and planned nuclear energy projects go forward, demand for uranium is
projected to increase, while supplies may lag (although uranium reserves are estimated to be
ample to meet projected needs, they will need to be extracted and processed to supply the
market, and development and production has slowed during 2011 to 2012). Longer term, the
price is projected to increase. The Australian Bureau of Research and Energy Economics, cited
by the Australian Uranium Association, projects the price of uranium to rise to about $64 per
pound by 2018 (Australian Uranium Association, 2013) . If either the recovery from the global
recession lags or excess demand for uranium is slower to develop, these prices might not be
realized by 2018, but they do represent likely levels going forward.
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Section 3
THE PROPOSED RULE AND ITS ESTIMATED COSTS
EPA reviewed the existing regulations affecting ISR uranium projects and concluded that
40 CFR Part 192 should be amended to add a subpart F that specifically addresses groundwater
protection at ISR operations, which are now the dominant form of uranium extraction in the
United States. The ISR process presents different environmental concerns than conventional
milling; ISR does not result in large volumes of waste materials or the need for permanent
impoundments. However, the process directly alters groundwater chemistry, posing the
challenge of groundwater restoration and long-term stabilization after ISR operations end. In
developing the proposed rule, EPA's objective was to provide long-lasting protection of
groundwater aquifers surrounding ISR wellfields. EPA's proposed rule specifies how to
determine pre-operational background conditions that will be used to set appropriate restoration
goals, applicable standards, and alternative concentration limits. The proposed rule also provides
specifications for long-term groundwater stability monitoring to ensure that ISR sites do not
become a source of groundwater contamination after the operation is terminated. In addition, the
proposed rule explicitly requires corrective action if monitoring reveals that constituents have
left the exempted aquifer during operations or have become mobile again after restoration is
complete.
3.1 Description of Proposed Regulation
EPA's proposed regulation includes provisions addressing three issues: pre-operational
monitoring to establish baseline conditions, establishing and updating groundwater protection
standards, and monitoring to demonstrate that the restored water quality is stable. Below, we
describe these three aspects of the proposed rule. EPA considered several regulatory options
before selecting its preferred approach to each issue.
3.1.1 Groundwater Protection Standards
EPA's proposed rule identifies the minimum 13 constituents for which groundwater
protection standards must be met: arsenic, barium, cadmium, chromium, lead, mercury,
selenium, silver, nitrate (as N), molybdenum, combined radium-226 and radium-228, uranium
(total), and gross alpha-particle activity (excluding radon and uranium). The concentration of
each listed constituent must remain at or below the most protective standards under the Safe
Drinking Water Act (SDWA), values from Resource Conservation and Recovery Act (RCRA)
standards, or Table 1 to subpart A of Part 192, except in cases where the measured pre-
operational wellfield background concentration (commonly referred to in the industry as
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"baseline") is higher than the most stringent value in the applicable regulations. In such cases,
the measured background concentration will serve as the restoration goal. The proposed
language allows for the regulatory agency to set standards for additional constituents as
necessary, consistent with site conditions, and provides clarity and consistency by referring to
existing standards under each act at the time of licensing. Under the proposed rule, Subpart F
standards would automatically update if any of the referenced standards (SDWA or RCRA) were
revised (see Table 3-1).
Table 3-1. Table 1 to Subpart F of Part 192Maximum Concentration of Constituents
for Groundwater Protection at ISR Facility Sites
Constituent
Maximum
Arsenic
Barium
Cadmium
Chromium
Lead
Mercury
Selenium
Silver
Nitrate (as N)
Molybdenum
Radium-226 and radium-228 (combined)
Uranium (total)
Gross alpha particle activity (excluding radon and uranium)
The restoration goal is the primary or secondary
MCL listed in 40 CFR 141.61, 141.62, 141.66,
141.80, and 143.3, the maximum concentration of
hazardous constituents for groundwater protection
under 264.94, or the maximum constituent
concentration specified in Table 1 to subpart A of
this Part, whichever is most stringent.
Where a background concentration is determined to
be higher, the background concentration will serve
as the restoration goal.
3.1.2 Monitoring Requirements
To ensure that groundwater in the vicinity of ISR operations is protected, EPA's
proposed rule specifies groundwater monitoring requirements for each phase of the ISR
operation.
3.1.2.1 Pre-operational Monitoring: Adequate Characterization of Groundwater Prior to
Uranium Recovery
EPA's proposed rule specifies requirements for thorough pre-operational monitoring at
ISR sites. This monitoring serves several purposes. To design and operate an ISR facility, the
chemical composition and hydrology of the groundwater in and around the ore body must first be
rigorously characterized. Defining the configuration of the ore zone and designing the production
zone for uranium recovery require detailed subsurface information obtained from geophysical
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investigations, including but not limited to logs and cores (U.S. EPA, 2013). In addition, the
groundwater in the production zone is also characterized to determine the proposed chemical
composition of the lixiviant and to determine pre-operational groundwater chemistry by which to
set restoration goals for the post-production phase of the ISR operation (i.e., the efforts to return
the groundwater chemical conditions in the production zone to those that existed prior to the
uranium recovery efforts). EPA's proposed rule requires:
A sufficient number of wells, at appropriate locations and depths, to be installed in
such a manner as to yield representative samples in order to define the groundwater
flow regime and measure pre-operational hydrogeochemical conditions and water
quality for use in statistical tests during licensing, operations, restoration, stability,
and long-term stability.
The pre-operational background monitoring effort must include immediately
overlying aquifers, immediately underlying aquifers, and background monitoring
inside and outside of the exempted aquifer, including both the up- and down-gradient
areas outside of the production zone.
During the monitoring effort, relevant data documenting geology, hydrology, and
geochemistry for radiological and nonradiological constituents shall be collected,
both in the production zone and in surrounding areas that may be affected by the ISR
operations.
The monitoring effort must be of sufficient duration of no less than 1 year and of
sufficient scope to adequately characterize temporal and spatial variations in
groundwater and to account for impacts of well installation and development on
background concentrations of constituents and values of indicator parameters,
where applicable.
Pre-operational monitoring must be focused on determining background
concentrations of constituents and indicator parameters in point of compliance
wells within the proposed production zone, in immediately overlying and
immediately underlying aquifers, and outside the production zone, in wells within
the exempted aquifer and in up-gradient and down-gradient wells within non-
exempt portions of the adjacent aquifer.
- The owner/operator must employ appropriate statistical techniques to analyze
background concentrations measured in individual wells within the proposed
production zone for the purpose of determining restoration goals for groundwater
restoration and long-term stability. As determined by the owner/operator and
approved by the regulatory agency, background concentration limits may be
representative of individual wells, multiple wells, or all wells within the proposed
production zone.
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3.1.2.2 Operational Phase Monitoring
The proposed rule requires monitoring during the operational phase to detect excursions.
The rule calls for monitoring of indicator parameters in horizontal and vertical monitoring wells.
If an excursion is detected, corrective action must be undertaken and all constituents listed in
Table 3-1 must be monitored until the excursion is controlled.
3.1.2.3 Restoration Phase Monitoring
During the active restoration phase, all constituents listed in Table 1 of this subpart or
otherwise specified by the regulatory agency must be monitored through quarterly sampling or
other time interval specified by the regulatory agency. Indicator parameters must be monitored in
horizontal and vertical excursion wells. If an excursion is detected, corrective action must be
undertaken, and all constituents listed in Table 3-1 must be monitored until the excursion is
controlled.
3.1.2.4 Stability Phase Monitoring
The proposed rule requires that constituents be monitored throughout the stability phase
of an ISR facility in points of compliance wells in the production zone, as determined by the
regulatory agency, including
all constituents listed in Table 1 of the new subpart and
any additional constituents required by the regulatory agency, such as constituents
and parameters necessary for geochemical calculations of the groundwater chemistry
in order to demonstrate that a stable groundwater chemistry has been achieved after
restoration; components of the lixiviant fluids injected during uranium recovery and
any fluids injected during restoration; or metals potentially mobilized by the uranium
recovery process.
The owner/operator must collect sufficient data and apply appropriate statistical methods
to demonstrate that the aquifer conditions within the production zone are stable (i.e., there are no
temporal trends in the constituent concentration data considering natural variation in
compositions). Stability must be demonstrated for 3 consecutive years at a 95% confidence level
and based on sampling no less frequently than quarterly.
If the owner/operator demonstrates 3 consecutive years of stable concentrations of
constituents but is unable to meet the restoration goal for one or more of these constituents, the
owner/operator may request an alternate concentration limit (ACL) from the regulatory agency.
The regulatory agency may then approve an ACL or it may require that the owner/operator
resume active restoration efforts in an attempt to bring down the constituent concentrations.
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3.1.2.5 Long-Term Stability Phase Monitoring
After stability has been demonstrated, EPA's proposed rule requires that owner/operators
continue quarterly monitoring to ensure that groundwater conditions remain stable.
The proposed rule requires long-term stability monitoring to be maintained for a period
of 30 years. The regulatory agency may shorten the long-term stability monitoring period if, after
stability is documented for a period of 3 consecutive years, the owner/operator demonstrates
through hydrogeological and geochemical modeling of the site that the subsurface conditions
within the production zone will remain stable into the future. In evaluating such modeling, the
regulatory agency must determine that there is a reasonable expectation that restoration goals
will not be exceeded and that subsurface conditions in the future will not cause the
remobilization of uranium, radium, or other constituents into the groundwater and their migration
beyond the boundaries of the production zone. The owner/operator must notify the regulatory
agency and undertake corrective actions if, during the course of long-term stability monitoring,
one or more monitored groundwater constituents exceeds a groundwater protection standard or
shows statistically significant increasing trends that would threaten groundwater quality if left
unabated. The proposed rule also specifies the components of a corrective action program.
3.1.3 Other Regulatory Alternatives for Long-Term Monitoring Considered but Rejected
EPA also considered two additional regulatory alternatives:
Requiring long-term stability monitoring to continue for 30 years without the
opportunity to use hydrogeological and geochemical modeling to shorten the
monitoring period. This alternative was not selected for proposal because EPA felt it
was unnecessarily burdensome, because modeling may be able to demonstrate that
geochemical mechanisms exist to prevent uranium and other constituents from
remobilizing and migrating beyond the boundaries of the production zone. In
addition, while monitoring for 30 years would enable a determination about whether
the wellfield chemistry is remaining stable over a longer period of time, it does not
provide any assurance that the groundwater will remain stable after 30 years, such as
geochemical modeling may be able to do.
Using a narrative long-term stability monitoring standard, with no fixed duration.
EPA chose not to propose this regulatory alternative because statistical analyses alone
would provide no assurance that groundwater systems will remain chemically stable
over a longer period of time. In addition to being somewhat ambiguous, a narrative
standard poses a higher risk of prematurely terminating the license.
This analysis examines the costs of complying with the proposed rule and the costs of
complying with the required 30-year long-term stability regulatory alternative. In addition, EPA
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recognizes that it is possible that geochemical modeling may demonstrate that geological
conditions in and around the wellfield may not ensure long-term stability; in this case, if
operations have begun at the ISR facility, EPA expects that the regulatory agency would require
30 years of long-term stability monitoring to ensure that conditions are stable within the
wellfield. EPA also estimated the cost of geochemical modeling, followed by an extended 30-
year period of long-term stability monitoring.
3.2 Estimated Incremental Costs of Compliance with Proposed Rule
EPA reviewed the existing regulations affecting ISR facilities and concluded that 40 CFR
Part 192 should be amended to add a subpart F that specifically addresses groundwater
protection at ISR operations, which are now the dominant form of uranium extraction in the
United States. The ISR process directly alters groundwater chemistry, posing the challenge of
groundwater restoration and long-term stabilization after ISR operations end. EPA is evaluating
the range of cost estimates associated with proposed groundwater monitoring options. The
current costs associated with groundwater monitoring at ISR facilities under the existing
regulatory scheme were calculated and then compared against three groundwater monitoring
scenarios that implement alternative groundwater monitoring approaches proposed by the
regulation:7
30-year post-restoration stability monitoring with option to reduce monitoring
duration using hydrogeological and geochemical modeling
30-year post-restoration stability monitoring with no option for shortening the
duration
In addition, costs were considered for a third monitoring scenario that is not a regulatory
option but rather a worst case scenario for an owner/operator under the proposed regulatory
approach:
Geochemical modeling followed by 30 years of required stability monitoring
EPA does not consider that this worst-case scenario is likely to occur. The proposed
regulatory approach requires thorough characterization of hydrogeochemical conditions within
the production zone and down-gradient during the pre-operational phase. EPA expects that, if the
conditions are found to be insufficiently reducing (so that any constituents carried down-gradient
Throughout the document, the cost estimates are labeled based on the long-term stability monitoring phase
requirements for convenience. As shown below in Tables 3-2 through 3-7, requirements and estimated costs for
other phases also differ among alternatives and between alternatives and current practice.
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by groundwater would not be stabilized there), the owner-operator might decide not to develop
the deposit and the licensing agency would likely not grant the license. This worst-case scenario
would only occur if the sampling and geochemical modeling conducted after operations are
complete gives a negative signal, after geochemical modeling during pre-operations signaled that
development would be safe. Thus, this worst case likely overestimates the costs that a site would
incur. Because EPA regards this worst case as unlikely, and because it does not represent a
regulatory alternative, EPA presents the estimated impacts under the worst case scenario only in
Appendix D.
A third regulatory alternative was considered by EPA but not analyzed in this economic
analysis. EPA also considered a narrative standard with no fixed monitoring period. The actual
compliance activities that might be required under this alternative would depend entirely on
negotiations between the owner/operator and the licensing agency. Because they would be site
specific and thus uncertain, EPA concluded that it would not be possible to assess what the
compliance requirements and associated costs for a given facility would be. For this reason,
although EPA considered this regulatory approach, its costs and impacts are not analyzed in this
document.
Although the above scenarios address proposed monitoring requirements during the
stability monitoring phase, these changes also affect the numbers of wells and analytical
constituents that must be monitored during earlier phases of an ISR project. These costs have
also been estimated as they relate to each of the scenarios.
3.2.1 Technical Approach: Conceptual Site Model Facility
A conceptual model was used to help frame the costs for each of these scenarios that are
described below. The design of one production unit and the hydrogeology of the associated 50-
sand ore bearing layer within Wellfield-E at the Highland Site in Wyoming were used as a basis
for constructing the CMU model. The CMU model (Figure 3-1) was developed based on the
actual design of the Wellfield-E production and mine units (Cameco Resources, 2008) but also
considering standard wellfield design practice (NRC, 2003). The conceptual model was used as a
basis for developing the costing scenarios. A general layout of the CMU model for the different
scenarios showing the well locations is provided in Figures 3-1 and 3-2.
3.2.1.1 Conceptual Mine Unit (CMU) Model Description
The CMU area, inside the perimeter monitoring well ring, is approximately 200 acres
with a 44-acre production area. Approximately 243 wells (166 injection and 77 extraction wells)
were assumed for the production area of the CMU model. This assumes that a 5-spot pattern was
5-7
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used for the wellfield grid with a well spacing of approximately 120 feet, which is similar to the
design of the production units in Wellfield-E. A distance of approximately 600 feet from the
edge of the production unit was used to locate the perimeter-well ring. This was consistent with
the configuration and design of Wellfield-E. The spacing of perimeter wells was also patterned
after the Wellfield-E design.
Figure 3-1. ISL/ISR Conceptual Site Model Applicable to Current Practice and 30-Year
Monitoring
Legend
X> Coreholes (Number based
on other Cameco sites)
ffi Perimeter well (OZ-PW)
H 8-acre square
^ 4-acre square
Production Unit
^H 5-Spot Pattern (Approximately 120 foot spacing)
£ Extraction well used for baseline monitoring (EW)
Q Inj ection well used for baseline monitoring (IW)
^k Overlying (10) and Underlying (5) monitoring well (OW/UW)
f(ow> The approximate direction of current groundwater
flow is based on an April 2011 CAMECO Resources
report for Smith Ranch - Highland. Accessed 3/28/
2013).
Approximate Scale (feet)
Note: Site model is loosely based on actual conditions for one production area within Wellfield E of the Highland
Ranch site. Configuration of the perimeter well ring has been adjusted.
Sandstone aquifers were assumed to be overlying and underlying the ore zone (also
sandstone) aquifer. For simplicity of modeling, it was assumed that laterally continuous shale
beds served to hydraulically separate the aquifers from the consolidated ore sand. Such a
stratigraphy is typical of ISR situations. The ore zone sandstone layer was assumed to have an
average thickness of approximately 35 feet with an average base-of-bed depth of about 600 feet.
The overlying aquifer base-of-bed average depth is approximately 490 feet below ground
surface, and the underlying aquifer top-of-bed depth is approximately 650 feet below land
-------�
surface. These depths are roughly similar to the Highland site geology (Michel and Hoffman,
1991). The 60-sand and 40-sand aquifers, overlying and underlying the 50-sand aquifer unit,
respectively, are also ore sand layers at the Highland site, and production units for one or both of
these sands are co-located within the boundaries of and near Wellfield-E; however, operational
strategy that may be used when mine units are co-located was not considered in the CMU model
or modeled scenarios because these considerations would make the model very site specific, and
a more generalized model of an ISR wellfield was needed. The concept of these scenario
analyses was to make assessments of a generic nature but framed within the bounds of
characteristics associated with actual sites. In practice, the size of the prospective ore zone and
the configuration of the production wells will be determined by site-specific conditions.
Figure 3-2. ISL/ISR Conceptual Site Model Applicable to Geochemical Modeling
Scenario
f(GW): The approximate direction of groundwater flow is
based on an April 2011 CAMECO Resources report for
Smith Ranch - Highland. Accessed 3/28/2013).
_J 8-acre square <
O Extraction well used for baseline monitoring (EW)
Q Injection well used for baseline monitoring (IW)
^Lz Overlying (10) andUnderlying (5) monitoring well (OW/UW)
Downgradient ore zone monitoring well
* (OZ-MW)
Approximate Scale (feet)
Note: Site model is loosely based on actual conditions for one production area within Wellfield E of the Highland
Ranch site. Configuration of the perimeter well ring has been adjusted and ore zone monitoring wells have
been added down-gradient.
j-^
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Assumptions used for evaluating groundwater monitoring costs included:
the number of wells to be sampled
the duration of the period of sampling (or operation phase)
the sampling frequency (i.e., weekly, biweekly, monthly, quarterly) and
the list of parameters that must be sampled.
The duration of groundwater stability monitoring would in reality be site specific and is
typically specified in the license(s) (U.S. EPA, 2012a); however, past and current practice
assumed a monitoring and sampling period between 6 months and approximately 2 years.
Typically one injection, extraction, or other ore zone well is monitored per acre of the production
unit along with the perimeter monitoring wells surrounding the mining unit. Additional
monitoring wells were also assumed for other ISR phases for the geochemical modeling
scenario, which assumes that additional geochemical characterization would be needed. Samples
are generally collected on at least a quarterly basis during the stability phase for the same
analytes that were sampled during baseline monitoring. The specific lists of chemical analytes
that operators sample are those specified in the NRC's ISR Standard Review Plan (NRC, 2003)
along with analytes required by regulating state agencies. Stability sampling would be extended
to a minimum of 30 years under the proposed rule unless it could be demonstrated using
appropriate geostatistical tests, and a minimum of 3 years of stability monitoring data, that the
groundwater chemistry has reached baseline levels (or other regulatory supported groundwater
quality standards) and is stable at those levels for at least 3 years. Geochemical testing and
monitoring would also be required by the proposed rule to further demonstrate and ensure long-
term stability of groundwater quality in and around the wellfield. A demonstration of
geochemical stability based on monitoring data and a geochemical model would allow the
regulator to require less than a 30-year post-restoration monitoring period. In this analysis of the
proposed rule, EPA assumes that the long-term stability monitoring phase is reduced to 7 years.
During the restoration phase, groundwater chemical compositions are also monitored to follow
the course of the restoration effort and identify when constituents of particular interest appear to
be reaching a relatively constant level. At that point the restoration effort may be ending and
stability phase monitoring may be appropriate.
Tables 3-2 through 3-6 summarize specific assumptions about the CMU configuration
used in estimating the costs for each proposed groundwater monitoring scenario considered. The
number of wells that are sampled during each operational phase (i.e., pre-operational, operations,
3-10
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restoration, stability, and long-term stability monitoring) is assumed to vary among scenarios as
indicated in the tables. These numbers were selected based on professional judgment about the
data needs for each of the scenarios examined. The total number of wells also varies for each
groundwater monitoring scenario. Unit costs assumed for construction of a well are summarized
in Appendix A.
The assumed numbers of wells, duration, and frequency of groundwater monitoring were
combined with the analytical costs for the required parameter lists and the cost for groundwater
sample collection, as summarized in Appendix B (Sampling and Analysis Unit Costs), to
calculate the groundwater monitoring costs by operational phase under
current practice (Table 3-2),
30-year long-term stability monitoring with potential to shorten based on geochemical
modeling (Table 3-3), and
30-year long-term stability monitoring with no potential to shorten (Table 3-4).8
As shown in Table 3-2, under current practice, pre-operational monitoring was assumed
to last for 1 year, sampling from 85 wells for constituents required by the NRC and by
Agreement States. In contrast, under the regulatory alternatives examined in both Tables 3-3 and
3-4, samples are drawn from 100 wells, and the full suite of constituents is analyzed. In addition,
under the proposed rule (30 years long-term stability monitoring with potential to shorten using
geochemical modeling), we assumed that 10 additional wells, located down-gradient from the
wellfield, are also sampled to gather data on the geochemistry of the groundwater in that area for
use in modeling (for a total of 110 wells in Table 3-3). During operations under current practice,
we assumed that 41 wells are sampled; under the proposed rule, we assumed that 56 wells are
sampled, including 15 additional vertical excursion wells. ISR extraction operations were
assumed to last for 6 years. The 6-year duration is consistent with the range of times seen at ISR
sites; actual duration of uranium extraction depends on site-specific conditions. After extraction
operations end, the facility is assumed to begin restoration of groundwater to pre-operational
characteristics. This process involves flushing the production area with clean water (the extracted
water is often processed by reverse osmosis techniques before the water is reinjected to continue
8 EPA also analyzed the costs that might be incurred if geochemical modeling failed to demonstrate conditions
favorable for long-term stability. These costs combine the costs estimated for the proposed rule under Phases 1
through 4 and the costs of Phase 5 (long-term stability monitoring) estimated for the 30-year long-term stability
monitoring alternative.
3-11
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Table 3-2. ISR Conceptual Mine Unit: Current Practice
Sampling
Well Type of Wells Period Frequency Parameters
Phase 1: Pre-operations
1 extraction/injection wells 44 1 year Quarterly NRC and state
(E W/I W) ( 1 well per acre) (4 events)
Down gradient ore zone 0
monitoring wells (OZ-MW)
All perimeter ore zone wells 26
(OZ-PW)
All vertical excursion wells 15
(OW/UW)
Total wells sampled 85
OJ
^ Phase 2: Operations
to
Parameter Analysis Cost (Thousand
Average Low Median
200 160 198
000
118 95 117
68 55 68
386 309 383
$2011)
High
247
0
146
84
478
All perimeter ore zone wells 26 6 years
(OZ-PW)
Vertical excursion wells 15
(Overlying/underlying wells:
OW/UW)
Total wells sampled 41 6
Phase 3: Restoration (or
compliance monitoring)
All extraction wells (EW) 77 2 years
Down-gradient perimeter 6
wells (OZ-PW)
Biweekly Indicator parameters
(156
events)
Quarterly Indicator parameters
(8 events)
2,327
1,343
3,670
353
28
2,137
1,233
3,370
325
25
2,293
1,323
3,616
348
27
2,587
1,493
4,080
393
31
(continued)
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Table 3-2. ISR Conceptual Mine Unit: Current Practice (continued)
Well Type
Down-gradient ore zone
monitoring wells (OZ-MW)
Total wells sampled
Phase 4: Stability (or post-
restoration)
All extraction wells (EW)
Down-gradient perimeter
wells (OZ-PW)
Monitoring wells (OZ-MW)
Total wells sampled
Sampling
of Wells Period Frequency Parameters
0
83
77 6 months Quarterly NRC and state
(2 events)
6
0
83
Total
Duration Number of
of Sampling
Activities Events
9.5 years 170 Total costs:
Parameter Analysis
Average
0
381
175
14
0
189
4,626
Low
0
350
140
11
0
151
4,180
Cost (Thousand
Median
0
375
173
14
0
187
4,562
$2011)
High
0
424
216
17
0
233
5,213
Note: The "Well Type," "Sampling Period," "Sampling Frequency," and "Parameters" criteria were based on discussions with the ISR project team during a
phone conference on 3/26 and 4/16/2013. Total parameter costs include indirect labor, direct labor, travel, fee (8%), and contingency (10%).
1 There are approximately 243 injection (166) and extraction (77) wells shown in the model production area.
2 The "full suite" of chemical parameters includes EPA, NRC, and state required parameters. Based on parameter lists provided in the BID for Revision of 40
CFR Part 192, Revision 6, November 26, 2012. Indicator parameters are Alkalinity, Conductivity, TDS, Chloride, Uranium, and Radium 226 and Radium 228.
3 Range for duration of operations provided by EPA as documented during WA 2-04, Task 2B (contract No. EP-D-10-042).
-------�
Table 3-3. ISR Conceptual Mine Unit: 30-Year Stability Shortened with Geochemical Modeling
Numbers -
Well Type of Wells
Phase I: Pre-operations
Extraction/injection wells 44
(EW/IW) (1 well per acre)
Down-gradient ore zone 10
monitoring wells (OZ-MW)
All perimeter ore zone wells 26
(OZ-PW)
All vertical excursion wells 30
(OW/UW)
Total wells sampled 1 1 0
Phase 2: Operations
All perimeter ore zone wells 26
(OZ-PW)
Vertical excursion wells 30
(Overlying/underlying wells:
OW/UW)
Total wells sampled 56
Phase 3: Restoration
All extraction wells (EW) 77
Down-gradient perimeter wells 6
(OZ-PW)
Sampling Parameter Analysis Cost (Thousand $2011)
Period Frequency Parameters Average
1 year Quarterly Full suite plus 253
(4 events) geochemical parameters
and modeling
58
150
173
633
6 years Biweekly Indicator parameters 2,327
(156 events)
2,685
5,013
2 years Quarterly Indicator parameters 353
(8 events)
28
Low Median High
205 250 312
47 57 71
121 148 184
140 170 213
512 625 781
2,137 2,293 2,587
2,466 2,646 2,986
4,603 4,940 5,573
325 348 393
25 27 31
(continued)
-------�
Table 3-3. ISR Conceptual Mine Unit: 30-Year Stability Shortened with Geochemical Modeling (continued)
Well Type
Down-gradient ore zone
monitoring wells (OZ-MW)
Total wells sampled
Phase 4: Stability
All production unit wells
(IW/EW)
All perimeter ore zone wells
(OZ-PW)
All vertical excursion wells
(OW/UW)
Total wells sampled
Phase 5: Long-Term Stability
All extraction wells (EW)
Down-gradient perimeter wells
(OZ-PW)
Monitoring wells (OZ-MW)
Total wells sampled
Numbers -
of Wells
10
93
77
26
30
133
77
6
10
93
Sampling Parameter Analysis Cost (Thousand $2011)
Period Frequency Parameters Average
46
427
3 years Quarterly Full suite plus 1,330
(12 events) geochemical parameters
Indicator Parameters 242
Indicator Parameters 403
1,716
7 years Quarterly Full suite plus 3,105
(28 events) geochemical parameters
and modeling
242
403
3,750
Low
42
392
1,075
196
326
1,430
2,509
196
326
3,031
Median
45
421
1,312
239
398
1,692
3,062
239
398
3,698
High
51
475
1,639
298
497
2,068
3,825
298
497
4,619
(continued)
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Table 3-3. ISR Conceptual Mine Unit: 30-Year Stability Shortened with Geochemical Modeling (continued)
Sampling
Well Type
of Wells Period
Duration
of
Activities
19 years
Frequency Parameters
Total
Number of
Sampling
Events
208 Total Costs:
Parameter Analysis Cost (Thousand $2011)
Average Low Median High
11,539 9,968 11,375 13,515
Note: The "Well Type," "Sampling Period," "Sampling Frequency," and "Parameters" criteria were based on discussions with the ISR project team during a
phone conference on 3/26 and 4/16/2013. Total parameter costs include indirect labor, direct labor, travel, fee (8%), and contingency (10%).
1 There are approximately 243 injection (166) and extraction (77) wells shown in the model production area.
2 The "full suite" of chemical parameters includes EPA, NRC, state, and additional parameters needed for geochemical modeling. Based on parameter lists
provided in the BID for Revision of 40 CFRPart 192, Revision 6, November 26, 2012. Indicator Parameters are Alkalinity, Conductivity, TDS, Chloride,
Uranium, and Radium 226 and Radium 228.
3 Range for duration of operations provided by EPA as documented during WA 2-04, Task 2B (contract No. EP-D-10-042).
-------�
Table 3-4. ISR Conceptual Mine Unit: 30-Year Stability with No Provision to Shorten
Well Type
Phase I: Pre-operations
1 Extraction/injection wells
(EW/IW) (1 well per acre)
Down-gradient ore zone
monitoring wells (OZ-MW)
All perimeter ore zone wells
(OZ-PW)
All vertical excursion wells
(OW/UW)
Total wells sampled
Phase 2: Operations
All perimeter ore zone wells
(OZ-PW)
Vertical excursion wells
(Overlying/Underlying wells:
OW/UW)
Total wells sampled
Phase 3: Restoration (or
Compliance Monitoring)
All extraction wells (EW)
Down-gradient perimeter
wells (OZ-PW)
Sampling
IXTinnhf*!"^
of Wells Period Frequency Parameters
44 1 year Quarterly Full suite
(4 events)
0
26
30
100
26 6 years Biweekly Indicator parameters
(156 events)
30
56
77 2 years Quarterly Indicator parameters
(8 events)
6
Parameter Analysis Cost (Thousand $2011)
Average Low Median High
227 182 225 281
0000
134 107 133 166
155 124 153 191
516 413 512 638
2,327 2,137 2,293 2,587
2,685 2,466 2,646 2,986
5,013 4,603 4,940 5,573
353 325 348 393
28 25 27 31
(continued)
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Table 3-4. ISR Conceptual Mine Unit: 30-Year Stability with No Provision to Shorten (continued)
oo
Well Type
Down-gradient ore zone
monitoring wells (OZ-MW)
Total wells sampled
Phase 4: Stability (Post-
restoration)
All production unit wells
(IW/EW)
All perimeter ore zone wells
(OZ-PW)
All vertical excursion wells
(OW/UW)
Total wells sampled
Phase 5: Long- Term Stability
All extraction wells (EW)
Down-gradient perimeter
wells (OZ-PW)
Monitoring wells (OZ-MW)
Total wells sampled
Sampling
IXTinnhf*!"^
of Wells Period Frequency Parameters
0
83
77 3 years Quarterly Full suite
(12 events)
26 Indicator parameters
30 Indicator parameters
133
77 30 years Quarterly Full suite
(120 events)
6
0
83
Parameter Analysis Cost (Thousand $2011)
Average
0
381
1,110
179
207
1,495
11,910
928
0
12,838
Low
0
350
954
164
190
1,308
9,535
743
0
10,278
Median
0
375
1,182
176
204
1,562
11,818
921
0
12,739
High
0
424
1,387
199
230
1,816
14,728
1,148
0
15,876
(continued)
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Table 3-4. ISR Conceptual Mine Unit: 30-Year Stability with No Provision to Shorten (continued)
Sampling
Well Type of Wells Period
Duration
of
Activities
42 years
Frequency Parameters
Total
Number of
Sampling
Events
300 Total Costs
Parameter Analysis Cost (Thousand $2011)
Average Low Median High
20,243 16,952 20,128 24,325
Note: The "Well Type," "Sampling Period," "Sampling Frequency," and "Parameters" criteria were based on discussions with the ISR project team during a
phone conference on 3/26 and 4/16/2013. Total parameter costs include indirect labor, direct labor, travel, fee (8%), and contingency (10%).
1 There are approximately 243 injection (166) and extraction (77) wells shown in the model production area.
2 The "full suite" of chemical parameters includes EPA, NRC, and state required parameters. Based on parameter lists provided in the BID for Revision of 40
CFR Part 192, Revision 6, November 26, 2012. Indicator parameters are Alkalinity, Conductivity, TDS, Chloride, Uranium, and Radium 226 and Radium 228.
3 Range for duration of operations provided by EPA as documented during WA 2-04, Task 2B (contract No. EP-D-10-042).
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the restoration process) and frequently introducing reducing agents to attempt to recreate the
conditions that caused the deposit to form in the first place. Under all scenarios, wellfield
restoration is assumed to last 2 years. Under current practice and under the 30-year alternative,
83 wells are sampled for the purpose of obtaining data needed to construct a geochemical model
of the groundwater chemistry. Under the proposed rule, 10 additional down-gradient ore zone
monitoring wells are sampled for the purpose of constructing a geochemical model. Thus, during
pre-operations, operations, and restoration, EPA's costing assumptions result in somewhat higher
costs under the proposed rule than would be incurred under current practice.
The major differences between current practice and the regulatory alternatives that were
considered occur after restoration is assumed to be completed. Under current practice, facilities
typically monitor conditions for 6 months to 2 years (we assumed 6 months), before
decommissioning the wellfield and petitioning to have their license terminated. As discussed
above, examination of the data has led EPA to conclude that this may not be a sufficiently long
period of time to ensure that, as natural oxygenated groundwater begins to infiltrate the wellfield,
uranium, radium, and other constituents may not remobilize. Thus, the two regulatory
alternatives examined incorporate a considerably longer period of post-restoration stability
monitoring. Initially, EPA's proposed rule requires that sufficient data be collected to
demonstrate with 95% confidence that conditions are stable for a period of at least 3 years. The
data required would depend on site-specific conditions; based on the model site, EPA has
assumed for the purposes of estimating costs that monitoring all production wells for the full
suite of constituents and monitoring perimeter and vertical excursion wells for indicator
parameters, on a quarterly basis for 3 years, would develop enough information to provide a 95%
level of confidence that conditions are stable. Finally, both regulatory alternatives specify a
period of long-term stability monitoring to ensure that conditions remain stable. Under the
proposed rule, facilities have the option of reducing the 30-year long-term stability monitoring
period by demonstrating through sampling and hydrogeochemical modeling that conditions
down-gradient are sufficiently reducing that any constituents remobilized would be trapped
down-gradient, preventing widespread contamination beyond the production zone. In the
analysis, EPA assumes that this period of sampling and modeling (the long-term stability
monitoring period) lasts for 7 years.9 In practice, this period may be longer or shorter depending
on the natural variation observed in the monitoring data collected over that period and during the
9 The assumption was made based on EPA's professional judgment that 7 years represents a reasonable mid-range
value, because EPA has reviewed at least one case study showing that monitoring with geochemical modeling at
an ISR site has taken 15 years.
3-20
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preceding stability phase monitoring. The larger the natural variation observed, the longer it
would take to demonstrate that temporal trending is not present in the data. Under the other
regulatory alternative, facilities would be required to conduct long-term stability monitoring for a
period of 30 years, with no possibility for shorting the duration. Thus, the capital and analysis
costs are higher under the proposed rule (as shown in Table 3-5), but the duration is much longer
under the 30-year alternative.
Table 3-5 summarizes the differences in anticipated costs by phase, comparing the
estimated costs under current practice with the estimated costs of the regulatory option being
proposed and for another regulatory option considered but not selected. Costs for each phase are
estimated to be lower under current practice than under the regulatory alternatives. Post-
restoration stability monitoring, in particular, is estimated to have higher annualized costs and
longer duration under the regulatory alternatives relative to current practice. Comparing the
regulatory alternatives to each other, annualized costs are estimated to be higher for the proposed
rule, because it entails more wells and cores, geochemical modeling, and analyzing for more
constituents. Only the operations phase has estimated costs that do not differ between the two
alternatives. Although it does not appear in Table 3-5, the other difference between the two
alternatives is that the selected alternative (30 years of long-term stability monitoring with the
possibility to shorten the duration using geochemical modeling) is estimated to have a shorter
duration than the alternative that was not selected (30 years of long-term stability monitoring
with no potential to shorten the duration).
Table 3-5. ISR Conceptual Mine Unit: Annual Monitoring Cost by Scenario and Phase
(Thousand $2011)
Current Practice
Phase 1. Pre-operational
Phase 2: Operations
Phase 3. Restoration
Phase 4. Stability
Low
$309
$562
$175
$151
Average
$386
$612
$191
$189
High
$478
$680
$212
$233
30-Year Stability with Geochemical Modeling
Phase 1. Pre-operational $512 $633 $781
Phase 2: Operations $767 $835 $929
Phase 3. Restoration $196 $213 $237
Phase 4: Stability $477 $572 $689
Phase 5. Long-term stability $433 $536 $660
(continued)
3-21
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Table 3-5. ISR Conceptual Mine Unit: Annual Monitoring Cost by Scenario and Phase
(Thousand $2011) (continued)
Current Practice
Low Average High
30-Year Stability with No Provision to Shorten
Phase 1. Pre-operational $413 $516 $638
Phase 2: Operations $767 $835 $929
Phase 3. Restoration $175 $191 $212
Phase 4: Stability $436 $498 $605
Phase 5. Long-term stability $343 $428 $529
3.2.1.2 Annualized Capital Costs and Incremental Costs of the Rule for the CMU
After the capital (well construction) and monitoring costs were estimated for the CMU
under each regulatory alternative for each phase of ISR operations, the next step involves
comparing the costs of each alternative with the costs incurred under current practice. To do this,
EPA created a time series of monitoring costs under the current practice and under the three
regulatory alternatives. EPA then annualized the capital cost under current practice and under the
three regulatory alternatives, using a 7% interest rate and an assumed loan duration of 15 years
(for current practice, which in our illustration is expected to have an overall duration of between
10 and 15 years) or 20 years (for all regulatory alternatives). In each year, total annualized costs
of compliance are the sum of the monitoring cost for that year and the annualized capital cost
estimated to be incurred in that year. To measure the cost impact of each regulatory alternative,
EPA computed the incremental compliance cost by subtracting the costs of compliance under the
regulatory alternative minus the costs that would be incurred absent the proposed rule. For each
stream of costs, EPA computed the total sum across all years and the discounted present value of
each stream of costs using a 3% and a 7% discount rate. Finally, to obtain a single annualized
cost value for current practice and for each regulatory alternative, EPA annualized the costs
using a 7% interest rate over a period of 42 years. This treats all the costs in an equivalent
manner and provides a single uniform annualized value for the monitoring costs under each
regulatory alternative, which can be added to the annualized capital cost to provide a total
annualized value that is uniform across time. Table 3-6 shows the annual cost, the sum, and the
discounted values under 3% and 7% discount rates for monitoring costs, capital costs, and
incremental costs.
3-22
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Table 3-6. ISR Conceptual Mine Unit: Annualized Monitoring and Capital Costs for Current Practice and Each Regulatory
Scenario (Thousand $2011)
With-Regulation Monitoring
Costs
Summed cost
NPV, 3%
NPV, 7%
Current
Practice
$4,626
$4,029
$3,396
30 year,
Geo-
chemical
Modeling
$11,739
$9,087
$6,787
30-Year
Long-
Term
Stability
$20,243
$12,155
$7,487
Geo-
chemical
Modeling,
Extended
$20,935
$12,703
$7,908
Current
Practice
$8,418
$6,699
$5,111
Annualized
30 year,
Geo-
chemical
Modeling
$10,684
$7,947
$5,659
Well Costs
30-Year
Long-
Term
Stability
$10,522
$7,703
$5,429
Incremental Total Annualized
Costs by Scenario, Relative to
Current Practice
Geo-
chemical
Modeling,
Extended
$10,684
$7,947
$5,659
30 year,
Geo-
chemical
Modeling
$9,379
$6,306
$3,939
30-Year
Long-
Term
Stability
$17,721
$9,130
$4,409
Geo-
chemical
Modeling,
Extended
$20,935
$12,703
$7,908
Notes:
oj Capital costs are annualized as follows:
£J Current Practice capital costs are annualized at 7% over 15 years, reflecting assumption that operations at a site would last at most 15 years.
Geochemical capital costs are annualized at 7% over 20 years, consistent with expected life of capital equipment.
30-year capital costs are annualized at 7% over 20 years, with an assumed 10% of wells requiring replacement after 20 years.
Incremental total annualized costs subtract the estimated annualized monitoring and capital costs for each regulatory scenario minus the estimated annualized
monitoring and capital costs under current practice.
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3.3 Estimated National Costs of Proposed Rule
The final step in estimating the costs of the rule and evaluating how they compare with
the costs of current practice requires extrapolating from the costs estimated for the CMU to
estimated costs that apply to ISR facilities projected to exist in 2014. As mentioned in Section 2,
above, six ISR facilities currently operate: La Palangana, Alta Mesa, Willow Creek (Christensen
and Irigaray), Crow Butte, Lost Creek, and Smith Ranch-Highland-Reynolds. Several other ISR
facilities are in various stages of licensing and are not in operation. The cast of ISR facilities in
operation can be expected to vary over time, depending on uranium market conditions and how
long it takes to extract the uranium from deposits at each facility. EPA has chosen to use the
existing ISR operations in 2013 and the companies that own them as models for ISR facilities
and owner companies likely to exist in the future and thus be affected by the proposed rule. EPA
had some information about existing ISR facilities, but not sufficient information to estimate
their costs on a facility-specific or wellfield-specific basis. Thus, it was necessary to extrapolate
or scale up the costs estimated for the CMU to estimate costs that would be incurred by existing
ISR facilities.
EPA examined three possible bases on which to extrapolate the CMU costs to estimate
the costs that would be incurred at ISR facilities:
facility capacity
uranium production
wellfield acreage
After considering these options, as described below, EPA determined that extrapolation based on
wellfield acreage is the most reasonable basis.
Facility capacity is reported by the EIA in its Uranium Production Report, so it is
available for all planned and actual ISR facilities. However, facility capacity is measured in
terms of the production capacity of the processing plant. Although this may be correlated to the
size and complexity of the wellfield, and thus to the capital and operating costs of monitoring,
the link is not close and would not seem to provide a reliable method of scaling site-specific
costs to nationwide estimates.
Uranium production at a particular facility may vary widely from year to year because of
changing conditions in the uranium market or facility-specific factors. We do not, however,
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expect monitoring requirements or costs to vary significantly from year to year, although we
recognize that they vary depending on the phase of the ISR operation.
Some correlation can generally be assumed between the size of the wellfield and the
numbers of wells required for monitoring and, therefore, between the size of the wellfield and
the corresponding well and groundwater sampling costs. Thus, EPA chose to use wellfield
acreage as the basis on which to scale up costs from the CMU to the facility level. EPA obtained
maps of wellfields or used available published information for the five existing ISR facilities to
estimate the acreage of each wellfield. There is a large variation in the size of existing wellfields
based on the information available from a variety of sources. Individual wellfield size for the
sites considered ranges between approximately 7 acres and 750 acres. The total acreage of all the
individual wellfields at each of the ISR sites considered is shown in Table 3-7.
The costs that would be incurred by each ISR facility under current practice and under
each regulatory alternative were estimated based on the ratio of the ISR facility's total wellfield
acreage to that of the CMU (see Table 3-7).
Table 3-7. Estimated Total Acreage of All Wellfields at ISR Sites
ISR Operation Acres
LaPalangana3 210
AltaMesa 330
Willow Creek 409
CrowButte 1,524
Smith Ranch-Highlands-Reynolds 6,582
Lost Creek 254
Conceptual model unit 202
a Palangana total acreage scaled up by 50% to estimate area including PAA3.
Note: Most site acreages computed using site map and planimeter.
Table 3-8 shows estimated costs for each of the ISR facilities, based on the total acreage
of the wellfield at each facility. EPA recognizes that not all the wellfields at all facilities may be
in the same phase of uranium recovery at a given time; some may be in a planning stage, others
actively being mined, while others are undergoing restoration and still others may be
decommissioned. To evaluate potential impacts based on a conservatively high range of costs,
we estimated costs using 100% of wellfield acreage at each facility to analyze the economic
impacts of the proposed rule; generally, this overstates annual costs. An uncertainty in this
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approach relates to the potential for ISR sites to contain multiple ore zones within the same
surface area (i.e., ore bodies located at different depths and separated by isolating beds), thereby
allowing sequential uranium recovery within the same surface footprint. In that situation, acreage
Table 3-8. Total Average Annualized Incremental Costs for Individual ISR Operations
(Thousand 2011$)
Regulatory Scenario
Cost per acre
ISR operation
La Palangana
Alta Mesa
Willow Creek
Crow Butte
Smith Ranch-Highland-
Reynolds
Lost Creek
National Cost
30 year, Geochemical
Modeling to Shorten
$1.45
$304
$477
$591
$2,205
$9,521
$367
$13,465
30 Years, No
Shortening
$1.62
$340
$534
$661
$2,468
$10,657
$411
$15,072
Geochemical
Modeling, Extended
$1.86
$390
$613
$759
$2,832
$12,229
$472
$17,296
would not be as closely correlated with costs of complying with the rule. Facility-level
incremental total annualized costs are estimated to range from $304,000 to $9.52 million10 under
the proposed rule (30-year with geochemical shortening option), and from $340,000 to $10.7
million under the required 30-year monitoring option, when costs are calculated based on the
entire wellfield acreage. Facility-level incremental total annualized costs were also estimated for
the worst case scenario, under the proposed regulatory approach, to be from $390,000 to $12.2
million with the failure of geochemical modeling to predict a stabilized condition in the wellfield
then requiring 30-years of long-term monitoring.
National costs computed using this assumption are $13.5 million for the proposed rule,
30 years with geochemical modeling, and $15.1 million under the 30-year long-term stability
monitoring alternative. Under the scenario where geochemical modeling is followed by 30 years
of long-term stability monitoring, average national total annualized costs are estimated to be
$17.3 million. The well costs and the duration and frequency of sampling assumed for costing
these scenarios are different. The geochemical scenario incorporates additional well and boring
This represents the sum of estimated costs for Smith Ranch, Highland, and Reynolds.
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costs and assumes fewer years of sampling are needed. The frequency of sampling is consistent
between the scenarios considered but the geochemical modeling scenario accounts for additional
constituents that will need to be sampled and monitored. Labor and other routine costs were held
constant between the scenarios considered. Table 3-9 presents summary values for national-level
costs, including annualized, summed, and discounted present value of costs. Finally, national
well development capital costs are presented in Table 3-10. The well development costs for
geochemical modeling with required 30-year monitoring are based on the well development
costs for geochemical modeling.
Table 3-9. Estimated Average National Incremental Cost Summary (Thousand 2011$)
Regulatory Scenario
Total annualized cost
Total cost, summed across LOM
Present value, 3% discount rate
Present value, 7% discount rate
30 Year,
Geochemical
Modeling to
Shorten
$13,465
$431,284
$289,991
$181,135
30 Years
$15,072
$814,903
$419,826
$202,754
Geochemical
Modeling,
Extended
$17,296
$854,177
$456,257
$232,673
Scaled up from CMU costs to national costs based on estimated total acreage. LOM is life of mine.
Table 3-10. Incremental Total Capital Costs (Thousand 2011$)
Cost, $
30 years with geochemical modeling $25,203
30 years long-term stability monitoring $19,339
Scaled up from CMU costs to national costs based on estimated total acreage.
3.4 Uncertainties and Limitations
EPA illustrated three regulatory alternatives using a CMU. As part of this exercise, we
assumed the duration of each phase of the ISR monitoring operation. These durations are
reasonable, but arbitrary assumptions. All could be longer, and all except the 30-year post-
monitoring schedule under those regulatory alternatives could be shorter.
A major set of uncertainties arises from the process used to extrapolate from the
estimated costs of each regulatory alternative at the CMU to costs that would be incurred by
other ISR facilities. Due to limited resources and data accessibility, EPA's cost estimates are
based on a model facility approach, with the model derived from the characteristics of a single
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wellfield at one ISR facility. Additional data collection could help to refine these cost estimates;
however, despite these limitations we believe that the cost estimates presented here would
generally approximate those for mine units characteristic of other ISR sites. EPA also recognizes
that compliance actions required at a particular site depend on the characteristics of the site; the
characteristics of the CMU may not closely correspond to characteristics of other existing or new
ISR facilities. Thus, the costs actual ISR facilities incur may differ from the costs described here.
Further, EPA is using existing ISR facilities as models for future ISR facilities that may be
subject to the proposed rule at different times in the future. Although future ISR facilities may
differ in various ways from existing ISR facilities, EPA nevertheless believes that the existing
facilities provide the best guide available as to what future ISR facilities may be like.
Another uncertainty is the cost savings a facility may experience if it applies for and
receives an ACL. EPA recognizes that ISR facilities that are attempting to restore and stabilize
an ISR site may determine that they are unable to return contaminant concentration levels for all
constituents to baseline/pre-operational levels as required. In that situation, facilities may apply
for an alternative concentration limit for those constituents. Receiving approval of ACLs would
likely enable the facility to stop its restoration/stabilization activities, rather than continuing
efforts to achieve pre-operational levels of all constituents. This arrangement would likely reduce
the number of years over which the site would have to be monitored. Obtaining an ACL would
also entail some additional effort and cost associated with negotiating the ACL with the licensing
agency. As an example of such costs, if a constituent (e.g., radium or a trace metal) remains
above the restoration goal, the owner/operator may make an argument that the adverse health
effects of the higher concentration level are not significant. In that example, a dose assessment
would be part of the operator's case to obtain an ACL and such an assessment would entail costs
to gather data and perform the assessment. EPA does not have enough information to enable it to
estimate the cost savings associated with ACLs, but we do recognize that there could be cost
savings, relative to extensive efforts to achieve pre-operational levels for all constituents.
Requirements for licensing are described in 10 CFR Part 171.16, and financial assurance
requirements for ISR operations are described in 10 CFR Part 40, Appendix A, Criterion 9.
EPA's proposed rule will not change the substance of the requirements affecting ISR facilities,
but it will potentially change the duration over which a facility is subject to the requirements and
thus incurs the costs. Because both types of requirements are set for the entire facility (although
they vary depending on the activities currently under way at a facility), as long as any activity is
under way at a facility, the facility will incur the costs of complying with the requirements.
License fees range from $35,400 to $40,000 per year, but drop to zero if only decommissioning
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is occurring. Financial assurance costs continue through decommissioning, but decline as more
of the site is decommissioned. Throughout the life of an ISR operation, the costs associated with
licensing and financial assurance would, in EPA's assessment, be unaffected by the proposed
rule, until only one wellfield is still in operation or undergoing decommissioning. . The longer
duration of monitoring required would cause the firms to incur the costs associated with financial
assurance for a longer period of time (potentially 30 years). However, as the number of
wellfields in operation declines, and the amount of radioactive material onsite declines, the
magnitude of the financial assurance required would decline proportionally. EPA thus believes
that the additional costs associated with payment of license fees and financial assurance would
be small relative to other incremental costs and thus we did not include them in our quantitative
estimate of costs and impacts.
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Section 4
BENEFITS ANALYSIS
The benefits from revising Part 192 will primarily result from measures to prevent future
occurrences of groundwater contamination and protection of groundwater resources for future
generations. By requiring owners and operators of ISR facilities to take actions that ensure the
long-term stability of geochemical conditions in on-site and nearby aquifers, the revisions will
(1) help preserve the quality and quantity of increasingly scarce groundwater resources in the
U.S., (2) reduce potential human and environmental health risks associated with contaminant
exposures, and (3) avoid potential future remediation costs, which would be required if the
existence and migration of groundwater contaminants were not detected prior to
decommissioning the site. In addition, by incorporating constituent-specific standards that are
flexibly referenced to SDWA and RCRA standards for groundwater contaminants, the proposed
revisions will reduce the Agency's administrative burden from periodically reviewing and
revising standards to ensure consistency. In so doing, they will also incorporate recently revised
and more protective standards for arsenic and uranium, which will also contribute to reduced
risks to human health and the environment.
Due to data limitations and resource constraints the monetary value of these benefits
cannot be fully quantified and aggregated across ISR sites in the U.S. However, it is possible to
provide a detailed qualitative discussion and partially quantified description of the expected
benefits of the proposed rule. The purpose of this chapter is to assist decision makers by
providing this discussion and description of benefits.
4.1 Conceptual Framework and Methods for Valuing Groundwater Resources and
Groundwater Protection
Water is vital to a productive and growing economy in the United States, directly and
indirectly affecting the production of goods and services in many sectors. Current economic
literature provides many insights into the importance of water to various sectors, including
agriculture, tourism, fishing, manufacturing, and energy production, but this information is
dispersed and, in many cases, incomplete. To take stock of what is currently known and where
the main knowledge gaps lie, EPA has been conducting a study on the importance of water in the
U.S. economy (U.S. EPA, 2012d). The main objectives of the study include (1) summarizing
existing knowledge about the role and importance of water to the U.S. economy; (2) providing
information that supports private and public sector decision-making, and (3) identifying areas
with additional research needed. The draft findings show that, although water plays an essential
and vital role in the economy, it is enormously difficult to place a monetary value on its
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contribution, in part because the value of water varies greatly both within and across sectors of
the economy.
Although groundwater resources play a vital role in the U.S. economy, the economic
value of these resources extends beyond their current contribution to market production. To
understand and fully account for the contributions of groundwater to human well-being is useful
to refer to the concept of "total economic value" (TEV) (Young, 2005). As shown in Figure 4-1,
TEV includes both use and nonuse values.
Figure 4-1. Main Components of the Total Economic Value (TEV) of Groundwater
Resources
Total Economic Value (TEV)
Use Value
Nonuse Value
Extractive Value
In-situ Value
Option Value
Existence Value
Bequest Value
Use values include the well-being that is derived from direct use of the resource by
individuals or households, for example as a source of drinking water. It also includes values from
indirect use, such as through groundwater's contribution to the production of goods or services
people enjoy (e.g., agricultural commodities). As noted in a 1997 National Academy of Sciences
study of groundwater valuation (NAS, 1997), use values for groundwater can also be divided
into extraction value and in-situ value (also described as consumptive vs. nonconsumptive use
values). Extraction value is widely recognized, and includes the value of groundwater used for
drinking water, industrial water supply, and agriculture. Values for in-situ services are (or were
in 1997) less well-known. They represent services or values that occur or exist as a consequence
of water remaining in place within the aquifer. They include the capacity of groundwater to
(1) buffer against periodic shortages in surface water supplies; (2) prevent or minimize
subsidence of the land surface from groundwater withdrawals; (3) protect against sea water
intrusion; (4) protect water quality by maintaining the capacity to dilute and assimilate
groundwater contaminants; (5) facilitate habitat and ecological diversity; and (6) provide
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discharge to support recreational activities. One potential additional source of use values is
"option value," which refers to the value that humans derive today from preserving the option to
use the resource (directly or indirectly) in the future.
Nonuse values refer to well-being derived from the resource that is not associated with an
individual's current or future use of the resource. Two main types of nonuse values are (1) the
"existence" value that individuals may derive simply from knowing that a resource exists and is
being protected, even if they do not or have no intention to use the resource directly or indirectly
and (2) the "bequest" value individuals derive from know that a resource is being preserved for
future generations to use.
One of the main challenges with valuing groundwater resources and their services is that
they are typically not privately owned or exchanged in markets. As a result, one cannot rely on
market prices for groundwater to infer its values. To address this problem, which is common for
many public goods and natural resources, economists have developed variety of nonmarket
valuation method. These methods are typically divided into two main categories: revealed and
stated preference methods.
To infer nonmarket use values, revealed preference (RP) methods rely on information
from market activities or other human behaviors that are related to the resource of interest. For
example, the value of groundwater as an irrigation resource can be inferred from the value it
contributes to products sold in agricultural markets. Similarly, the value of protecting
groundwater quality as a source of household drinking water may be inferred from substitute
sources of drinking water (e.g., bottled water prices) or from differences in housing prices in
areas with different groundwater quality. Unfortunately, RP methods cannot be used to estimate
nonuse values for natural resources, because they require a behavioral connection to the resource
of interest in order to infer values.
The value of protecting groundwater quality may also, in some cases, be inferred from
the avoided future costs of restoring the resource. This approach, which is sometimes grouped
with RP methods, is meaningful if there is a high likelihood that (1) restoration activities will be
implemented if groundwater contamination occurs and (2) restoration activities will not be
needed if the groundwater is protected.
Stated preference (SP) methods employ household surveys to more directly measure
people's nonmarket values. To address the lack of existing markets for the good or service of
interest, SP surveys present respondents with hypothetical markets or scenarios and elicit their
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willingness to pay (WTP) for defined changes (e.g., improvement in groundwater quality). One
of the main advantages of SP methods is that they allow researchers to specifically define the
nonmarket "commodity" of interest. Moreover, unlike RP methods, they can be used to capture
and estimate nonuse value. The main drawback of these methods is that it is difficult to validate
WTP estimates based on responses to hypothetical conditions.
A number of studies have used SP methods to estimate U.S. households' WTP for
protecting and improving groundwater quality; however, most of these studies were conducted in
the 1980's and 1990's. Using meta-analysis, Poe et al. (2001) reviewed and synthesized key
findings from this empirical literature. In particular, they identified and analyzed 105 WTP
estimates from 12 studies. They found that the types of groundwater changes described and
analyzed in these SP studies varied widely, and consequently the mean annual WTP estimates
also varied significantly from $46 to $1,316 (in 1997 dollars). Using a consumer price index
adjustment, this range is equivalent to $64 to $1,844 in 2011 dollars.
Poe et al. used regression methods to investigate the main determinants of this variation
in WTP. For example, they differentiated between studies that focused mainly on use-related
values associated with drinking water protection and those that used a broader environmental
perspective and included nonuse values related to aquifer protection. They found that including a
nonuse perspective had a significantly positive effect on WTP. They also differentiated studies
that specifically mentioned cancer risks associated with groundwater contamination. They found
that WTP estimates were higher in these studies, but only at a moderate level of statistical
significance.
4.2 The Benefits of Proposed Changes in Monitoring Requirements
The purpose of the proposed change in monitoring requirements, including requiring
improved characterization of groundwater prior to uranium recovery and more extensive
restoration and post-restoration stability monitoring, is to reduce the probability and magnitude
of potential groundwater contamination incidents resulting from ISR operations.
Currently NRC allows ISR operators to terminate their license at the end of a relatively
short (one to two years) stability monitoring phase. However, this practice means that any later
contamination might not be detected and corrected in a timely manner. If oversight at these
facilities ends before groundwater conditions have in fact stabilized, there is the potential for
ongoing contamination.
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Thus, the proposed rule's provisions help to ensure that any potential excursions
occurring after the completion of production operations are detected and corrected. As a result,
they would ensure that groundwater and, potentially, the surface water to which it discharges,
remain at levels the groundwater was restored to. Stability period monitoring ensures that the
long-term trends in the groundwater concentrations stay within the target restoration
concentrations ensuring the stability of the aquifer water quality and class of use required by
regulatory authorities (Davis, 2007). This monitoring reduces the probability of water quality
degradation within the exempted aquifer, prevents further degradation of the overlying or
underlying aquifer, and reduces the probability of aquifer degradation outside the ore zone. By
ensuring that groundwater conditions within the exempted aquifer are in fact stable, the proposed
stability monitoring program will reduce the likelihood of undetected degradation of conditions
in the exempted aquifer and adjacent aquifers. Thus, the proposed stability monitoring program
would result in a higher probability that adverse human health and environmental impacts will be
avoided.
There are several potential benefits associated with preventing groundwater
contamination due to post-restoration exceedances/excursions at ISR facilities. The following
discussion describes three main areas and offers insights into the potential magnitude of these
benefits.
4.2.1 Reducing Potential Human Health Risks Associated with Contaminant Exposures
If excursions occur from ISR facilities and aquifers are contaminated, the main potential
risks for human health would be those associated with exposures to radionuclides in well water
used for drinking or agriculture in areas located down-gradient from an ISR site. Most
importantly, EPA considers all radionuclides to be known (category A) human carcinogens, and
exposures to radiation can cause cancers in almost all tissues and organs in humans.11
To evaluate the potential human health risks that would occur if groundwater
contamination were to result from ISR operations, EPA evaluated a number of exposure
scenarios and pathways (U.S. EPA, 2012c). The findings of this analysis indicate that the
migration of contaminants into aquifers in the vicinity of an ISR site has the potential to cause
significant exposures and risks for selected receptors. For example, the maximum of the
estimated adult cancer risks from these scenarios was an increased latent cancer fatality risk of
almost 5 in 1000 per year of exposure. However, due to the slowness of the groundwater
11 See for example EPA's Users Guide for Radionuclide Carcinogenicity, found at
http://www.epa.gov/radiation/heast/docs/heast ug 0401.pdf
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transport process, it could take several decades or more for the contaminants to reach down-
gradient wells that could potentially be used by humans. Also, the exposure scenarios examined
in the analysis deal with failures of the ISR operations during the operating phase, such as leaks
from extraction wells into overlying potable water aquifers or surface spills during operations.
These scenarios can pose exposure risks, but implementing a robust regulatory regime during
operations (the responsibility of the NRC or Agreement States) would minimize the potential for
significant exposures.
Estimating the monetary value of health benefits from the proposed rule requires
estimates of the expected number of cancer cases and fatalities that would be avoided. To
estimate the benefits of avoided mortality risks from its programs and policies, EPA recommends
multiplying the number of avoided deaths by a "value of statistical life" (VSL) concept, with a
central default estimate of $8 million per avoided premature death. This VSL estimate is based
on a review and synthesis of findings from several empirical nonmarket valuation studies, which
estimate individuals' WTP to reduce their own probability of premature death. Unfortunately,
due to uncertainties and data limitations, including lack of certainty regarding the size of future
populations in proximity to ISR operations, it is not possible to estimate these population-level
risk changes for this rule; however, the VSL of $8 million at least provides a point of reference
for understanding the potential value of health benefits of the proposed rule. It is also worth
noting that the unit value for avoided cancer fatalities may be even higher than the $8 million
VSL. Economic studies of VSL suggest that people value reductions in cancer risks by more than
similar reductions in noncancer risks of mortality, because individuals fear the pain and other
symptoms associated with cancer more than they fear, for example, traffic or work-related
accidental death (U.S. EPA, 2010). Moreover, as previously described, the findings from the Poe
et al. (2001) meta-analysis of groundwater valuation studies suggest that individuals place a
particularly high value on avoiding groundwater contamination when cancer risks are involved.
4.2.2 Protecting Groundwater Resources for Future Generations
As described above, groundwater resources provide a wide variety of extractive, in-situ
uses, and nonuse values and services to human populations in the U.S.; however, the ability to
sustain these services over the long term is being threatened by groundwater scarcity. Due to
population growth and technological advances, the pace of groundwater extraction in the U.S.
has increased significantly in the last 75 years (Reilly et al, 2008). As a result, declining
groundwater resources are a growing concern in many parts of the country. Continuing
population growth and the additional threats to water resources posed by climate change only
serve to reinforce these concerns.
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Growing scarcity also means that existing groundwater stocks are becoming increasingly
valuable. Therefore, even though the aquifers in the vicinity of ISR operations are currently
providing relatively little extractive value (due to their locations in relatively sparsely populated
areas), there are potentially significant longer term benefits to protecting these resources for
future generations. The fact that ISR operations are mostly located in arid regions of the country
where water scarcity is a chronic problem further underscores the significance of these benefits.
Empirical evidence regarding these "bequest" values for protecting groundwater
resources is limited; however, the Poe et al. (2001) meta-analysis provides some insights into the
magnitude of these nonuse values. In particular, valuation studies that focused broadly on aquifer
protection, rather than more specifically on use values associated with drinking water protection,
had average WTP estimates that were larger by $531-$736 per household.
4.2.3 Avoiding Potential Future Remediation Costs
Under current conditions, due to limited post-restoration monitoring by ISR operations,
the potential exists for groundwater contamination to occur and go undetected over a long period
of time. Such processes could occur if the initial injection of oxidizing agents into the deposit
also destroyed the natural reducing capacity in the host rock that immobilized the uranium
initially. Later injection of chemical reducing agents may then only produce a temporary
reduction of uranium mobilized by the lixiviant injection. Over time the influx of oxidized
groundwater from up gradient of the deposit may remobilize the uranium, radium, or other
constituents, and result in contaminant migration down gradient.
If such contamination does occur and is only discovered after a long delay, extensive and
costly remediation would most likely be required to remove the contaminants from the aquifer
and reduce human health and environmental risks to acceptable levels. As the time period before
detection increases, it is also likely that the spatial extent of contamination and the corresponding
remediation costs would increase. A long delay before detection could also decrease the
likelihood that the ISR owners/operators will be held responsible for the cleanup costs and
instead the burden could be shifted to future taxpayers.
Consequently, one of the expected benefits of the proposed rule will be to increase the
likelihood of detecting mobilized uranium, radium, or other constituents at an early stage and
therefore avoiding costs associated with more extensive remediation activities. To analyze these
avoided remediation costs, we used the model facility described in Section 3, and applied the
parameters of this facility to develop cost estimates for alternative remediation scenarios.
Appendix C provides a detailed description of the methods and assumptions used to construct
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these remediation cost estimates. Note that this is an illustration of potential costs and cost
savings associated with the proposed rule for a model mine unit; because we have no idea of
which (if any) wellfields would experience a remobilization after restoration, EPA is unable to
estimate national cost savings from reduced remediation costs.
As described in Appendix C, EPA used different assumptions about groundwater flow to
estimate distance from the location where the constituents are first mobilized to the nearest
monitoring well, and hence how long it would take for contamination to be detected. In addition,
a variety of Kd12 values were used, to reflect a variety of assumptions about how readily
constituents are transported in groundwater. For purposes of this discussion, we focus on
calculations assuming that Kd = 6.0E-06 m3/gm. The Kd variable is a site specific measurement
and limited examples were found for actual ISR sites that were measured either as part of
baseline or after restoration was completed. The value selected for modeling purposes was a
referenced (FJ. Pearson Jr., CJ. Noronha, and R.W. Andrews, 1983) Kd measured at a roll front
sandstone site and was used as a representative general condition.
To evaluate the potential magnitude of the benefits associated with avoided remediation
cost, we compare two main scenarios. The first scenario represents conditions without the
proposed rule. Under this scenario, contamination is detected after the site is decommissioned
and the license is terminated.13 Three situations are examined: a small plume that is
approximately 10% of the wellfield, or a larger plume that fills the entire wellfield. Once
contamination is detected, this scenario estimates that remediation activities would continue for a
period of 30 years (small plume) or 60 to 75 years (larger plume), involving pumping and
treatment of contaminated groundwater from approximately 70 wells. For the larger plume, costs
and duration vary depending on assumed direction of groundwater flow; we examine two
possible directions because the current direction appears to be different from historical direction,
possibly because of other mining activities in the area. Estimated total annualized costs of this
scenario range from $1.45 million (small plume) to $10.3 to $10.5 million (large plume).14
Because the site has been decommissioned and the license terminated, remediation costs might
be borne by the taxpayer. Total costs, as shown in Table 4-1, range from $35.3 million for a
12 Sorption partition coefficient that controls the degree of linear sorption represented by the model.
13 The actual time of detection depends on when someone drills a well in this location and tests the water at the
correct time to detect the plume. In fact, if the facility has been decommissioned, it could be a long time before
someone drills a well into the contaminated aquifer.
14 Note that these costs do not include costs of scoping efforts to identify the size of the plume and develop a
remediation strategy.
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small plume to $586 million for a large plume, where the groundwater flows along the length of
the wellfield.
The second scenario represents conditions with the proposed rule. In this case,
contamination is assumed to be detected during long-term stability monitoring. We use costs for
the 30-year with no geochemical modeling alternative, and assume that monitoring within the
wellfield detects an increased concentration of constituents ten years into the 30 year period.
When the remobilized constituents are detected, the licensing agency would require the
owner/operator to resume restoration activities, in an effort to achieve restored, stable conditions.
To estimate the costs of this additional restoration, we use the estimated restoration costs for the
original restoration phase. We assume that the second restoration would be successful and no
further remobilization of constituents is detected. After this second restoration, the facility would
monitor to ensure that constituent levels are stable at 95% confidence for 3 years, then continue
to monitor to ensure that stability is maintained for 30 years. EPA estimates that the cost of these
activities would total $27.1 million.
The resulting estimates of avoided remediation costs for the model facility are
summarized in Table 4-1. The summary costs for each scenario are expressed as a lump sum
value, computed by summing costs across time. The avoided remediation costs are calculated as
the difference between the two scenarios. Therefore, for this example facility and post-
restoration contamination profile, the estimated benefits from the proposed rule include a value
of at least $8.2 million to nearly $560 million in avoided remediation costs, including both
capital/well development costs and annual costs.
In addition, the proposed rule is expected to shift the burden of required groundwater
cleanups from future taxpayers to the owners and operators of ISR facilities. By requiring ISR
operations to conduct more extensive long-term stability monitoring, it is more likely that
movement of contaminants will be detected in the short term while owners and operators are still
responsible for the site. Conversely, it is less likely that contamination episodes will go
undetected for years into the future and be detected only after the facility has been
decommissioned, thus reducing the probability of larger and taxpayer funded remediation
activities.
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Table 4-1. Summary of Avoided Remediation Cost Estimates for Model Facility with
Post-restoration Groundwater Contamination (million 2011 $)
Sum of Costs Over Time
Plume Size and
Groundwater Flow
Direction
Small Plume
Large Plume, Transverse
Large Plume, Along
Without-regulation
Scenario
(A)
$35.3
$481.0
$586.1
With-Regulation:
Compliance and
Additional Restoration
(B)
$27.1
$27.1
$27.1
Avoided Remediation
Costs
(A) - (B)
$8.20
$453.1
$559.0
Further, the proposed rule, with its geochemical modeling and monitoring components,
provides both the regulator and the public with evidence that restored wellfield conditions will
remain stable into the future and that the operator can be released from a 30-year long-term
stability monitoring requirement and the site decommissioned, with greater confidence in its
long-term safety than could be achieved based on monitoring alone.
4.3 Setting Groundwater Protective Standards
The second component of the revised regulation aligns the groundwater standards to
current regulatory criteria (i.e., primary and secondary maximum contaminant levels (MCLs)
under the SDWA and/or maximum concentration of hazardous constituents for groundwater
protection under RCRA). The primary benefit to households of revising the standards will be
reduced risk of adverse human health and environmental impacts.
As proposed, the revisions will reduce the need for EPA to update the regulations each
time a standard changes and avoid the rulemaking process for each update, thus reducing future
regulatory burden on both EPA and the regulated community. Rather, EPA would take comment
during the rulemaking process for the primary rule that is being changed. Currently the list of
groundwater standards is out of date and not aligned to SDWA and RCRA. Aligning the
standards will ensure that the standards stay current with other regulations and increase the
probability that society will be protected from risks to human health and the environmental. The
requirement requires that regulators and operators update their plans based on the latest
standards, but it relieves EPA of the costs associated with updating the regulation each time a
standard is changed and ensures that there are no lags in updating the standards, which would
potentially expose the public to risks.
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4.4 Comparison of Benefits and Costs of the Proposed Rule
Since EPA conducted a qualitative assessment of the benefits of the proposed rule, a
direct quantitative comparison of total benefits and costs is not possible. However, the analysis
described in this section does provide some limited insights into the relative magnitude of costs
and benefits. In particular, for the model facility with a defined excursion of groundwater
contamination, the estimated net present value of avoided remediation costs is at least $35.0
million, whereas the NPV of monitoring costs plus a second remediation has an estimated NPV
of $11.0 million, based on average costs and using a 3% discount rate. Therefore, for this
example, the cost avoidance benefits exceed the costs. Whether this relationship holds at an
aggregate level, however, depends importantly on (1) the likelihood of groundwater
contamination events across all sites and (2) the similarity of conditions at other sites to those at
the model facility.
4.5 Caveats and Uncertainties
Although the proposed rule is expected to provide substantial benefits by helping to
ensure that potential groundwater contamination occurrences from ISR operations are promptly
detected and addressed, it is not possible to reliably quantify the total magnitude of these
benefits. One of the main sources of uncertainty is a lack of adequate data and models for
estimating a full probability distribution of all alternative groundwater contamination scenarios
across all current and future ISR sites. Instead, to provide a general understanding of avoided
remediation costs and avoided health risks, EPA has examined a limited number of groundwater
contamination scenarios at a defined site to illustrate the magnitude of potential remediation
costs. It should not be assumed that all restored ISR wellfields will fail in the long-term. A
second important source of uncertainty is for estimating benefits is the very long term nature of
potential groundwater contamination episodes. Although future generations will certainly benefit
from avoided contamination, it is very difficult to reliably predict the size and locations of
potentially affected future populations.
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Section 5
ECONOMIC IMPACT ANALYSIS
EPA examined the economic impacts that may result from the proposed rule, using
information about the industry and estimated incremental costs that would result from the
proposed rule and from one additional regulatory alternative, and employing accepted economic
analysis methods.
5.1 National Costs
EPA first estimated the total annualized national cost of the proposed rule, as a measure
of the overall impact the proposed rule might have on the uranium industry and the national
economy. As described in Section 3, EPA estimated the incremental annual costs of monitoring
for ISR facilities; EPA first estimated the costs under current practice and under two regulatory
alternatives for a conceptual mine unit (CMU) model facility. Incremental costs were computed
by subtracting the estimated base case costs from estimated costs under the two regulatory
alternatives. EPA then scaled up the estimated incremental costs for the CMU to costs that would
be incurred by facilities such as the five ISR facilities expected to be operating in 2014, the
effective date of the proposed rule, based on the ratio of the wellfield acreage at each facility to
the wellfield acreage of the CMU. EPA illustrated the range of costs that may result from the
proposed rule using average, low, and high costs of monitoring. This approach makes the
conservative high-cost assumption that all wellfields at each facility would be in some stage of
pre-operations, operations, restoration, stability, or long-term stability monitoring (and thus
affected by the proposed rule) in 2015.
Estimated national total annualized costs based on average monitoring costs are shown in
Table 3-9, above, and used in this analysis. National costs based on low and high monitoring
costs are shown in Appendix D. Depending on the assumptions used to compute the national
costs, EPA's cost estimates varied widely, ranging from $11.6 million to more than $17.9
million. EPA examined the potential costs of the provisions of the proposed rule (30-year
stability monitoring with the potential to reduce the duration if geochemical modeling
demonstrated that wellfield conditions would remain stable); EPA also examined the potential
costs of one regulatory alternative that was considered and rejected: 30-year stability monitoring
with no potential to reduce the monitoring duration.15 EPA chose to propose 30-year long-term
15 EPA also considered another regulatory alternative: a narrative standard with no fixed monitoring period. Because
the compliance requirements under this alternative would be determined by the licensing body and thus
extremely site and case specific, EPA did not estimate costs or impacts for this alternative.
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stability monitoring with geochemical modeling because this standard has the advantage of being
less costly than the 30-year monitoring alternative, and it demonstrates that conditions will
remain stable or that conditions down-gradient will trap any mobilized constituents, thus
ensuring that groundwater quality is protected. The regulatory alternative of 30-year stability
monitoring with no provision to reduce the duration was rejected because it is generally expected
to be more costly and less protective than the proposed alternative; even monitoring for 30 years
does not guarantee that wellfield conditions will not degrade in the future. The remainder of the
economic impact analysis thus focuses on the impacts of EPA's proposed rule. Analytical results
for the 30-year stability monitoring with no provision for shortening are found in Appendix D. In
addition, Appendix D provides results of a simulation reflecting the possibility that geochemical
monitoring will reveal geochemical conditions in and around the wellfield that would not
guarantee long-term stabilitya "worst case" cost scenario. If that occurred, we expect
regulators to require 30 years of long-term stability monitoring. EPA analyzed the costs and
economic impacts that would occur if all ISR facilities had this experience, although that is
unlikely to occur in actuality. As noted in Section 3 above, this scenario would only be realized
if pre-operational monitoring and geochemical modeling indicated the site was safe to develop,
but post-operational sampling and modeling gave a different result. If pre-operational sampling
and modeling indicated that conditions are not sufficiently reducing to ensure long-term stability,
EPA expects that either the owner operator would choose not to develop, or the licensing
authority would not issue a license. Thus, this worst case is unlikely to occur.
Based on the proposed 30-year long-term stability monitoring with geochemical
modeling using average monitoring costs and assuming that all wellfields are affected, EPA
estimated that national total annual costs of complying with the proposed rule would be
approximately $13.5 million (see Appendix D for the range of national costs estimated for the
geochemical modeling alternative). Compared with the U.S. economy as a whole, these total
annual costs are not extremely large. However, the uranium industry is small, with relatively few
firms. Compared with the industry sales (estimated to be $3.0 billion in 2015 based on a uranium
price of $57 per pound), these estimated total annualized costs comprise about 0.4% of estimated
2015 sales. EPA thus conducted a more in-depth assessment of potential impacts on the market
for uranium and on firms in the industry.
5.2 Market Impact Assessment
To illustrate likely impacts of the proposed rule on the market for uranium, EPA
developed a simplified model of the U.S. market for uranium, using projected quantities of
uranium purchased by COOs in 2015, the effective date of the proposed rule. The U.S. Energy
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Information Administration projects that uranium purchases by U.S. COOs will increase between
2010 and 2040 at a rate of 0.2% per year. Using this rate of growth, EPA estimates that in 2015,
COO purchases will have grown from 57.4 million pounds (2013) to 57.6 million pounds. Over
the period 2000 to 2013, the share of COO purchases supplied by U.S.-origin uranium averaged
16.4% (EIA, 2014b). Assuming that the share of that quantity coming from domestic-origin
uranium in 2015 reflects this historical pattern, EPA estimated that in 2015, COOs will purchase
9.45 million pounds of domestic-origin uranium. Using the projected market price and quantity,
EPA applied the costs of complying with the proposed rule and simulated market responses,
including changes in market price and quantity, and changes in the share of the market
represented by domestic supply and imports. Table 5-1 shows projected 2015 conditions in the
U.S. uranium market, which estimate quantities and prices without the proposed rule, and form
the basis for the market impact simulations.
Table 5-1. Projected U.S. Uranium Market Conditions, 2015
Market Conditions
Supply (million pounds) 57.630
U.S. Origin Uranium 9.451
Foreign Origin Uranium 48.179
Price $57.00
5.2.1 Market Simulation Model
EPA used a partial equilibrium model of the U.S. market for uranium to analyze the
impacts of the proposed rule. Market supply is defined as the sum of domestic-origin uranium
purchased and foreign-origin uranium. Domestic demand for uranium is a function of the
demand for electricity and is represented by projected purchases of U.S. COOs. Figure 5-1
illustrates a market in which some suppliers of the product are affected by the proposed rule and
others (such as foreign suppliers) are not. Promulgation of the proposed rule would increase the
costs of supplying uranium for ISR facilities, thus shifting their supply curve upward, and the
market supply curve upward by a lesser amount. As a result, the with-regulation equilibrium
price is slightly higher, and the with-regulation equilibrium market quantity slightly lower. The
unit cost of complying with the rule (the vertical shift in the supply curve for affected facilities)
is greater than the increase in the market price. Because unaffected facilities respond to the
increased market price by increasing the quantity of uranium they supply the market, affected
facilities are unable to pass along much of their increased costs to their customers, and the
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SM/
+ p
Affected Facilities
Unaffected Facilities
Market
a) Without-Regulation Equilibrium
S'a / Sa/
P'
P
Su ,
q'a
Affected Facilities
qu q'u
Unaffected Facilities
Q'Q
Market
b) With Regulation Equilibrium
Figure 5-1. Market Equilibrium Without and With Regulations
profitability of their operations declines. Thus, the quantity of uranium supplied by U.S. ISR
facilities declines, while the quantity of uranium supplied by unaffected suppliers increases. The
partial equilibrium model used by EPA quantifies estimated market impacts, as described below.
5.2.2 Characteristics of Market Demand for Uranium
Uranium is an input into the production of electricity. Thus, the demand for uranium is
derived from the demand for electricity. The responsiveness of the demand for uranium to
changes in the price of uranium is measured by the elasticity of demand for uranium (computed
as the percentage change in the quantity of uranium demanded divided by the percentage change
in its price). Elasticity values are typically negative, because increases in price typically cause
demanders to want to purchase less of a commodity, if all the other influences on uranium
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demand are held constant. Elasticity values greater than one in absolute value are termed elastic
and indicate demand that is responsive to changes in price. Elasticity values below one in
absolute value are termed inelastic. The closer the value is to zero, the less responsive demand is
to changes in price. EPA's assessment indicates that the demand for uranium is very inelastic.
Economists compute the elasticity of demand for an input as a function of
the elasticity of demand for the final product,
the elasticity of substitution between the input and other inputs,
the elasticity of supply of other inputs, and
the cost share of the input as a share of the cost of the final product, in this case
electricity.
The elasticity of demand for electricity is low, approximately -0.3. The elasticity of
substitution between fuels in production of electricity is also low. The cost of uranium typically
represents between 0.2% and 0.4% of the cost of electricity. Using these values, we estimated the
elasticity of demand for uranium to be about -0.07%. This very low elasticity value indicates
that changes in the price of uranium do not result in great changes in the quantity of uranium
purchased. Another way of looking at this is to say that the demand for uranium responds less to
changes in its price than to other factors affecting demand, such as the share of electricity
produced using nuclear power, the price of alternative energy sources for electricity generation,
and operating status of U.S. nuclear power plants, for example.
5.2.3 Characteristics of Market Supply
The responsiveness of supply to changes in price is similarly measured by an elasticity of
supply, computed as the percentage change in quantity supplied divided by a percentage change
in price. When price increases, uranium firms will respond by increasing uranium production,
because at higher prices, more uranium sources will be profitable to operate. Currently, several
ISR facilities are not operating because the market price has been too low to make operation
profitable. Further, several ISR facilities are licensed and permitted but have not been
constructed. If price rises as projected, some of these sources may be brought online. EPA uses a
supply elasticity of two to measure the price-responsiveness of both domestic supply and import
supply. Historically, because of the presence of large stockpiles of uranium, supply has been
quite responsive to price. However, there is evidence that this is changing, because stockpiles are
being drawn down. Thus, in the future, uranium supplied will generally be from recent
production, which is expected to be less responsive to price changes than are supplies drawn
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from inventories or stockpiles. A supply elasticity of two is consistent with values from the
literature (University of Chicago, 2004; Ux Weekly, 2004).
5.2.4 Impacts of the Proposed Rule
Based on average monitoring costs and assuming 100% of each facility's wellfields are
affected simultaneously, implementation of the proposed rule would increase the cost of
producing uranium at ISR facilities by $1.50 per pound of uranium. Neither the cost of
production using conventional technologies nor the cost of uranium from foreign sources would
be affected. Incremental costs of complying with the proposed rule are estimated to be
approximately 2.6% of baseline market price.
The increased costs incurred by ISR facilities would increase the cost of domestic
production overall. Given the characteristics of demand and supply described above, economic
theory would predict that the market price of uranium would increase, and the quantity of
uranium purchased would fall somewhat. Because imports are a large share of total supply and
their costs would not be affected by the rule, domestic suppliers of uranium would have a limited
ability to pass the costs of compliance to their customers through price increases. EPA thus
estimates that the market price of uranium would increase by only a fraction of the rule's cost per
pound, the share of uranium purchased from domestic sources would decline, and the share of
foreign-origin uranium imports would increase, if all market conditions other than the proposed
rule are held constant.
5.3 Summary of Economic Impact Results
Table 5-2 shows EPA's market impact analysis results. These results should be
interpreted as an illustration of the relative impacts on the U.S. uranium market as a whole and
on domestic suppliers, demanders, and foreign trade, rather than a specific prediction of market
outcomes.
Using a 2015 projected baseline, initial market quantity is approximately 57.6 million
pounds of UsOg, of which an estimated 9.45 million pounds are of domestic origin and 48.2
million pounds are imported. Baseline price is assumed to be $57 per pound. After the market
adjusts to costs of compliance with the proposed rule in effect, increasing the costs of ISR
production by $1.50 per pound, the overall quantity of uranium demanded by U.S. COOs is
projected to decline by about 15.9 thousand pounds (0.03%), and the price of uranium is
estimated to increase by approximately $0.24 (0.4%). The quantity of domestic-origin uranium
purchased is projected to decline to 9.03 million pounds, a decline of approximately 4.4%, while
COO purchases of foreign-origin uranium are estimated to increase by 0.8%.
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Table 5-2. Market Impacts of Proposed Rule based on Average Costs, 2014
Supply (million pounds)
U.S. origin
Foreign origin
Price ($/pound)
Change in price
Percentage changes
Market quantity
U.S. origin
Foreign origin
Price
Incremental cost per pound of
uranium
30 Years, Geochemical Modeling to
Baseline Shorten
57,630 57,614
9,451 9,032
48,179 48,582
$57.00 $57.24
$0.24 $0.27
-0.03%
-4.4%
0.8%
0.4%
$1.50
30 Years
57,612
8,982
48,631
$57.27
-0.03%
-5.0%
0.9%
0.5%
$1.68
5.4 Employment Impacts of the Proposed Rule
According to the U.S. Census Bureau's Statistics of U.S. Business (Census, 2013), in
2011 the uranium and vanadium mining industry had 670 employees. Assuming that
employment in the uranium and vanadium industry increases at the same rate as production,
employment in 2015 is projected to be 682.16
Assessing the impact of the proposed rule on employment requires consideration of
factors that tend to decrease employment and factors that tend to increase it. Assuming
production employment in the U.S. uranium industry declines by approximately the same
percentage as output is estimated to decline, EPA estimates that production employment in the
U.S. uranium industry would fall by approximately 30 full-time equivalent employees. However,
EPA's assessment is that this computation overestimates the decline in employment. First,
although ISR is the dominant form of uranium production in the United States, it is less labor
intensive than conventional mines and mills. Not all the industry's employees work at ISR
facilities, so the actual reduction in ISR facility employment would be smaller than estimated.
Further, because of the labor needed to implement the provisions of the proposed rule, EPA
expects a countervailing increase in employment in the industry. To comply with the proposed
16 Note that the companies owning operating ISR facilities have more than 1,400 employees; however, not all of
these employees work in the United States.
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rule, ISR operations may increase their environmental compliance staff to conduct the additional
monitoring. To the extent that facilities install more monitoring wells than they would have at
baseline, well-drilling employment may also increase. In addition, outside the uranium and
vanadium industry, laboratories that analyze groundwater samples may also increase their
employment somewhat, in response to an increased demand for analysis. Thus, it is difficult to
estimate either the direction or the magnitude of overall employment impacts that would result
from the proposed rule.
5.5 Impacts on Small Entities
Under the RFA, as amended by SBREFA, EPA is required to evaluate the impacts on
small entities affected by its rulemakings. Small entities include small businesses, small
governments, and small nonprofits. Small governments and small nonprofits are not expected to
be affected by the proposed rule; however, two of the firms owning currently operating ISR
facilities, and five additional firms owning planned or standby facilities are small businesses,
based on the SBA's criterion for NAICS 212291: 500 or fewer employees. It is important to note
that the size determination is made at the owner-company level. Uranium companies frequently
have complicated ownership structures, with several layers of ownership. To accurately assess
the vulnerability of the firms owning ISR operations, it is the ultimate parent company's size that
should be considered. If a small company is actually a subsidiary of a larger company, the impact
on the larger company is examined. However, where a larger company is a shareholder in a small
company but the small company is nevertheless an independent entity, EPA evaluated the
impacts on the small company.
EPA assessed the potential for adverse impacts on small businesses by estimating the
costs that would be incurred by the firms that own existing facilities, then comparing those
estimated costs to the firms' revenues. EPA's guidance on complying with the RFA and
SBREFA (2006) establishes criteria for significant impacts: if the proposed rule's costs are less
than 1% of sales, impacts are deemed insignificant. If costs exceed 3% of sales, significant
impacts are likely. Between 1% and 3% of sales, impacts may or may not be significant. EPA
adopted these criteria in determining whether the proposed rule's impacts on small businesses
are significant.
In Table 5-3, EPA compares the estimated costs for firms owning existing ISR facilities
to their sales. Of the four firms owning existing ISR facilities, three are small according to the
SBA's definition for NAICS 212291, because they have fewer than 500 employees.
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Table 5-3. Estimated Impacts of the Proposed Rule on Small Entities
Parent Company
(ISR Facilities)
Small Annual Sales
Business (millions USD)
Estimated Cost to Sales Ratio
Low
Average
High
30 Years with Geochemical Modeling
to Shorten
Cameco Corporation
(Crow Butte, Smith Ranch-Highland-
Reynolds)
Mestena Uranium3
(Alta Mesa)
Uranium One, Inc.
(Willow Creek)
Uranium Energy Corp.3
(Hobson-La Palangana)
Ur-Energy (Lost Creek)
30 Years, No Option to Shorten
Cameco Corporation
(Crow Butte, Smith Ranch-Highland-
Reynolds)
Mestena Uranium3
(Alta Mesa)
Uranium One, Inc.
(Willow Creek)
Uranium Energy Corp.3
(Hobson-La Palangana)
Ur-Energy (Lost Creek)
No
Yes
No
Yes
Yes
No
Yes
No
Yes
Yes
$2,400.0
$28.5
$530.4
$28.5
$57.0
$2,400.0
$28.5
$530.4
$28.5
$57.0
0.4%
1.4%
0.1%
0.9%
0.6%
0.5%
1.6%
0.1%
1.0%
0.6%
0.5%
1.7%
0.1%
1.1%
0.6%
0.5%
1.9%
0.1%
1.2%
0.7%
0.6%
1.9%
0.1%
1.2%
0.7%
0.6%
2.2%
0.1%
1.4%
0.9%
3 To assess impacts on the small firms companies based on typical operations, EPA estimated sales revenues based
on the facility's estimated production and market price. For the two large firms, 2013 reported sales were used.
small firm, Mestena Uranium, no data on sales are available. EPA estimated Mestena's 2015
sales revenues by first estimating their production, then multiplying estimated production times
the projected 2015 price of uranium. For Mestena's Alta Mesa ISR operation, EPA estimated
2015 production to be 500,000 pounds. At $57 per pound, which is the projected price of UsOg
in 2015, Mestena's estimated revenue from uranium sales would be $28.5 million. Another small
firm, Uranium Energy Corporation (UEC), reported that it had sold 220,000 pounds of uranium
in 2013 for $9.0 million. Based on projections that the market for uranium will have recovered
somewhat by 2015, EPA estimates that UEC also will sell 500,000 pounds of UsOg in 2015,
with estimated revenues of $28.5 million. The third small business, Ur-Energy, stated in its 2013
Annual Report that it planned to sell 1,000,000 pounds of UsOg from its Lost Creek operation in
2014. EPA thus assumed that 2015 production at Lost Creek would again be 1,000,000 pounds
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and that Ur-Energy's revenues for the year would be $57 million. For the two large firms,
Cameco and Uranium One, EPA used 2013 reported sales as the estimate for 2015 sales.
EPA's analysis estimates that average estimated costs of complying with the proposed
rule represent between 0.6% and 1.9% of estimated revenues for the three small businesses, and
between 0.1% and 0.6% of revenues for the two businesses that are not small. Even using the
high estimated costs and making the unrealistic assumption that 100% of facilities' acreage
would be involved in operations regulated under the proposed rule at a given time, the maximum
cost-to-sales ratio is 1.9%. For none of the firms analyzed does EPA's analysis indicate that costs
of the proposed rule would exceed 2% of company sales revenues. EPA has chosen to analyze
the possible impacts on companies owning ISR facilities using information about the companies
that own existing ISR operations because they are believed to be representative of companies
that may own ISR facilities in the future. EPA examined financial information for some firms
that own planned facilities. However, it is unclear when and indeed whether these ISR facilities
may begin producing uranium. Without this information about planned production, EPA was
unable to include them in the analysis. Thus, the results in Table 5-3 include only firms that own
existing ISR facilities.
Using these companies as representative of companies that may own ISR facilities
affected by the proposed rule and estimating revenue for the small firms based on estimated
production in 2015, EPA found that their costs would be between 0.6% and 1.9% of firm
revenue, based on average compliance costs, and at most 2.2% based on high-cost estimates.
Further, EPA estimates that fewer than 10 small businesses would be affected by the proposed
rule at any time in the future. Thus, EPA thus does not expect the costs of complying with the
proposed rule to result in significant impacts to a substantial number of small firms.17
5.6 Uncertainties
For a given ISR operation, the costs of complying with the proposed rule are a function
of the characteristics of the wellfields at that operation. Unfortunately, EPA does not have
detailed descriptions of the mine units at existing ISR operations and thus cannot directly
estimate the costs that would be incurred for individual wellfields. Instead, EPA estimated the
costs of complying with the proposed rule for a CMU and scaled the costs up, proportional to
17 Cost-to-sales ratios for firms owning ISR operations under different regulatory alternatives are shown in Table D-
3. Even for the highest cost assumptions and the most costly regulatory alternative, costs represent at most 2.7%
of estimated firm sales. These estimates support EPA's findings that there would not be a significant economic
impact to a substantial number of small entities.
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total acreage, to estimate the costs for each ISR facility. This approach implies that costs are a
function of wellfield size and does not take into account the other facility-specific factors that
would affect costs. For example, in the case of a site composed of more than one distinct ore
zone within its footprint, costs would be underestimated because more monitoring and sampling
would be conducted than assumed in the scaling calculations reported here. Unfortunately, in the
absence of wellfield-specific data, EPA is unable to assess whether costs for a particular ISR
facility are overestimated or underestimated.
EPA estimated the costs of undertaking additional monitoring at the pre-operational,
operational, restoration, stability, and long-term stability monitoring stages. Incremental costs
were computed by subtracting estimated costs of current compliance practices from the estimated
costs of compliance under the proposed rule. EPA recognizes that many of the provisions of the
proposed rule are embodied in existing permits and licenses. Therefore, the incremental costs of
the proposed rule are somewhat overstated. However, EPA is unable to determine the exact
magnitude of this effect.
EPA has analyzed the potential economic impacts of the proposed rule and possible
impacts on both small and large owner companies using information about the projected 2015
conditions in the market for uranium and companies owning existing ISR facilities. The
proposed rule will take effect in 2015 and affect ISR facilities that operate from that time, going
forward. Conditions in the uranium market are volatile; the price of uranium and the market
share of U.S. producers have historically been variable. The market price of uranium is projected
to increase to about $57 per pound of UsOg equivalent, from a 2013 price of about $52 per
pound. If that occurs, several of the facilities that are currently idle or that are in the process of
being licensed may begin production. Revenues for firms owning ISR uranium facilities would
certainly increase, if both production and price rises. However, EPA is unable to estimate how
those changes would affect estimated market impacts and impacts on small entities and has made
conservative assumptions about the quantities of UsOg that would be produced by these
facilities. Also, although the EIA projects that both purchases of uranium and its price will
increase by 2015, the price of uranium has recently been declining, because of the combined
influences of the Fukushima earthquake and tsunami and the global economic downturn. If the
market for uranium does not recover as projected, 2015 conditions could reflect lower purchases
and prices than are estimated in this study. EPA used publicly available sales revenue data for
two large firms owning ISR facilities. For the small entities, EPA first estimated 2015 production
by estimating 2015 production levels based on their capacity and recently reported production
levels, adjusted to reflect somewhat higher prices and production in 2015. EPA then estimated
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revenues for these firms by multiplying the estimated production times the projected 2015 price
of $57 per pound. These estimates are thus based on EPA's projections of 2015 conditions in the
uranium market; both production and the price of uranium in 2015 are uncertain.
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Section 6
STATUTORY AND EXECUTIVE ORDER REVIEWS
6.1 Synopsis
This section summarizes the statutory and Executive Order (EO) impact analyses relevant
for Proposed Revisions to 40 CFR Part 192, Health and Environmental Protection Standards for
Uranium and Thorium Mill Tailings. For each EO and statutory requirement, we describe both
the requirements and the way in which our analysis addresses these requirements.
EPA has concluded that ISR uranium facilities, if not adequately monitored during and
after operations, have the potential to pollute adjacent groundwater aquifers if geochemical
conditions in the wellfield change after restoration so that uranium is once again mobilized. Such
pollution would potentially impose costs on people who are neither buyers nor sellers of uranium
(thus, external to the market) who may be exposed to pollutants in down-gradient aquifers.
Externalities such as pollution are one type of market failure, which requires regulatory
intervention to ensure that social benefits of uranium production exceed social costs of its
production.
6.2 Executive Order 12866: Regulatory Planning and Review and Executive Order
13563: Improving Regulation and Regulatory Review
Under EO 12866 (58 FR 51735, October 4, 1993), this action is a "significant regulatory
action." The EO defines "significant regulatory action" as one that is likely to result in a rule that
may "raise novel legal or policy issues arising out of legal mandates, the President's priorities, or
the principles set forth in the Executive Order."
White House Office of Management and Budget Circular A-4, Regulatory Analysis,
requires government agencies to consider market failure "to the extent permitted by law and
where applicable." In market transactions where information is equally available to buyers and
sellers, all costs and benefits are borne by either buyers or sellers and there are enough buyers
and sellers to ensure competition, markets will efficiently allocate resources so that, from
society's point of view, the net benefits of the market transactions are maximized. However, in
situations where production of a commodity such as uranium produces pollution, people who are
external to the market (neither buyers nor sellers in the market) for uranium may be exposed to
uranium and thus bear costs. These external costs or negative externalities are one example of
market failure and are the underlying justification for government regulatory intervention in such
markets. Based on its examination of hydrogeology and geochemistry at ISR sites and its review
of publicly available information about ISR mining operations, EPA believes that ISR operations
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pose a risk of contaminating groundwater and having the contamination remain undetected for
years, if sufficient post-restoration monitoring is not done. Because ISR uranium mining poses
the potential for external costs and is thus affected by market failure, EPA is required by EO
12866 to develop this proposed rule and to examine its economic impacts, costs, and benefits to
ensure that its benefits to society exceed its costs.
Thus, EPA has conducted this economic analysis to examine the costs, benefits, and
estimated impacts of the proposed rule. EPA's study estimates that affected ISR operators would
incur costs to comply with the proposed rule, which would require comprehensive pre-
operational characterization of the site (including characterization of geochemical conditions
down-gradient of the production zone), careful monitoring during the operation, restoration of
groundwater quality, at least 3 years of stability monitoring, and 30 years of long-term stability
monitoring, with the potential to shorten the duration based on modeling and monitoring of
down-gradient geochemical conditions. Using existing ISR operations as models for ISR
operations that would be affected by the rule, projecting that 2015 ISR uranium production will
be 8.95 million pounds, and using average estimated costs of complying with the proposed rule,
EPA estimates that the proposed rule would increase the average cost of uranium production at
ISR facilities by approximately $1.50 per pound of uranium and that annual costs incurred by
individual ISR facilities would vary from $303,000 to $9.5 million, depending on the scale of the
ISR. Nationally, EPA estimates that the incremental total annual cost of the proposed rule would
be approximately $13.5 million. Discounted at 7%, the estimated present value of the stream of
national costs would be approximately $181 million. Discounted at 3%, the estimated present
value of national costs would be approximately $290 million. EPA also examined the costs that
would be incurred under a regulatory option that would require 30 years of long-term stability
monitoring with no option for shortening the duration using geochemical modeling. National
total annualized cost under this alternative is slightly higher, an estimated $15.1 million. The
estimated discounted present value of costs (discounted at 7%) would be approximately $203
million; discounted at 3%, the estimated present value of costs under this alternative would be
approximately $420 million. Please see Appendix D for a sensitivity analysis of estimated costs
and impacts of the proposed rule and the 30-year long-term stabilization monitoring alternative.
EPA conducted a qualitative assessment of the benefits of the proposed rule. The rule
would require thorough characterization of baseline conditions within the ore zone and
surrounding aquifers and would put in place an automatic updating feature so that the
requirements affecting ISR operations are always consistent with requirements of SDWA and
RCRA. Further, EPA's proposed rule would require a longer period of monitoring, 30 years, to
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ensure that conditions in the exempted aquifer had been restored, had achieved steady state, and
were stable. Further, EPA allows facilities to use geochemical modeling to demonstrate that
groundwater conditions will remain stable and thereby reduce the duration of stability
monitoring to less than 30 years. These provisions help ensure that, after the ISR operation's
license is terminated and the site is closed, groundwater conditions do not deteriorate.
Groundwater is a valuable resource, particularly in the western United States where ISR uranium
mining is most common. Although EPA is unable to quantify the value of the groundwater
resources that would be protected by the proposed rule, EPA nevertheless believes that the
groundwater resources are likely to become more valuable over time. Reducing the risk of
contamination of groundwater also protects surface water bodies to which it discharges. If
groundwater near an ISR facility were to become contaminated due to remobilization of uranium
and other constituents, it might be many years before the contamination was discovered,
especially under current practice where stability monitoring typically lasts only a year or two.
One way to illustrate the potential benefits of the proposed rule is to estimate the costs of
corrective action that would be required if contamination occurred. If the proposed rule prevents
the contamination (or causes it to be discovered sooner), it would reduce the corrective action
costs incurred to remediate the contamination. EPA estimated potential contamination and
associated corrective action costs for the CMU under various assumptions. The costs of
remediation far exceed the costs of complying with the proposed rule, both on an annualized
basis and as a present value. Using a hydrological model, EPA estimated that cleaning up the
plume of contamination could require 100 years of pump and treat remediation. In addition, if
contamination were detected after decommissioning of a site, the costs of remediation could be
borne by the taxpayer or by the owner of the property, rather than the uranium company
responsible, if the former owner company were no longer in existence. Because we cannot
anticipate how many ISR operations might experience deteriorating groundwater conditions after
decommissioning or how long it would be before the contamination would be detected, EPA is
unable to estimate what the national cost savings resulting from avoided remediation costs might
be. However, EPA believes they could be substantial.
In addition to cost savings, the proposed rule has the potential to protect human and
ecosystem health. Since a closed ISR facility has no regulatory oversight, this provision would
reduce the risks of unintended exposure of human and ecological receptors to chemical and
radiological constituents. To the extent that such exposures are reduced, associated human health
risks such as cancer may also be reduced.
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6.3 Paperwork Reduction Act
EPA has determined that this action does not impose an information collection burden
under the provisions of the Paperwork Reduction Act, 44 U.S.S. 3501 et seq. Burden is defined
at 5 CFR 1320.3(b).
6.4 Regulatory Flexibility Act
The RFA generally requires an agency to prepare a regulatory flexibility analysis of any
rule subject to notice and comment rulemaking requirements under the Administrative Procedure
Act or any other statute unless the agency certifies that the rule will not have a significant
economic impact on a substantial number of small entities. Small entities include small
businesses, small organizations, and small governmental jurisdictions.
For purposes of assessing the impacts of the proposed rule on small entities, small entity
is defined as (1) a small business whose company has fewer than 500 employees and is primarily
engaged in leaching or beneficiation of uranium, radium, or vanadium ores as defined by NAICS
code 212291; (2) a small governmental jurisdiction that is a government of a city, county, town,
school district, or special district with a population of less than 50,000; and (3) a small
organization that is any not-for-profit enterprise that is independently owned and operated and is
not dominant in its field. Of these three categories, only small businesses are potentially affected
by the proposed rule; no small organizations or small governmental entities have been identified
that would be impacted by the proposed revisions to Part 192.
This proposed rule is estimated to impact approximately 19 ISR uranium recovery
facilities that are currently operating or may operate in the future. The 19 uranium recovery
facilities are owned by 10 firms, of which eight are believed to be small.
To evaluate the significance of the economic impacts of the proposed revisions to Part
192, EPA estimated the costs that would be incurred by existing facilities, based on their
estimated production and EPA's estimated cost per pound of UsOg. According to EPA'sFinal
Guidance for EPA Rule Writers: Regulatory Flexibility Act as Amended by the Small Business
Regulatory Enforcement Fairness Act (EPA, 2006), firms for which estimated costs of
complying with a rulemaking are less than 1% of firm sales are presumed not to incur significant
impacts. Firms for which costs exceed 3% of firm's baseline sales are believed to incur
significant impacts. If costs of compliance are between 1% and 3% of the firm's revenue, it is
not certain whether impacts would be significant.
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To analyze the proposed revisions to Part 192, EPA assessed potential impacts to six
currently operating ISRs, believing that they are good proxies for firms that would own affected
ISR facilities subject to the proposed rule. The operating ISRs are Crow Butte and Smith Ranch-
Highland-Reynolds owned by Cameco Resources, Alta Mesa owned by Mestena Uranium, LLC,
Willow Creek owned by Uranium One, Inc., Hobson-La Palangana owned by Uranium Energy
Corp, and Lost Creek owned by Ur-Energy Corporation. Using the fewer than 500 employees'
criterion, Mestena Uranium, LLC, Ur-Energy Corporation, and Uranium Energy Corporation are
small businesses, while Cameco Resources and Uranium One, Inc. are both large businesses.
In addition to the six operating ISRs, 12 ISRs have are at some stage of planning or
licensing, or are undergoing restoration:
Dewey-Burdock owned by Powertech Uranium Corp.;
Nichols Ranch owned by Uranez Uranium Corp.;
Moore Ranch and Antelope-Jab, owned by Uranium One, Inc.;
Crownpoint, Kingsville Dome, Rosita, Church Rock, and Vasquez all owned by
Uranium Resources;
Ross, owned by Strata Energy/Peninsula Energy Ltd;
Goliad, owned by Uranium Energy Corp; and
Reno Creek, owned by Bayswater E&P.
All of these companies, except Uranium One, Inc., are small businesses.
Of the facilities identified above, 11 are owned by eight small businesses. EPA's
economic impact analysis estimated that for the small firms currently operating ISR facilities,
costs of the proposed rule would be at most 0.7% of estimated 2015 operating revenues for Ur-
Energy, at most 1.2% of estimated 2015 operating revenues for Uranium Energy, and at most
1.9% of estimated 2015 operating revenues for Mestena, if the highest-cost assumptions were
used. Based on EPA's criteria for significance, impacts for these firms are not believed to be
significant. In addition, the number of firms potentially incurring costs to comply with the rule is
not a substantial number. Thus, EPA concludes that the proposed rule would not result in a
significant impact to a substantial number of small entities. (See Section 5.5 above for additional
details.)
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6.5 Unfunded Mandates Reform Act (UMRA)
This rule does not contain a federal mandate that may result in expenditures of $100
million or more for state, local, and tribal governments, in the aggregate, or the private sector in
any 1 year. Using the five existing ISR operations as examples of typical ISR facilities, EPA
estimates that total annual costs of complying with the rule for five such ISR facilities would
range from $11.6 million to $15.2 million, averaging $13.5 million, assuming geochemical
modeling to shorten the duration, and between $12.9 and $17.9, averaging $15.1 for required 30-
year duration of long term stability monitoring. The proposed rule imposes no enforceable duties
on any state, local, or Tribal governments or the private sector. Thus, this rule is not subject to
the requirements of sections 202 or 205 of UMRA.
This rule is also not subject to the requirements of section 203 of UMRA because it
contains no regulatory requirements that might significantly or uniquely affect small
governments because it contains no requirements that apply to such governments nor does it
impose obligations upon them.
6.6 Executive Order 13132: Federalism
This proposed rule does not have federalism implications. It will not have substantial
direct effects on the states, on the relationship between the national government and the states, or
on the distribution of power and responsibilities among the various levels of government, as
specified in EO 13132. None of the facilities subject to this action are owned and operated by
state governments, and, nothing in the proposed rule will supersede state regulations. Thus, EO
13132 does not apply to this proposed rule.
6.7 Executive Order 13175: Consultation and Coordination with Indian Tribal
Governments
This action does not have tribal implications, as specified in EO 13175 (65 FR 67249,
November 9, 2000). The action imposes requirements on owners and operators of ISR facilities
and not tribal governments. Although EO 13175 does not apply to this action, EPA sought
opportunities to provide information to tribes and tribal representatives during the review of 40
CFR Part 192. EPA specifically solicits additional comment on this proposed action from tribal
officials.
6.8 Executive Order 13045: Protection of Children from Environmental Health Risks
and Safety Risks
EPA interprets EO 13045 (62 FR 19885, April 23, 1997) as applying to those regulatory
actions that concern health or safety risks, such that the analysis required under section 5-501 of
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the Order has the potential to influence the regulation. Because this action addresses
environmental standards intended to mitigate health or safety risks, it is subject to EO 13045. We
evaluated several regulatory strategies for ensuring groundwater restoration and stability at ISR
facilities and selected the option providing most assurance that groundwater systems will remain
in a chemically reduced state, thereby limiting contamination of groundwater. The proposed rule
is expected to reduce children's risk of exposure to contaminated groundwater by improving
monitoring to detect and correct contamination.
6.9 Executive Order 13211: Actions Concerning Regulations That Significantly Affect
Energy Supply, Distribution or Use
This action is not a "significant energy action" as defined in EO 13211 (66 FR 28355,
May 22, 2001), because it is not likely to have a significant adverse effect on the supply,
distribution, or use of energy. This proposed rule will not adversely directly affect productivity,
competition, or prices in the energy sector. EPA projects that the proposed rule would reduce the
quantity of uranium used in this country to produce electricity by less than 0.1%. The price of
uranium is projected to increase by only $0.24 (0.4%) per pound, and this is projected to increase
the cost of producing electricity by less than 0.1%.
6.10 National Technology Transfer and Advancement Act
Section 12(d) of the National Technology Transfer and Advancement Act (NTTAA) of
1995 ("NTTAA"), Public Law No. 104-113, 12(d) (15 U.S.C. 272 note) directs EPA to use
voluntary consensus standards in its regulatory activities unless to do so would be inconsistent
with applicable law or otherwise impractical. Voluntary consensus standards are technical
standards (e.g., materials specifications, test methods, sampling procedures, and business
practices) that are developed or adopted by voluntary consensus standards bodies. NTTAA
directs EPA to provide Congress, through OMB, explanations when the Agency decides not to
use available and applicable voluntary consensus standards.
This proposed rulemaking does not involve technical standards of the type indicated in
NTTAA. Therefore, EPA is not considering the use of any voluntary consensus standards.
We request public comment on this aspect of the proposed rulemaking, and specifically,
ask you to identify potentially applicable voluntary consensus standards and to explain why such
standards could be used in this regulation.
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6.11 Executive Order 12898: Federal Actions to Address Environmental Justice in
Minority Populations and Low-Income Populations
EO 12898 (59 FR 7629, Feb. 16, 1994) establishes federal executive policy on
environmental justice. Its main provision directs federal agencies, to the greatest extent
practicable and permitted by law, to make environmental justice part of their mission by
identifying and addressing, as appropriate, disproportionately high and adverse human health or
environmental effects of their programs, policies, and activities on minority populations and low-
income populations in the United States.
EPA has determined that this proposed rule will not have disproportionately high and
adverse human health or environmental effects on minority or low-income populations because it
increases the level of environmental protection for all affected populations without having any
disproportionately high and adverse human health or environmental effects on any population,
including any minority or low-income population. This proposed rule addresses groundwater
restoration, monitoring, and protection of surrounding aquifers and thus decreases the potential
groundwater contamination to which all affected populations are exposed. Thus, the proposed
rule is projected to have positive, not adverse, impacts on human health and the environment.
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Section 7
CONCLUSIONS
EPA is proposing revised groundwater monitoring program for ISR facilities that produce
uranium by injecting and extracting a solution that dissolves the uranium from the porous
minerals in which it is found. ISR uranium production represents an increasing share of uranium
production, and poses special groundwater protection challenges, compared to conventional
uranium production. Currently, facilities are required to monitor groundwater conditions for only
a short time (generally less than 2 years) after restoration. Case studies of post-restoration
monitoring conducted by the U.S. Geological Survey (USGS, 2009) have shown that conditions
may not remain stable within restored wellfields, with concentrations of some constituents
increasing again. Thus, there is a potential for uranium and other constituents to remobilize over
time, with the potential for groundwater contamination. Accordingly, EPA is proposing to add a
new subpart to 40 CFR Part 192, establishing additional monitoring requirements during all
phases of an ISR facility:
Pre-operational monitoring: measuring background groundwater concentrations
Operational monitoring: monitoring, to detect any excursions of contaminated
groundwater to adjacent aquifers, either beside, above, or below the exempted aquifer
Restoration monitoring: monitoring to document the progress of restoration through
groundwater sampling
Post-restoration monitoring, which has two parts:
- Stability monitoring: monitoring, conducted after restoration efforts have ended,
to establish that wellfield groundwater characteristics are stable and meet
restoration goals (at least 3 years)
- Long-term stability monitoring: monitoring and statistical analyses to show that
the concentration of each monitored constituent is not increasing with time and
that the concentration is not statistically different from the restoration goal
Using a model facility approach, EPA estimated the costs that facilities may incur to
comply with the proposed rule; costs were estimated for each phase of ISR operation under two
regulatory options, and a range of costing assumptions. Cost data were compiled for each stage
over the duration of the stage's monitoring activities for the CMU, then scaled up based on
relative total wellfield acreage to estimate the costs that would be incurred by existing facilities.
EPA estimated the acreage of the CMU and scaled estimated CMU costs up to actual facility
costs using the ratio of total wellfield acreage at existing facilities to acreage of the CMU. These
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estimated facility costs were used to assess impacts on the market for uranium and on firms
owning ISR facilities.
The market for uranium is an international market, with suppliers and demanders in many
countries. The United States has historically been the largest user of uranium for electricity
production but has generally produced only a small share of what it consumes, and foreign
suppliers have provided the remaining 80% to 90%. The uranium market has historically been
volatile, exhibiting considerable year-to-year variation in both price and domestic production.
Going forward, the worldwide demand for uranium is projected to grow substantially over the
next 20 years, due largely to increased demand from China and India; prices are also projected to
increase to $64 per pound by 2018. The U.S. EIA projects that uranium purchased by COOs of
nuclear power plants will grow by approximately 0.2% annually. Using this rate of growth, EPA
projected baseline market conditions in the U.S. uranium market in 2015, the effective date of
the proposed rule.
EPA estimated the impact of the proposed rule on the market for uranium and found that,
overall, the market quantity of uranium purchased for use in electric generation would decline by
less than 0.1% and the market price would increase by approximately 0.4%. Domestic ISR
facilities would decrease their production by approximately 4.1%, and imports of uranium would
increase by less than 1%. Because the cost of uranium is a very small share of the cost of
electricity, EPA estimates that the cost of generating electricity would increase by less than
0.1%.
Although the national total annual costs of the proposed rule (approximately $13.5
million, based on average costs) is well below the $100 million threshold that is one of the
criteria used to identify a significant regulatory action, the industry has only a small number of
companies operating a small number of ISR operations. EPA used existing ISR operations and
the companies that own them as models for the types of facilities and companies that would
likely be affected by the proposed rule. EPA thus estimated the ISR facilities would incur annual
costs of compliance between $262,000 and $12.7 million depending on the characteristics of the
ISR facility and the alternative and costing assumptions used; for small firms owning ISR
facilities, EPA's analysis estimates cost-to-sales ratios of 0.6% to 2.2%, depending on the size of
the operation and the costing assumptions used. Because EPA does not estimate costs to exceed
2.2% of small company sales, and because fewer than 10 small companies would be affected,
EPA has determined that the proposed rule would not have a significant impact on a substantial
number of small entities.
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EPA's qualitative benefits assessment presents a discussion of the expected effects of the
proposed rule on human and environmental health. EPA expects that the improved monitoring
program proposed will reduce the risk of contaminating groundwater resources, thus also
reducing potential exposures to radiological and nonradiological contaminants in groundwater
and potentially in surface water to which affected aquifers discharge. Because the major risk of
exposure to radiological constituents is cancer, the proposed rule has the potential to reduce
cancer risks.
If uranium and other constituents remobilize in groundwater over time and if monitoring
ends too soon and sites are prematurely decommissioned, it is possible that groundwater in
surrounding aquifers could be contaminated, and it might be many years before the
contamination is detected. EPA simulated groundwater contamination using its CMU model
facility under varying assumptions and estimated the costs of corrective action to remediate the
groundwater contamination. Based on these simulations, the cost of remediation would far
exceed the costs of complying with the proposed rule, both on an annual and total basis. For the
model facility simulation, this subset of benefits (avoided remediation costs) exceeded the costs
of complying with the proposed rule. See Table 7-1 for this comparison. Further, if
contamination were detected after decommissioning, the costs of remediation could be borne by
the taxpayer or the land owner, not the uranium company owner/operator (if, for example, the
former owner company were no longer in existence or if sufficient time had passed that the
connection between the contamination and the decommissioned mining operation was not
identified). EPA was unable, however, to estimate potential avoided costs of remediation on a
national scale and thus was unable to quantify the rule's net benefits nationwide.
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Table 7-1. Comparison of Costs of Complying with the Proposed Rule and Costs of
Remediating Contaminated Groundwater (Million 2011$)
Sum of Costs Over Time
With-Regulation:
Without-Regulation Compliance and
Plume Size and Groundwater Scenario Additional Restoration Avoided Costs
Flow Direction (A) (B) (A) - (B)
Small plume $35.3 $27.1 $8.2
Large plume, transverse $481.0 $27.1 $453.9
Large plume, along $586.1 $27.1 $559.0
Annualized Costs
Small plume $1.45 million
Large plume, transverse $10.3 million
Large plume, along $10.5 million
Compliance with proposed rule $345,000
plus additional restoration
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Annual. May 1, 2014. http://www.eia.gov/uranium/production/annual/
U.S. Energy Information Administration, 2014c. Uranium Marketing Annual Report. May 12,
2014. http://www.eia.gov/uranium/marketing/
U.S. Environmental Protection Agency (EPA), 2012a. Considerations Related to Post Closure
Monitoring of Uranium In-Situ Leach/In-Situ Recovery (ISL/ISR) Sites: Background
Information Document for the Revision of 40 CFR Part 192. Radiation Protection
Division, Office of Air and Radiation.
-------�
U.S. Environmental Protection Agency (EPA), 2012c. Groundwater Modeling Studies at In Situ
Leaching Facilities and Evaluation of Doses and Risks to Off-Site Receptors from
Contaminated Groundwater.
U.S. Environmental Protection Agency (EPA), 2012d. Importance of Water
Study, http://water.epa.gov/action/importanceofwater/study.cfm.
U.S. Environmental Protection Agency (EPA), 2013. "Considerations Related to Post Closure
Monitoring of Uranium In-Situ Leach/In-Situ Recovery Sites."
U.S. Environmental Protection Agency (EPA), December 2010. Guidelines for Preparing
Economic Analyses.
U.S. Environmental Protection Agency (EPA), March 26, 2012b. Data collected (WA 2-04, Task
B) and provided by EPA.
U.S. Environmental Protection Agency (EPA), November 2006. Final Guidance for EPA
Rulewriters: Regulatory Flexibility Act as amended by the Small Business Regulatory
Enforcement Fairness Act. http://www.epa.gov/sbrefa/documents/Guidance-
RegFlexAct.pdf
U.S. Geological Survey. 2009. Groundwater Restoration at In-Situ Recovery Uranium Mines,
South Texas Coastal Plain. Open File Report 2009-1143. Written by Susan Hall.
http://pubs.usgs.gov/of/2009/1143/
U.S. Nuclear Regulatory Commission, 1997. Final Environmental Impact Statement to Construct
and Operate the Crownpoint Uranium Solution Mining Project, Crownpoint, New
Mexico. NUREG-1508. U.S. Nuclear Regulatory Commission, Washington, DC.
U.S. Nuclear Regulatory Commission, 2009. Generic Environmental Impact Statement for In-
Situ Leach Uranium Milling Facilities. NUREG-1910, Final Report, Chapters 1 through
4. U.S. Nuclear Regulatory Commission, Washington, DC.
U.S. Nuclear Regulatory Commission, 2012b. Uranium
Recovery, http://www.nrc.gov/materials/uranium-recovery.html Accessed July 2012.
U.S. Nuclear Regulatory Commission, 2013. Part 40: Domestic Licensing of Source Material,
available at http://www.nrc.gov/reading-rm/doc-collections/cfr/part040/, and Appendix A
to Part 40: Criteria Relating to the Operation of Uranium Mills and the Disposition of
Tailings or Wastes Produced by the Extraction or Concentration of Source Material From
Ores Processed Primarily for Their Source Material Content, available
at http://www.nrc.gov/reading-rm/doc-collections/cfr/part040/part040-appa.html.
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Uranium Extraction License Applications. Final Report. NUREG-1569. Prepared by J.
Lusher., U.S. Nuclear Regulatory Commission, NRC ADAMS Accession Number:
ML032250177.
R-4
-------�
U.S. Nuclear Regulatory Commission, March, 2012a. Stages of the Nuclear Fuel Cycle.
http://www.nrc.gov/materials/fuel-cycle-fac/stages-fuel-cycle.html. Accessed July 2012.
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http://www.sba.gov/content/small-business-size-standards
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Uranium One-2013 Annual Report, http://www.uraniuml.com/index.php/en/investor/fmancial-
reports-and-filings/annual -reports
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reports/2013/v3 69199_UR-ENERGY%20INC%20FORM%2010-K%20Clean.pdf
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R-5
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World Nuclear Association, 2013. Military Warheads as a Source of Nuclear Fuel. Available at:
http://www.world-nuclear.org/info/Nuclear-Fuel-Cycle/Uranium-Resources/Military-
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R-6
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APPENDIX A:
UNIT COSTS FOR WELLS AND BORINGS
Unit costs were compiled for both wells and geotechnical borings. The number of wells
and borings varied between the groundwater monitoring scenarios. The following is a summary
of the unit costs used in the cost analysis.
A.I Mine Unit Wells
The well types considered in the conceptual mine unit (CMU) models developed for the
groundwater monitoring scenarios evaluated include:
Injection wells
Extraction wells
Perimeter monitoring wells,
Excursion monitoring wells in the overlying and underlying aquifers
Additional well types considered for some scenarios included:
Down-gradient ore zone monitoring wells,
Remediation wells
The total depths of these wells were based on the hydrogeology of the example mine unit
from the Highland site in Wyoming. Table A-l below summarizes the well depths of overlying
and underlying monitoring wells and also the production wells (Michel and Hoffman, 1991). The
average depth for each well zone (i.e., ore zone, overlying aquifer, and underlying aquifer) was
used to calculate the unit costs.
EPA (2012b) previously estimated the cost per foot (ft) for well construction. This was
assumed to include costs for well materials (casing, well screen, caps, etc.), mobilization of drill
rig and support trucks, drilling time, and surface completion (materials and labor). Range of
costs for well construction was from $9 to $32 per foot. Higher costs per foot were typically for
shallower wells. Based on documentation provided by EPA a cost of $30 per foot was assumed
for any well 500-ft or deeper. Since the wells at the Highland site, on which the CMU model was
based, are in the 500-foot depth range, the unit cost of $30 per foot was chosen all well types
considered in the groundwater monitoring and remediation scenarios. Costs of production wells
were also used for other ore zone wells (i.e., ore zone monitoring wells and remediation wells).
A-l
-------�
Table A-l. Depth of Selected Wells and Average Unit Cost
Overlying Wells Underlying Wells
Total Depth Well Cost Total Depth
410.4 $12,312 620.5
519.1 $15,573 658
534 $16,020 669
435 $13,050 681.3
484 $14,520 689.45
426 $12,780 682
510 $15,300 670
550 $16,500 650
424.5 $12,735 651
540 $16,200 676.8
520 $15,600 664.1
545 $16,350 669.6
450 $13,500 660
668
690
Well Cost
$18
$19
$20
$20
$20
$20
$20
$19
$19
$20
$19
$20
$19
$20
$20
,615
,740
,070
,439
,684
,460
,100
,500
,530
,304
,923
,088
,800
,040
,700
Injection/Extraction Wells
Total Depth
635
624
559.3
562
597
602
618
596
589
600.5
600
610.5
602.5
584
596.5
594
600.4
589.9
592
595
600
597.1
602.5
592
597
612
614.6
621.3
618
Well Cost
$19,050
$18,720
$16,779
$16,860
$17,910
$18,060
$18,540
$17,880
$17,670
$18,015
$18,000
$18,315
$18,075
$17,520
$17,895
$17,820
$18,012
$17,697
$17,760
$17,850
$18,000
$17,913
$18,075
$17,760
$17,910
$18,360
$18,438
$18,639
$18,540
(continued)
A-2
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Table A-l. Depth of Selected Wells and Average Unit Cost (continued)
Overlying Wells Underlying Wells Injection/Extraction Wells
Total Depth Well Cost Total Depth Well Cost Total Depth
614
625
604
650
645
600
601
571.5
588
629.6
595
607
586
593
599.3
581.7
537
585.4
592.4
612.8
631.8
602.55
591.6
591
592.5
557
MAX= 550 $16,500 690 $20,700 650
MIN= 410 $12,312 621 $18,615 537
MEDIAN= 510 $15,300 669 $20,070 599.3
AVERAGE= 488 $14,649 660 $19,795 600
Well Cost
$18,420
$18,750
$18,120
$19,500
$19,350
$18,000
$18,030
$17,145
$17,640
$18,888
$17,850
$18,210
$17,580
$17,790
$17,979
$17,451
$16,110
$17,562
$17,772
$18,384
$18,954
$18,077
$17,748
$17,730
$17,775
$16,710
$19,500
$16,110
$17,979
$17,993
A-3
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A.2 Geotechnical Borings
Costing information available from the U.S. DOE (2013) for geotechnical boring drilled
for characterizing the geochemistry for geothermal energy development in the western United
States was used as a guide for estimating corehole costs. However, due to the way the DOE costs
were presented and limited time, the estimated costs for geotechnical borings was also based on
experience and best professional judgment. The costs of a geotechnical boring is related to the
corehole depth, penetration rate expected, drilling method and technology requirements, the
number of samples, type of samples taken and the sample method; and there are also regional
factors that control costs for drilling and construction services (e.g., variation in licensing and
permitting requirements). Boring costs were only assumed applicable for geochemical modeling.
Drilling time was assumed to be one day per corehole with a maximum drilling depth of 650-feet
which is the total average depth assumed for the underlying non-exempt aquifer in the CMU.
Composite sampling of selective zones in each corehole was assumed resulting in 2 samples per
corehole, on average, sent to the laboratory for analysis. Costs for core analysis and logging were
also included. A summary of the boring costs assumptions and the total costs for the boreholes is
provided in Table A-2.
Table A-2. Summary of Well and Borehole Costs Assumed for Modeled Scenarios
Well Types
OZ-PW
OZ-IW
OZ-EW
OZ-MW
OW
uw
Core Hole
Core Analysis
Lab Analysis
Unit Cost -
($/well;
$/core;
$/day)
$17,993
$17,993
$17,993
$17,993
$14,649
$19,795
Well Totals:
$11,316.50
$400.00
$400.00
Core Totals:
CMU Well Totals and Costs
CP
26
166
77
0
5
10
284
0
0
0
0
2011$
$467,805
$2,986,755
$1,385,423
$0
$73,246
$197,950
$5,111,179
$0.00
$0.00
$0.00
$0.00
30-yr
26
166
77
0
10
20
299
0
0
0
0
2011$
$467,805
$2,986,755
$1,385,423
$0
$146,492
$395,900
$5,382,375
$0.00
$0.00
$0.00
$0.00
30-yr
with
Geochem
26
166
77
10
10
20
309
8*650ft
8
8
2011$
$467,805
$2,986,755
$1,385,423
$179,925
$146,492
$395,900
$5,562,300
$90,532.00
$3,200.00
$3,200.00
$96,932.00
CP = current practice
A-4
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A.3 References
Michel, T.G. and G. Hoffman, July 1991. E-Field 50 Sand Mine Unit Hydrology Test, Highland
Uranium Project, Power Resources, Inc.; Report for WDEQ/LQD Permit Number 603,
U. S. Nuclear Regulatory Commission Docket Number 40-8857, SUA-1511; Report by
Power Resources, Inc. and Hydro-Engineering; September 1990, revised July 1991.
U.S. Department of Energy, 2013. Cost and Time Metric Tool (Web Application); National
Renewable Energy Laboratory; Internet
resource: http://en.openei.org/wiki/Exploration Cost and Time Metric
U.S. EPA, March 26, 2012b. Data collected (WA 2-04, Task B) and provided by EPA.
A-5
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APPENDIX B:
SUMMARY OF UNIT COSTS FOR SAMPLING AND ANALYSIS
Unit costs were determined for the collection and analysis of a groundwater sample.
These unit costs were then used for estimating total sampling and analysis costs for each of the
groundwater monitoring scenarios evaluated. Groundwater sampling and analysis costs are
summarized for each scenario in Section 3 of the report.
B.I Analysis Costs
The total laboratory costs are dependent upon the number of parameters that are
analyzed. EPA recognizes that analytical costs are site specific since the list of parameters
required for monitoring are a function of the geochemistry of the aquifer units being sampled, as
well as operational and regulatory requirements. In general, analytes may be required for
analysis based on EPA or state regulation, to identify excursions, to monitor the condition of the
lixiviant, and to characterize and model the pre and post-mining geochemistry (U.S. EPA,
2012a). The groundwater monitoring scenario cost models have assumed full lists of applicable
analytes, and no assumptions were made that would serve to reduce a list of parameters and
analytes (e.g., based on the Highlands site geochemistry and CMU model) that might be sampled
due to an assumed monitoring requirement (i.e., state, EPANRC, etc.).
The lists of parameters and analytes were originally compiled from 4 different sources
including EPA, NRC, TCEQ, and WDEQas seen in Table B-l. A unit cost was developed to
estimate the cost of analyzing the full suite of 56 parameters, as well as for various subsets,
including the EPA specified 33 parameters, the 35 parameters from the NRC's ISL Standard
Review Plan, and the state specified parameters. EPA collected costs to perform the specific
analyses required from 12 actual analytical laboratories (TDSHS, 2007; Pace, 2009; BVNA,
2010; NDHHS, 2010; ELI, 2011; CCAL, 2012; ML, 2013; ELI, 2013; SARA, 2012; ACTI,
2005; EPA, 2012b). The average, low, median, and high analytical costs for each analyte are
shown in Table B-l. Average costs were only used in the analysis of the groundwater monitoring
scenarios; however, the other costs are provided for comparison.
B-l
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Table B-l. Analysis Costs for Analytes Generally Required in ISR Groundwater
Monitoring Programs (2011$)
Species
Requirements by Analyte Group
EPA
NRC
TCEQ
WDEQ
ucu
Geochem
Analysis Cost (sample *)
Average
Low
Median
High
Trace and Minor Elements
Aluminum
Antimony
Arsenic
Barium
Beryllium
Boron
Cadmium
Chromium
Cobalt
Copper
Fluoride
Iron1
Lead
Manganese
Mercury
Molybdenum
Nickel
Selenium
Silver
Thallium
Tin
Uranium
Vanadium
Zinc
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes&
V2O5
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes (Total
and Fe2+)
Yes
Yes
$13.63
$13.63
$13.63
$13.63
$13.63
$13.63
$13.63
$13.63
$11.83
$13.63
$16.50
$13.97
$13.63
$13.97
$17.13
$13.63
$13.63
$13.63
$13.63
$13.63
$11.00
$16.13
$11.33
$13.63
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$12.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$8.00
$14.40
$14.40
$14.40
$14.40
$14.40
$14.40
$14.40
$14.40
$10.00
$14.40
$15.50
$14.40
$14.40
$14.40
$14.40
$14.40
$14.40
$14.40
$14.40
$14.40
$10.00
$16.00
$10.00
$14.40
$19.00
$19.00
$19.00
$19.00
$19.00
$19.00
$19.00
$19.00
$19.00
$19.00
$21.00
$19.00
$19.00
$19.00
$37.00
$19.00
$19.00
$19.00
$19.00
$19.00
$19.00
$25.00
$16.00
$19.00
(continued)
B-2
-------�
Table B-l. Analysis Costs for Analytes Generally Required in ISR Groundwater
Monitoring Programs (2011$) (continued)
Species
Requirements by Analyte Group
EPA
NRC
TCEQ
WDEQ
ucu
Geochem
Analysis Cost (sample *)
Average
Low
Median
High
Common Constituents
Alkalinity
Ammonia
Bicarbonate
Calcium
Carbonate
Chloride
Magnesium
Nitrate
Nitrite
Phosphate6
Potassium
Silica
Sodium
Sulfate
Sulfide
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
(NH4+)
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
$16.33
$23.75
$13.00
$12.17
$13.00
$16.17
$14.00
$20.60
$19.83
$23.33
$14.00
$23.50
$14.00
$16.17
$38.00
$10.00
$15.00
$13.00
$8.00
$13.00
$10.00
$8.00
$12.00
$12.00
$20.00
$8.00
$10.00
$10.00
$10.00
$35.00
$16.00
$22.50
$13.00
$10.00
$13.00
$17.00
$10.00
$20.00
$20.00
$25.00
$10.00
$26.00
$14.00
$17.00
$39.00
$23.00
$35.00
$13.00
$19.00
$13.00
$21.00
$29.00
$30.00
$26.00
$25.00
$29.00
$32.00
$18.00
$21.00
$40.00
Chemical and Physical Indicators
Anion/Cation
Balance
Specific
Conductivity
pH
Redox
Potential
Total
Dissolved
Solids
Temperature
Turbidityf
Dissolved
Oxygen8
Yes
Yes
Yesa
Yesa
Yesb
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
$10.00
$13.67
$11.00
$45.00
$19.33
NA
$15.00
$18.67
$10.00
$10.00
$8.00
$45.00
$12.00
NA
$15.00
$10.00
$10.00
$12.00
$10.00
$45.00
$18.00
NA
$15.00
$11.00
$10.00
$19.00
$17.00
$45.00
$31.00
NA
$15.00
$35.00
(continued)
B-3
-------�
Table B-l. Analysis Costs for Analytes Generally Required in ISR Groundwater
Monitoring Programs (2011$) (continued)
Species
Requirements by Analyte Group
EPA
NRC
TCEQ
WDEQ
ucu
Geochem
Analysis Cost (sample *)
Average
Low
Median
High
Chemical and Physical Indicators (continued)
Dissolved
Organic and
Inorganic
Carbon11
Eh
Yes
Yes
$39.00
NA
$32.00
NA
$35.00
NA
$50.00
NA
Radiological Parameters
Gross Alpha
Gross Beta
Radium-226
Radium-228
Beta +
Gamma
Totals:
Yes
Yes
Yes
Yes
33
Yesc
Yes
Yesd
Yesd
35
Yes
25
Yes
Yes
Yes
Yes
28
4
Yes
Yes
29
$48.33
$45.00
$77.25
$83.00
$75.00
$40.00
$40.00
$75.00
$70.00
$75.00
$50.00
$45.00
$75.50
$79.00
$75.00
$55.00
$50.00
$83.00
$104.0
0
$75.00
a Field and laboratory determination
b Laboratory only
0 Excluding radon, radium, and uranium
d If site initial sampling indicates the presence of Th-232, then Ra-228 should be considered in the baseline sampling
or an alternative may be proposed
e Phosphate costs from Cooperative Chemical Analytical Laboratory, Midwest Laboratories, Energy Laboratories
Inc.
f Turbidity costs from Cooperative Chemical Analytical Laboratory (http://www.ccal.oregonstate.edu/fees.htm')
g Dissolved oxygen costs from Midwest Laboratories, San Antonio River Authority, and Aquatic & Consulting
Testing Inc.
h Dissolved Organic and Inorganic Carbon from Cooperative Chemical Analytical Laboratory, two method
(Combustion-Infrared and Sparge-Infrared) fees were combined for a total cost of analyzing both species
(http://www.ccal.oregonstate.edu/fees.htm')
1 Dissolved and total
> UCLupper control limit/excursion parameters.
B-4
-------�
B.2 Groundwater Sampling Unit Costs
Included in the unit cost for groundwater sampling are the:
laboratory analysis costs,
labor cost of contractor personnel to collect the sample,
expenses for contractor personnel to travel to the site,
contractor fees (assumed 8%), and a
contingency of 10% of all calculated costs.
These costs were calculated for each analyte group (i.e., EPA, NRC, etc.) and are
summarized in Table B-2. The following items are not included or considered in the unit costs:
materials (e.g., bottles, gloves, and reagents)
sample transport to laboratory
lodging
record keeping,
well maintenance during stability monitoring,
sample disposal, as well as
the impact of using on site personnel, rather than contractor personnel.
Table B-2. Unit Cost for Groundwater Sampling with Analysis Costs (2011$)
Species Analyzed
Component
Group Analysis (Average Costs)
Direct Labor (hr1)
Indirect Labor (hr"1)
Travel
Fee (8%)
Contingency (10%)
EPA
$741
$200
$46
$26
$25
$34
NRC
$700
$200
$47
$26
$25
$34
TCEQ
$447
$200
$47
$26
$25
$34
WDEQ
$665
$200
$47
$26
$25
$34
Geochem.
$629
$200
$47
$26
$25
$34
Total $1,073 $1,032 $779 $997 $961
B-5
-------�
These costs, individually and in total, were considered a small portion of the sum of
analysis and labor costs.
B.3 Parameter References
ACTI (Aquatic & Consulting Testing Inc.), 2005. "Biological and Analytical Chemistry
Services." Available at: http://www.aquaticconsulting.com/fee%20schedule.pdf
[Accessed March 23, 2013].
BVNA (Bureau Veritas North America), 2010. "Schedule 66, Scientific Equipment and
Services," Number: GS-07F-6029R, Period: 17 Aug 2010-17 Aug 2015.
CCAL (Cooperative Chemical Analytical Laboratory), 2012. "CCAL Fee Schedule for FY13."
Available at: http://www.ccal.oregonstate.edu/fees.htm [Accessed March 23, 2013].
NDHHS (Nebraska Department of Health and Human Services), 2010. "Analyte/Price List,
Nebraska NDHHS Laboratory 2009-10."
TDSHS (Texas Department of State Health Services), 2007. "2007 TDSHS Fee Schedule-
Austin Lab," CLIA ID #: 45D0660644, Tax ID # 32-0113643.
ELI (Energy Laboratories, Inc.), 2011. "Analytical Services 2011."
ELI (Energy Laboratories Inc.), 2013. "Technical Services and Fee Schedule 2013." Available
at: http://www.energylab.com/asp/Pri cingGuide/docs/ELI_2013_Fee_Schedule_-
_ALL_SECTIONS_v0.pdf [Accessed March 23, 2013].
ML (Midwest Laboratories), 2013. "Schedule of Fees 2013." Available at:
https://www.midwestlabs. com/wp-content/uploads/2013/0 I/Mi dwest-Labs-Schedule-of-
Fees-2013.pdf [Accessed March 23, 2013].
Pace (Pace Analytical Services Inc.), 2009. "Minneapolis, MN Laboratory, 2009 Pricing
Information," Revised 1/1/09.
SARA (San Antonio River Authority), 2012. "Analytical Services Fee Schedule." Available at:
http://www.sara-tx.org/public_services/laboratory_services/docs/Fee-schedule-2012.pdf
[Accessed March 23, 2013].
U.S. Environmental Protection Agency (EPA), 2012a. Considerations Related to Post Closure
Monitoring of Uranium In-Situ Leach/In-Situ Recovery (ISL/ISR) Sites: Background
Information Document for the Revision of 40 CFR Part 192. Radiation Protection
Division, Office of Air and Radiation.
U.S. Environmental Protection Agency (EPA), 2012b. Data collected (WA 2-04, Task B) and
provided by EPA. March 26.
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APPENDIX C:
SIMULATION OF REMOBILIZED URANIUM FROM A RESTORED ISR MINE
This appendix documents modeling simulations of a plume that could develop within an
ore body after ISR mining and restoration have been completed. The scenario represents
conditions that have destabilized the restored wellfield years after restoration of the production
unit had been completed. The destabilization is due to a natural influx of oxidized groundwater
from up-gradient of the mine unit that oxidizes the remaining uranium in the wellfield making it
more mobile, thereby allowing a groundwater contamination plume to develop and allow the
migration of the constituents down-gradient into the rest of the wellfield and potentially into the
aquifer below the production zone. For this situation to develop, the mechanisms that were
responsible for sequestering the uranium initially would have to be destroyed or dramatically
weakened by the uranium recovery process so that the restoration process amounted to only a
temporary re-establishment of chemically reducing conditions in the ore zone. For that situation,
the movement of oxygenated groundwater into the production zone from up-gradient could, over
time, re-oxidize the uranium and allow migration of the contaminants down-gradient.
The simulations illustrate the potential behavior of a remobilized contamination plume
for the example mine site in Wyoming with the model setup generally based on actual conditions
at the Highland site. It should be noted, however, that the model is for illustrative purposes only
and the results do not suggest that the scenarios developed have or will occur at the example site.
Varying groundwater flow directions were considered for the conceptual mine unit
(CMU) based on data from Wellfield-E documentation (Michel and Hoffman, 1991). A general
groundwater flow direction, longitudinal with the linear extent of the ore zone, was assumed that
could have been either induced from nearby pumping centers (e.g., other ISL production units)
or preferential flow toward abandoned, idle, or active underground mine units that were nearby
(see Fig. 3-1). A typical groundwater flow direction perpendicular to the length or face of the ore
zone front was also considered for the remediation scenarios.
Even though a more eastward groundwater flow gradient is characteristic of the 50-sand
unit due to the influence of other nearby pumping or groundwater drainage points, the modeled
simulations of groundwater flow predict plume migration under ambient conditions that exist
without any active pumping or extraction at the mine site. The simulations also predict plume
migration under hypothetical pump and treat remediation scenarios, assuming the remobilized
plume is discovered and actively remediated. The modeling results were used to support the
estimation of remediation costs for a generally small and larger sized plume.
C-l
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C.I Background
The ISR mining process involves the injection of oxidizing agents and other chemicals
(the lixiviants) into the ore zone to mobilize uranium for subsequent extraction. The oxidizing
agents remove iron sulfides and reactive organic material in addition to uranium. Such naturally-
occurring reducing agents were typically responsible for the original uranium sequestration that
formed the ore deposit. The restoration process (following the ISR mining) is intended to return
the aquifer to a chemically reducing environment similar to pre-mine conditions, thereby
immobilizing uranium and other potential contaminants. However, the restoration process can
have a limited potential to restore reducing conditions, particularly over long time periods. If
levels of iron sulfides and organics have been reduced significantly by the mining process,
attempts at restoration may only have a short term effect. The restoration may reduce uranium
concentrations in groundwater, but unless a strongly chemically reducing environment is in
place, concentrations may later increase. If more oxidizing groundwater enters the mine unit
from up-gradient, it can re-oxidize the uranium, thereby increasing concentrations and creating
an inorganic contaminant plume of uranium plus other metals (e.g., thorium) in groundwater.
This plume could migrate out of the mine unit and impact down-gradient areas of the aquifer,
particularly if there is not a strong reducing environment down-gradient, and potentially
impacting beneficial groundwater uses.
Effects of uranium re-mobilization could be mitigated through natural attenuation
processes that reduce down-gradient concentrations. The key attenuation mechanisms are
dispersion along the flow path, sorption of uranium on the aquifer materials, and chemical
reduction. The model simulations include mechanisms of dispersion and linear equilibrium
sorption. Chemical reduction (and oxidation) processes require more information and more
complex modeling than attempted for this evaluation.
C.2 Approach
The assessment uses the groundwater flow model MODFLOW (McDonald and
Harbaugh, 1983) and the groundwater transport model MT3DMS (Zheng and Wang, 1999).
These codes are well accepted in the technical community and widely used for groundwater and
contamination fate and transport modeling. Table C-l provides input parameter values developed
to represent the case study site.
C-2
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Table C-l. Input Parameter Values
Parameter
Hydraulic
Conductivity (K)
Hydraulic gradient
Porosity
Aquifer top elevation
Aquifer bottom
elevation
Head at up-gradient
plume boundary
(ambient flow)
Pore velocity
Dispersivity
Bulk density
Ore body length
Value Unit
2.20 m/day
0.0135
0.20
1351 m
1341 m
1570 m
0.15 m/day
30 m2/day
2.00E+06 gm/m3
1600 m
Source
Michel, Thomas G. and George Hoffman (July 1991).
Michel, Thomas G. and George Hoffman (July 1991).
Typical
Michel, Thomas G. and George Hoffman (July 1991);
Plate 2-1 and 2-1.
Michel, Thomas G. and George Hoffman (July 1991);
Plate 2-1 and 2-1.
Michel, Thomas G. and George Hoffman (July 1991);
Plate 4-2, head near up-gradient ore body location
Calculated (K*gradient/porosity)
Estimated as 0. l*plume scale*pore velocity; plume
scale=2000 m (http://www.iowadnr.gov/portals/
idnr/uploads/ust/monohydrocarbonsguide.pdf)
McWorter, David B. and Daniel K. Sunada, 2010
Based on length of northern ore body and configuration
Ore body width
Initial dissolved
concentration
Target dissolved
concentration
Kd minimum
Kd maximum
Pumping rate (per
well)
400
0.10
0.03
m
mg/L=gm/m3
mg/L=gm/m3
l.OOE-06 m3/gm
(0.03 mL/gm)
l.OOE-05 m3/gm
(2200 mL/gm)
164 m3/day
ofWellfieldE
Based on width of northern ore body and configuration
ofWellfieldE
Communication with EPA and data from Wellfield E
annual reports
Communication with EPA
Pearson et al., 1983 and communication with EPA
Pearson et al., 1983 and communication with EPA
Michel, Thomas G. and George Hoffman (July 1991).
The model domain is rectangular and extends 10,000 m from the ore body in all
directions. A line of constant head boundary cells along the up-gradient and down-gradient edges
of the domain. The specified head values were set so that the ambient/background groundwater
flow gradient matched the gradient at the example mine site. A rectangular plume with a similar
geometry to the ore body (see Figures 3-1 and 3-2) was delineated in the middle of the model
domain with a concentration of 0.1 mg/L. The simulations predict the time for the plume
concentrations to decrease below 0.03 mg/L and any associated plume migration.
C-2
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The sorption partition coefficient (Kd) controls the degree of linear sorption represented
by the model. The Kd variable is site specific and limited examples were found for actual ISR
sites that were measured either as part of baseline or after restoration was completed. The value
selected for modeling purposes was a referenced (FJ. Pearson Jr., CJ. Noronha, and R.W.
Andrews, 1983) Kd measured at a roll front sandstone site and was used as a representative
general condition. This value was varied for the simulations between le-6 and le-5 m3/gm to
examine the sensitivity of the projections to the assigned value for this uncertain parameter.
The simulations predict plume migration under two flow-direction scenarios:
1) groundwater flow oriented parallel to the length of the original ore body; 2) groundwater flow
oriented transverse to the length of the original ore body. The expected direction of groundwater
flow would be perpendicular to the length of the ore body; however, a scenario was also
considered with groundwater flow along the length of the ore body that would simulate geologic
conditions where the modern flow regime was different than when the deposit was formed, and
for cases where anthropogenic activities had altered the natural groundwater flow in the aquifer.
The simulations predict plume migration under two flow field scenarios: 1) flow under ambient
conditions with no groundwater pumping; 2) flow under hypothetical pump and treat scenarios
that include groundwater injection as well as extraction wells. The pump and treat scenarios were
selected to reduce plume concentrations below the target concentration (0.03 mg/L) in 100 years
or less. More aggressive pump and treat designs could result in shorter remediation times. The
selected scenarios were considered reasonable representations under the idealized model
conditions. The scenario involving ambient flow rates without the pump and treat remediation is
an assessment of the potential for natural attenuation mechanisms to contain the contamination
plume.
With flow parallel to the length of the deposit, the pump and treat scenario includes a line
of extraction wells through the center of the plume. The scenario also includes lines of extraction
wells along the upper and lower plume boundaries (see Figure C-l). This configuration induces
flow between the injection and extraction wells, removing contaminated groundwater and
injecting treated water. In all scenarios, the total injection rate matches the extraction rate. At
points of injection is the flow rate is 82 ft/day, and at extraction points the flow rate is
164 ft3/day. As illustrated in Figure C-l, constituent concentrations are continually lowered over
time while the plume is contained within the treatment area.
C-4
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Figure C-l. Example Simulations with Flow Oriented Parallel to the Strike of the Ore
Body; Kd=6e-6 m3/gm; Pump and Treat
0 years
oooooooooooooo
20 years
40 years
*
Legend
O.lmg/L
0.03 mg/L
Groundwater
elevation contour
Injection well
Extraction well
C-5
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With flow perpendicular to the length (or length) of the deposit, the pump and treat
scenario includes a line of injection wells along the up-gradient plume edge. The scenario also
includes a line of extraction wells along the down-gradient plume edge (see Figure C-2). This
configuration induces flow between the injection and extraction wells, removing contaminated
groundwater and injecting treated water. In all scenarios, the total injection rate matches the
extraction rate. The flow at injection wells is at 164 ft3/day, and flow from extraction wells is at
164 ft3/day. As illustrated in Figure C-2, constituent concentrations are continually lowered over
time while the plume is contained within the treatment area. Water is injected and flows down-
gradient to the extraction wells, thereby flushing contamination to the extraction wells and
reducing contaminant concentrations.
C.3 Simulation Results
Table C-2 summarizes the results of the modeling assessment for each scenario. The
results are very sensitive to the Kd parameter that controls the degree of linear sorption
represented by the model. Table C-2 includes the calculated retardation factor, which indicates
how much slower the contaminant plume moves due to sorption when compared to groundwater
flow.
The results illustrate that significant down-gradient migration of a remobilized plume is
possible before natural attenuation mechanisms reduce concentrations below acceptable levels.
For this situation, remediation intervention approaches are necessary to prevent large scale
migration of the contamination. In addition, plume migration times are relatively slow under
ambient flow conditions (the scenarios with no P&T component), further indicating that active
remediation efforts would be needed to address the contamination potential. Consistently, pump
and treat remediation times are relatively slow, requiring decades or longer to reduce
concentrations to acceptable levels. In any particular field situation, the time frames for oxidizing
waters to re-enter a well field that was not permanently returned to a strongly reducing chemical
regime by the restoration process will vary based on site-specific conditions. Reliable prediction
of when, and if, re-mobilization may take place is not possible without a thorough geochemical
characterization of site conditions after the restoration process has been completed and continued
monitoring of those conditions.
For developing the geochemical model, it is important to characterize conditions down-
gradient from the ore body. As mentioned earlier, chemically reducing conditions in the
sandstone host rock were responsible for originally sequestering the uranium and the presence of
these conditions in the portion of the aquifer down-gradient of the ore zone would act as a barrier
C-6
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Figure C-2. Example Simulations with Flow Oriented Perpendicular to the Strike of the
Ore Body; Kd=6e-6; Pump and Treat
0 years
20 years
40 years
Legend
O.lmg/L
0.03 mg/L
Groundwater
elevation contour
Injection well
Extraction well
C-7
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Table C-2. Simulation Results
Number of
Flow
Direction
Parallel to
length of
deposit
Transverse
to length
of deposit
Flow
Field
Ambient
Flow
Pump and
Treat
Ambient
Flow
Pump and
Treat
Kd
(m3/gm)
l.OE-06
6.0E-06
l.OE-05
l.OE-06
6.0E-06
l.OE-05
l.OE-06
6.0E-06
l.OE-05
l.OE-06
6.0E-06
l.OE-05
Retardatio
n Factor
11
61
100
11
61
100
11
61
100
11
61
100
Injection
Wells
0
0
0
20
48
60
0
0
0
20
36
45
Pumping
Wells
0
0
0
9
23
29
0
0
0
20
36
45
Time to Reach
C<0.03 mg/
L(yr)
>2200a
>5000b
>5000b
50
75
100
725
4750
>5000b
20
60
80
Down
gradient
Travel
Distance (m)
>10000a
>4800b
>2800b
0
0
0
3300
3800
>2800
0
0
0
a Plume exits simulation domain before decreasing below 0.03.
b Simulation ends before plume decreases below 0.03.
to contaminant migration from the ore zone if re-mobilization occurs. In many cases, unmined
down-gradient materials will maintain reducing conditions with sufficient capacity to immobilize
a plume. The simulations in this appendix assume oxidizing conditions remain as the plume
migrates down gradient.
The consequences of re-mobilization illustrated in the simulations supports the use of a
reasonably long post-restoration long-term stability monitoring period to provide an opportunity
to detect any re-mobilization and address it before the contamination becomes widespread
through the wellfield. The 30 yr post-restoration stability monitoring period in the proposed rule
is aimed at providing at least an opportunity to detect re-mobilization if it begins to occur. The
benefit of developing a geochemical model of the production zone aquifer is also illustrated by
these assessments. If the geochemical reducing capacity of the restored wellfield and down-
gradient portions of the production aquifer can be shown to minimize the potential for post-
restoration remobilization of uranium, the regulator can terminate the license with confidence
that the full thirty year monitoring period would not be necessary. Conversely, if the
geochemical model of the system does not indicate a strong chemically reducing environment
exists at the site, the regulatory agency can consider additional monitoring periods as necessary
-------�
to verify that contamination is not moving out of the restored production zone area and
potentially beyond the border of the wellfield aquifer. Developing a defensible geochemical
model of the system can provide significant cost savings for all the alternative situations. If a
strongly reducing environmental is present, costs can be lowered by early termination of the ISR
license since re-mobilization is unlikely and the full 30 year monitoring period may not be
required. If a less effective geochemical situation exists at an ISR site, standard restoration
activities can be augmented to limit the potential for re-mobilization and monitoring efforts can
be focused on detecting re-mobilization before it spreads over a wider area, thereby reducing the
potential for incurring significant remediation costs.
C.4 Estimated Costs of Remediation
The simulation results described above for the pump and treat scenarios were then used to
estimate the costs of remediating a plume of contamination that might result if conditions within
a restored mine unit did not remain stable over time. The costs of remediation include the costs
of the wells (installation and 20% replacement after 20 years) and the costs of treatment. Not
explicitly included are costs of disposing of treated water since during the pump and treat
operations, it is assumed that much of this will be re-injected; in addition, treated water could be
evaporated from holding ponds or used for irrigation in these generally rural areas. None of these
options would add significant costs. Also omitted from the costs are scoping assessments to
identify the location and characteristics of the plume. In reality, such scoping would likely be
needed to determine how to structure the pump and treat remediation. Omitting these costs
means that our estimated costs of remediation may underestimate actual costs.
This examination of the requirements and costs of remediating a plume of constituents at
the CMU (under varying scenarios) is meant to illustrate the value of long-term stability
monitoring. Clearly, the potential for remobilization, and creation of contaminant plumes, varies
widely from site to site. EPA therefore did not attempt to generalize or extrapolate to estimate
remediation requirements or costs that would be incurred at actual ISR sites. Instead, this is a
CMU-specific example.
Table C-3 presents the estimated costs of remediation. Annual O&M costs are a function
of the number of wells (and thus, the estimated wellfield yield); they are estimated based on a
unit cost of $6.35 per 1000 gallons (EPA, 2001) treated. Capital costs are also a function of the
number of wells (and the estimated wellfield yield), and are computed based on $30.48 per
thousand gallons (EPA, 2001) treated. It is assumed that, after 20 years, 20% of the wells will
need to be replaced. Capital costs are annualized over a period of 20 years at 7% rate of interest.
C-9
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Total annualized costs are the sum of annual O&M costs and annualized capital costs for each
scenario.
Because higher Kd means the constituents are more difficult to remove (due to the
tendency for the constituents to adhere to aquifer matrix material), both the number of wells and
the duration of treatment increase as Kd increases under each scenario (transverse to the length of
the deposit and along the length of the deposit).
Also included in Table C-3 is a "short" remediation example, intended to represent the
costs of using pump and treat methods to address increasing constituent concentrations detected
in only a small area of the wellfield, approximately 20 acres. Fewer wells would be needed, and
a shorter duration of treatment would be required to remediate the plume. This represents a
lower-bound estimate of potential pump and treat remediation costs.
Table C-3. Estimated Costs of Remediation (Thousand $2011)
Transverse
to length of
deposit
Along length
of deposit
Short
Kd
l.OE-06
6.0E-06
l.OE-05
l.OE-06
6.0E-06
l.OE-05
6.0E-06
No. of
Wells
40
72
90
29
71
89
10
Annual
Wellfield
Yield
(1000 gal)
630,720
1,135,296
1,419,120
457,272
1,119,528
1,403,352
157,680
Annual
O&M
4,005
7,209
9,011
2,904
7,109
8,911
1,001
Costs, S
Capital
19,224
34,604
43,258
13,938
34,123
42,774
4,806
Annualized
Total
Capital
1,815
3,266
4,083
1,316
3,221
4,038
454
Pumping
Duration
(years)
20
60
80
50
75
100
30
Total
Annualized
Remediation
Costs
5,820
10,475
13,094
4,219
10,330
12,949
1,455
Table C-4 summarizes the overall cost estimates. EPA estimated that contamination
moving transverse to the length of the deposit would be detected in 6 years after restoration is
complete, and that contamination moving along the length of the deposit would be detected after
the site is decommissioned and the license terminated. In fact, a plume of contamination would
be detected only if and when someone wishing to use groundwater in the area had it tested; the
longer the time before the plume is detected, the more extensive the area of contamination is
likely to be, and the more costly it would be to remediate, and greater is the possibility that
humans or ecological receptors could be exposed to the constituents. If contamination does
occur, and is detected long after license termination, the costs of remediation could fall on the
taxpayer, rather than the owner/operator.
C-10
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Table C-4. Summary of Estimated Remediation Costs, by Scenario and Kd (Millions
$2011)
Kd (m3/gm): l.OE-06
Scenario: Transverse to the length of the ore deposit
Summed Costs $99.3
Scenario: Along the length of the ore deposit
Summed Costs $163.3
Scenario: Short, assumes small area of contamination
is detected during long-term stability monitoring
Summed Costs
6.0E-06
$481.0
$586.1
Kd=6.0E-06
$35.3
l.OE-05
$790.1
$968.1
The summary provided below, for each remediation scenario and assumed Kd, shows that
costs (either summed across the duration of the pump and treat remediation operations without
discounting, or present values discounted at 3% or discounted at 7%) increase depending on the
size of the plume, the direction of groundwater flow, and the Kd. Comparing the estimated total
summed costs of pump and treat remediation for Kd=6.0E-06 m3/gm (under different scenarios)
to the cost of complying with the proposed rule, including resuming restoration if contamination
is discovered during long-term stability monitoring (see Table 4-1 for details) demonstrates the
advantage of monitoring long enough to detect an upward trend in some constituents while the
plume is still small so that re-mobilization can be detected and decisions made concerning
treatment before the contamination becomes widespread and more expensive remedies are
needed.
C.5 References
McDonald, M.G., and A.W. Harbaugh, 1983. A modular three-dimensional finite-difference
ground-water flow model. Open-File Report 83-875. U.S. Geological Survey, December
28.
McWorter, D.B. and D.K. Sunada, 2010. Ground-Water Hydrology and Hydraulics; Water
Resources Publications, LLC; ISBN-10: 1887201610; ISBN-13: 978-1887201612; 304
pages.
Michel, T.G. and G. Hoffman, \99l.E-Field50 Sand Mine Unit Hydrology Test, Highland
Uranium Project, Power Resources, Inc.; Report for WDEQ/LQD Permit Number 603,
U. S. Nuclear Regulatory Commission Docket Number 40-8857, SUA-1511; Report by
Power Resources, Inc. and Hydro-Engineering; September 1990, revised July 1991.
C-ll
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Pearson, F.J., Jr., C. J. Noronha and R.W. Andrews, 1983. "Mathematical Modeling of the
Distribution of Natural 14-C, 234-U, and 238-U in a Regional Ground-Water System,"
Radiocarbon, Vol.25, No. 2, 1983, p 291-300.
U.S. Environmental Protection Agency (EPA), 2001. Cost of Analysis for Selected Groundwater
Cleanup Projects: Pump and Treat Systems and Permeable Reactive Barriers; U.S. EPA,
Office of Solid Waste and Emergency Response; EPA Document No. 542-R-00-013;
Exhibit 7, page 8, February.
Zheng, C. and P.P. Wang, 1999. MT3DMS: A modular three-dimensional multispecies model
for simulation of advection, dispersion and chemical reactions of contaminants in
groundwater systems; Documentation and User's Guide, Contract Report SERDP-99-1,
U.S. Army Engineer Research and Development Center, Vicksburg, MS.
C-12
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APPENDIX D
SENSITIVITY ANALYSIS: ESTIMATED COSTS AND ECONOMIC IMPACTS
This Appendix presents results of a sensitivity analysis conducted to explore the
uncertainty around costs of sampling. In Section 3, EPA presented the assumptions for each
phase of ISR monitoring. These assumptions, shown in Tables 3-2 through 3-5, include a range
of sampling and analysis costs. They also reflect estimated requirements under two regulatory
alternatives and a "worst case" under which geochemical modeling does not provide assurance
of future stability, and 30 years of long-term stability monitoring are required, in addition to
geochemical modeling. As discussed in Section 3 above, EPA does not believe this "worst case"
is likely to occur, because it would require that geochemical modeling conducted prior to the
start of operations yields results that indicate that conditions would be stable long-term, but
geochemical modeling conducted after operations have ended yields the opposite result. In
reporting the results of the economic impact analysis in the main sections of this document, EPA
focused on the proposed regulatory option; this appendix provides results for all the costing
scenarios, under low, average, and high monitoring cost assumptions.
Table D-l presents estimated costs under each alternative and cost scenario. In general,
the costs are lowest for the proposed regulatory alternative, which includes 30 years of long term
stability monitoring, with the potential to shorten the duration if geochemical modeling indicates
that geochemical conditions in the wellfield and especially down-gradient from the field will
ensure that restored conditions will remain stable over time. Costs for the other regulatory
alternative, which requires 30 years of long-term stability monitoring with no potential for
shortening the duration, are slightly higher. Table D-l also presents the "worst case" scenario,
which assumes that the geochemical modeling does not provide assurance of stability, so that 30
years of long term stability monitoring is then required. As ex[ected, these costs are the highest.
Table D-2 presents the results of a market model, which examines how the market for
uranium (UsOg) would potentially be affected by the costs of complying with the regulation,
under each alternative and costing scenario. The proposed regulatory alternative increases the
cost of producing uranium by $1.30 to $1.70 per pound of UsOg. The 30-year long term stability
monitoring with no potential to reduce duration causes the cost of uranium production to increase
by an estimated $1.44 to $2.00 per pound. The "worst case" costing scenario causes the cost of
uranium production to increase by $1.51 to $2.40 per pound. The lower the increase in the unit
cost, the smaller the effect on the market. In all cases, the market price of UsOg is projected to
increase by less than the unit cost, domestic uranium production is projected to decline, and
imports of uranium are projected to increase.
D-l
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Table D-l. Estimated Facility and National Costs, by Costing Scenario (Thousand 2011$)
Proposed Rule: 30-Year Long-term Stability Monitoring
with Geochemical Modeling to Shorten Duration
ISR Operation
La Palangana
Alta Mesa
Willow Creek
Crow Butte
Smith Ranch-Highland-Reynolds
Lost Creek
Estimated Incremental National Costs
Total Annualized Cost
Total Cost, Summed across LOM
Present Value, 3% discount rate
Present Value, 7% discount rate
Required 30-Year Long-Term Stability Monitoring
ISR Operation
La Palangana
Alta Mesa
Willow Creek
Crow Butte
Smith Ranch-Highland-Reynolds
Lost Creek
Estimated Incremental National Costs
Total Annualized Cost
Total Cost, Summed across LOM
Present Value, 3% discount rate
Present Value, 7% discount rate
Low
$262
$412
$510
$1,905
$8,224
$317
$11,631
$379,564
$253,378
$156,468
$290
$456
$565
$2,107
$9,097
$351
$12,865
$684,068
$355,378
$173,072
Average
$304
$477
$591
$2,205
$9,521
$367
$13,465
$431,284
$289,991
$181,135
$340
$534
$661
$2,468
$10,657
$411
$15,072
$814,903
$419,826
$202,754
High
$343
$540
$668
$2,493
$10,766
$415
$15,226
$490,514
$329,385
$204,822
$404
$635
$786
$2,931
$12,658
$488
$17,901
$975,573
$500,372
$240,818
(continued)
D-2
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Table D-l. Estimated Facility and National Costs, by Costing Scenario (Thousand 2011$)
(continued)
Geochemical Modeling with 30-Year Long- Term
Stability Monitoring
ISR Operation
La Palangana
Alta Mesa
Willow Creek
Crow Butte
Smith Ranch-Highland-Reynolds
Lost Creek
Estimated Incremental National Costs
Total Annualized Cost
Total Cost, Summed across LOM
Present Value, 3% discount rate
Present Value, 7% discount rate
Low
$305
$480
$594
$2,217
$9,571
$369
$13,536
$15,145
$7,999
$3,960
Average
$390
$613
$759
$2,832
$12,229
$472
$17,296
$18,575
$9,922
$5,060
High
$484
$761
$942
$3,516
$15,182
$586
$21,472
$22,642
$12,157
$6,281
Scaled up from CSM to national costs based on estimated total acreage.
Table D-3 examines the ratio of the estimated costs incurred by companies owning ISR
facilities to their revenues, to assess the potential financial impacts of complying with the rule on
firms in the industry, especially small firms. For the two large firms, reported 2013 sales are used
to estimate 2015 sales. Revenues for two small firms owning currently-operating ISR facilities
are not publicly available. They are estimated based on the projected 2015 price of uranium
($57.00 per pound) and their estimated facility production in 2015. A third small firm is publicly
traded (Uranium Energy); its 2013 sales are depressed due to market conditions; because we are
projecting improved market conditions by 2015, we also estimate sales for this firm, based on
estimated 2015 facility production and estimated market price. The proposed regulatory
alternative results in cost-to-sales ratios ranging from 0.1% to 1.9%, depending on the costing
scenario. Even under the "worst case" costing scenario, costs are at most 2.7% of estimated
company sales under the highest costing assumptions. Because costs are estimated to be less than
3.0% of company sales for the small businesses owning currently operating ISR facilities, and
because EPA expects at most 10 small firms may be affected by the rule going forward, EPA
concludes that the rule will not have a significant impact on a substantial number of small firms.
D-3
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Table D-2. Estimated Market Impacts by Regulatory Alternative
Proposed Rule: 30-Year Long-Term Stability
Monitoring with Geochemical Modeling to
Shorten Duration
Supply (1,000 pounds U3O8)
U.S. Origin (1,000 pounds U3O8)
ROW (1,000 pounds U3O8)
Demand (1,000 pounds U3O8)
Price ($/pound U3O8)
Change in Price
Percentage Changes
Market Quantity
U.S. Quantity
Imports
Price
Compliance Cost per Pound
Required 30-Year Long-Term Stability
Monitoring
Supply (1,000 pounds U3O8)
U.S. Origin (1,000 pounds U3O8)
ROW (1,000 pounds U3O8)
Demand (1,000 pounds U3O8)
Price ($/pound U3O8)
Change in Price
Percentage Changes
Market Quantity
U.S. Quantity
Imports
Price
Compliance Cost per Pound
With
Baseline Low
57,630 57,616
9,451 9,089
48,179 48,527
57,630 57,616
$57.00 $57.21
$0.21
-0.02%
-3.8%
0.7%
0.4%
$1.30
57,630 57,615
9,451 9,050
48,179 48,564
57,630 57,615
$57.00 $57.23
$0.23
-0.03%
-4.2%
0.8%
0.4%
$1.44
Regulation in
Average
57,614
9,032
48,582
57,614
$57.24
$0.24
-0.03%
-4.4%
0.8%
0.4%
$1.50
57,612
8,982
48,631
57,612
$57.27
$0.27
-0.03%
-5.0%
0.9%
0.5%
$1.68
Effect
High
57,612
8,977
48,635
57,612
$57.27
$0.27
-0.03%
-5.0%
0.9%
0.5%
$1.70
57,609
8,893
48,715
57,609
$57.32
$0.32
-0.04%
-5.9%
1.1%
0.6%
$2.00
(continued)
D-4
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Table D-2. Estimated Market Impacts by Regulatory Alternative (continued)
With Regulation in Effect
Baseline
Low
Average
High
Geochemical Modeling with 30-Year Long-
Term Stability Monitoring
Supply (1000 pounds U3O8)
U.S. Origin (1000 pounds U3O8)
ROW (1000 pounds U3O8)
Demand (1000 pounds U3O8)
Price ($/pound U3O8)
Change in Price
Percentage changes
Market Quantity
U.S. Quantity
Imports
Price
Compliance Cost per Pound
57,630
9,451
48,179
57,630
$57.00
57,614
9,029
48,585
57,614
$57.24
$0.24
-0.03%
-4.5%
0.8%
0.4%
$1.51
57,610
8,912
48,697
57,610
$57.31
$0.31
-0.04%
-5.7%
1.1%
0.5%
$1.93
57,605
8,782
48,823
57,605
$57.38
$0.38
-0.04%
-7.1%
1.3%
0.7%
$2.40
D-5
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Table D-3. Estimated Company Cost-to-Sales Ratios by Regulatory Alternative
30 Year with Geochemical Modeling
Parent Company
Cameco
Mestena
Uranium One
Uranium Energy
Ur-Energy
30-Year Stability
Parent Company
Cameco
Mestena
Uranium One
Uranium Energy
Ur-Energy
Geochem with Required 30 Year
Parent Company
Cameco
Mestena
Uranium One
Uranium Energy
Ur-Energy
Estimated
2015 Sales
(millions
USD)
$2,400.0
$28.5
$530.4
$28.5
$57.0
$2,400.0
$28.5
$530.4
$28.5
$57.0
$2,400.0
$28.5
$530.4
$28.5
$57.0
Low
0.4%
1.4%
0.1%
0.9%
0.6%
0.5%
1.6%
0.1%
1.0%
0.6%
0.5%
1.7%
0.1%
1.1%
0.6%
Average
0.5%
1.7%
0.1%
1.1%
0.6%
0.5%
1.9%
0.1%
1.2%
0.7%
0.6%
2.2%
0.1%
1.4%
0.8%
High
0.6%
1.9%
0.1%
1.2%
0.7%
0.6%
2.2%
0.1%
1.4%
0.9%
0.8%
2.7%
0.2%
1.7%
1.0%
D-6
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