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1. WATER QUALITY PREDICTIONS AT HARDROCK MINE SITES: METHODS, MODELS, AND CASE STUDY COMPARISON
James Kuipers, Kuipers & Assoc
Ann Maest, Buka Environmental
2. Study Approach Synthesize existing reviews
Develop “toolboxes”
Evaluate methods and models
Recommendations for improvement
Outside peer review (Logsdon, Nordstrom, Lapakko)
Case studies Synthesize existing reviews – lead to more depth and breadth
Develop characterization and modeling “toolboxes”
Evaluate methods and models - uncertainty
Recommendations for improvement
Outside peer review – in process (Logsdon, Nordstrom, Lapakko)
Case studies
Characterization Program:
scientific and engineering studies that describe the physical, chemical, and biological characteristics of the site, its rocks and minerals, and its fluids
allows one to describe the nature and extent of potential physical and chemical impacts to ground and surface water, and the engineering or institutional steps to control potential water-quality impacts.
Synthesize existing reviews – lead to more depth and breadth
Develop characterization and modeling “toolboxes”
Evaluate methods and models - uncertainty
Recommendations for improvement
Outside peer review – in process (Logsdon, Nordstrom, Lapakko)
Case studies
Characterization Program:
scientific and engineering studies that describe the physical, chemical, and biological characteristics of the site, its rocks and minerals, and its fluids
allows one to describe the nature and extent of potential physical and chemical impacts to ground and surface water, and the engineering or institutional steps to control potential water-quality impacts.
3. 47% did no kinetic testing
16% didn’t evaluate AGP
53% did kinetic
Doesn’t include characterization of mineralogy, whole rock analysis, paste pH, etc., but only 14/69 = 20% mentioned mineralogy in the EIS. Of those with “None,” only one was for an EA. It may be that the information is in other documents, but these are difficult to obtain and are not really considered publicly available.47% did no kinetic testing
16% didn’t evaluate AGP
53% did kinetic
Doesn’t include characterization of mineralogy, whole rock analysis, paste pH, etc., but only 14/69 = 20% mentioned mineralogy in the EIS. Of those with “None,” only one was for an EA. It may be that the information is in other documents, but these are difficult to obtain and are not really considered publicly available.
6. Specific Models Used Water Quantity only (18 mines)
Near-surface processes: HEC-1, HELP
Sediment transport: SEDCAD, MUSLE, RUSLE, R1/R3SED
Storm hydrographs: WASHMO
Groundwater flow: MODFLOW, MINEDW
Vadose zone: HYDRUS; drawdown
7. Specific Models Used (cont.) Water quantity and quality (21 mines)
Water quantity + PHREEQE (3), WATEQ (1), MINTEQ (5)
Pyrite oxidation (PYROX) – 3 mines
Water balance/contam transport (LEACHM) – 1 mine
Pit water flow and quality (limited): CE-QUAL-W2 (3), CE-QUAL-R1 (1)
Mass balance/loading: unspecified (4 mines), FLOWPATH
Proprietary codes for pit lake water quality or groundwater quality downgradient of waste rock pile (4 mines)
8. Sources of Uncertainty - Modeling Use of proprietary codes
need testable, transparent models – difficult to evaluate, should be avoided. Need efforts to expand publicly available pit lake models (chemistry).
Modeling inputs
large variability in hydrologic parameters; seasonal variability in flow and chemistry; sensitivity analyses (ranges) rather than averages/medians
Estimation of uncertainty
Acknowledge and evaluate effect on model outputs; test multiple conceptual models
“…there is considerable uncertainty associated with long-term predictions of potential impacts to groundwater quality from infiltration through waste rock...for these reasons, predictions should be viewed as indicators of long-term trends rather than absolute values.”;
CAEDYM is a publicly available lake model, but it is more of an aquatic ecological model than a hydrogeochemical model. Only addresses Fe, Mn, Al – redox chemistry (including Al redox chemistry???). Can be linked with a 3D hydrodynamic model, but unclear if user would have to input all info on groundwater inputs, loads from wall rock, etc.
Hydrologic parameters: hydraulic conductivity
Uncertainty analysis: Monte Carlo analysis, stochastic methods, and evaluating a range of model parameters to develop a range of deterministic outcomes (e.g., a range of water quality in a given receptor). These methods account for the fact that, rather than being well described by a single value as required in the model, parameters are better described with a probability distribution (i.e., a mean, variance, skewness, etc.), especially hydraulic conductivity and other hydrologic parameters. Uncertainty may derive from incomplete characterization, an inability to discretize the model domain sufficiently, or incomplete knowledge of the geochemical and hydrologic conditions at the site. CAEDYM is a publicly available lake model, but it is more of an aquatic ecological model than a hydrogeochemical model. Only addresses Fe, Mn, Al – redox chemistry (including Al redox chemistry???). Can be linked with a 3D hydrodynamic model, but unclear if user would have to input all info on groundwater inputs, loads from wall rock, etc.
Hydrologic parameters: hydraulic conductivity
Uncertainty analysis: Monte Carlo analysis, stochastic methods, and evaluating a range of model parameters to develop a range of deterministic outcomes (e.g., a range of water quality in a given receptor). These methods account for the fact that, rather than being well described by a single value as required in the model, parameters are better described with a probability distribution (i.e., a mean, variance, skewness, etc.), especially hydraulic conductivity and other hydrologic parameters. Uncertainty may derive from incomplete characterization, an inability to discretize the model domain sufficiently, or incomplete knowledge of the geochemical and hydrologic conditions at the site.
10. Summary Characterization methods need major re-evaluation, especially static and short-term leach tests
Increased use of mineralogy in characterization – make less expensive, easier to use/interpret
Modeling uncertainty needs to be stated and defined
Limits to reliability of modeling – use ranges rather than absolute values
Increased efforts on long-term case studies
11. Comparison of Predicted and Actual Water Quality
12. EIS Review Mines
183 major, 137 NEPA, 71 NEPA reviewed
Similar in location, commodities, extraction, processing, operational status
104 EISs reviewed for 71 mines
16 months to obtain all documents
Compared EIS predictions to actual water quality for 25 case study mines
137 NEPA = on federal lands or certain NPDES or ACOE or 404 permits or land on Native American trust lands administered by BIA or state NEPAs (CA, MT, WA, WI)
Largest repository of mining EISs in western hemisphere = Jim Kuiper’s office in Butte after I sent him my 10 boxes of EISs137 NEPA = on federal lands or certain NPDES or ACOE or 404 permits or land on Native American trust lands administered by BIA or state NEPAs (CA, MT, WA, WI)
Largest repository of mining EISs in western hemisphere = Jim Kuiper’s office in Butte after I sent him my 10 boxes of EISs
13. EIS Years
14. EIS Approach to Impacts
15. Case Study Mines Selection based on
ease of access to water quality data
variability in geographic location, commodity type, extraction and processing methods
variability in EIS elements related to water quality (climate, proximity to water, ADP, CLP)
Best professional judgment
Similar to all NEPA mines, but
more from CA and MT
fewer Cu mines
more with moderate ADP and CLP
more with shallower groundwater depths
16. Case Study Mines: General States
AK: 1 - MT: 6
AZ: 2 - NV: 7
CA: 6 - WI: 1
ID: 2
Commodity
Au/Ag: 20 - Pb/Zn: 1
Cu/Mo: 2 - PGM: 1
Mo: 1 Extraction type
open pit: 19
underground: 4
both: 2
Processing type
CN Heap: 12
Vat: 4
Flotation: 7
Dump Leach: 2
17. Case Study Mines Selected
18. Comparison Results Mines with mining-related surface water exceedences: 60%
% estimating low impacts pre-mitigation: 27%
% estimating low impacts with mitigation: 73%
Mines with mining-related groundwater exceedences: 52%
% estimating low impacts pre-mitigation: 15%
% estimating low impacts with mitigation: 77%
Mines with acid drainage on site: 36%
% predicting low acid drainage potential: 89% Later compare overall findings with findings for mines with inherent geochemical and hydrologic characteristics.Later compare overall findings with findings for mines with inherent geochemical and hydrologic characteristics.
19. Inherent Factors ore type and association
climate
proximity to water resources
pre-existing water quality
constituents of concern
acid generation and neutralization potentials
contaminant leaching potential This is the type of information on inherent factors we could find in EISs.
ore type and association (e.g., commodity, sulfide vs. oxide ore, vein vs. disseminated)
• climate (e.g., amount and timing of precipitation, evaporation, temperature)
• proximity to water resources (distance to surface water resources, depth to groundwater resources, presence of
springs)
• pre-existing water quality (baseline groundwater and surface water quality conditions)
• constituents of concern
• acid generation and neutralization potentials (and timing of their release), and
• contaminant generation potential.
This is the type of information on inherent factors we could find in EISs.
ore type and association (e.g., commodity, sulfide vs. oxide ore, vein vs. disseminated)
• climate (e.g., amount and timing of precipitation, evaporation, temperature)
• proximity to water resources (distance to surface water resources, depth to groundwater resources, presence of
springs)
• pre-existing water quality (baseline groundwater and surface water quality conditions)
• constituents of concern
• acid generation and neutralization potentials (and timing of their release), and
• contaminant generation potential.
20. Surface Water Results Arguably, for all case study mines, there were 12/15 that exceeded that predicted no exceedences (Thompson predicted no exceedence in one EIS). This brings % to 80%.
All results are for mining-related impacts or exceedences.
Suggests that mines with these factors are more likely to have surface water quality problems.Arguably, for all case study mines, there were 12/15 that exceeded that predicted no exceedences (Thompson predicted no exceedence in one EIS). This brings % to 80%.
All results are for mining-related impacts or exceedences.
Suggests that mines with these factors are more likely to have surface water quality problems.
21. Groundwater Results All results are for mining-related impacts or exceedences.
Suggests that mines with these factors are more likely to have groundwater quality problems.
All results are for mining-related impacts or exceedences.
Suggests that mines with these factors are more likely to have groundwater quality problems.
22. Mines without Inherent Factors California desert mines
American Girl, Castle Mountain, Mesquite
No groundwater or surface water impacts or exceedences
Delayed impacts? Climate change (but less precip predicted)
Stillwater, Montana
Close to water, low ADP, moderate/high CLP
Unused surface water discharge permit
Increases in nitrate (predicted from LAD by modeling) in Stillwater River, but no exceedences
Mining-related exceedences in adit and groundwater under LAD, but related to previous owners?
Inherently lucky – ultramafic mineralogy Check on high %S.
Better mines had more accurate predictions – but only b/c ~all said there would be no WQ problems after mitigations were in place
Note that “better” performance is generally related to inherent factors, not mitigations or operational controls.Check on high %S.
Better mines had more accurate predictions – but only b/c ~all said there would be no WQ problems after mitigations were in place
Note that “better” performance is generally related to inherent factors, not mitigations or operational controls.
23. Predicted vs. Actual Water Quality Cascading effect – if geochemi/hydrololic info is wrong, mitigations won’t be what they need to be.
Not all exceeds were caused by mitigation failures; some mines had all three kinds of failures (geochem, hydrologic, mitigation).
Cascading effect – if geochemi/hydrololic info is wrong, mitigations won’t be what they need to be.
Not all exceeds were caused by mitigation failures; some mines had all three kinds of failures (geochem, hydrologic, mitigation).
24. Implications Mines close to water with mod/high ADP/CLP need special attention from regulators
Water quality impact predictions before mitigation in place more reliable
These can be in error too – geochemical and hydrologic characterization need improvement
Why do mitigations fail so often and what can be done about it?
25. Characterization Methods Geology
Mineralogy
Whole rock analysis
Paste pH
Sulfur analysis
Total inorganic carbon
Static testing
Short-term leach testing
Laboratory kinetic tests
Field testing of mined materials
26. Modeling Opportunities
27. Modeling Toolbox Category/subcategory of code
Hydrogeologic, geochemical, unit-specific
Available codes
Special characteristics of codes
Inputs required
Modeled processes/outputs
Step-by-step procedures for modeling water quality at mine facilities
28. EIS Information Reviewed Geology/mineralogy
Climate
Hydrology
Field/lab tests
Predictive models used Water quality impact potential
Mitigation measures
Predicted water quality impacts
Discharge information Information was scored (0 – 7). Information derived from Section 3’s of EISs: Environmental Consequences. Didn’t get additional reports, but did look at appendices.
Hydrology
proximity to surface water
Depth to groundwater
Water quality impact potential
acid drainage (ADP)
contaminant leaching (CLP)
surface water
groundwater
pit water
Mitigation measures
surface water
groundwater
pit water
treatment
other
Predicted water quality impacts
surface water
groundwater
pit water
Discharge information
zero discharge
surface water
groundwaterInformation was scored (0 – 7). Information derived from Section 3’s of EISs: Environmental Consequences. Didn’t get additional reports, but did look at appendices.
Hydrology
proximity to surface water
Depth to groundwater
Water quality impact potential
acid drainage (ADP)
contaminant leaching (CLP)
surface water
groundwater
pit water
Mitigation measures
surface water
groundwater
pit water
treatment
other
Predicted water quality impacts
surface water
groundwater
pit water
Discharge information
zero discharge
surface water
groundwater
29. Surface Water Examples Flambeau, WI had inherent factors but no impact or exceedence to date
Stillwater, MT had an impact (0.7 mg/l nitrate in Stillwater River) but no exceedence
McLaughlin, CA predicted exceedences in surface water and was correct McLaughlin Mine:
Acid Drainage and Contaminant Leaching Potential: Ninety-two% of the waste rock has been determined to be either neutralizing or itself neutral. Comparison of the (tailings) extract analysis concentrations with the health-based Soluble Threshold Limit Concentration (STLC) based on the WET test shows that the estimated concentration of copper exceeds the STLC which could cause the tailings to be considered hazardous. In addition to high copper values, the tailings extract also had lead, arsenic, silver, and cyanide concentrations in excess of water quality standards.
Potential Water-Quality Impacts (before mitigations): Groundwater - Permanent degradation of groundwater quality is expected due to tailings seepage. Surface Water - There are three types of surface water quality impacts that may potentially occur (from the waste rock dumps): (1) increased sedimentation from runoff, (2) increased total dissolved solids from leachate, and (3) increased heavy metal concentrations from acidic leachate. Potential water quality decreases in Hunting Creek from waste rock leachate. Pit Water - Quality of water accumulated in the pit is expected to be of poor quality, with high concentrations of heavy metals and major ions including arsenic, cadmium, iron, lead, manganese, mercury, nickel, boron, sodium, chloride, and sulfate.
Mitigations: Groundwater – monitoring. Underdrains for waste rock piles. Surface Water - Sediment basins to protect streams and numerous erosion/sedimentation controls. Potentially acid generating rock will be surrounded by alkaline material during waste rock disposal. Lime will be added to sediment ponds if acidic conditions are encountered during mining. Pit Water – None.
Predicted Water-Quality Impacts (after mitigations): Groundwater - Proposed tailings facility would allow 40 gpm of seepage to local groundwater underlying the reservoir. This impact would be long term, resulting in permanent degradation of the local groundwater and potentially of the shallow groundwater flowing toward Hunting Creek. Existing groundwater data in the tailings area show poor quality water with long residence times, and very low permeabilities. Therefore, although the proposed action and alternatives would lead to permanent degradation of localized groundwater, local water supply would not be impacted, because the groundwater regime in Quarry Valley has not been found to be connected to a regional aquifer system, and the dam foundation would penetrate to less permeable material. Possible release of TDS from waste rock dump, but it will be collected in the underdrains, the diversion ditches, or in the sediment impoundment. Surface Water - Modeling indicated that arsenic, nickel, zinc, silver, iron, and copper concentrations would be lower than drinking water standards in Hunting Creek. Manganese was predicted to slightly exceed its standard. There would be no impact to surface water quality under normal operation of the mill facilities. Pit Water - The quality of water accumulated in the pit is expected to be of poor quality, with high concentrations of heavy metals and major ions including arsenic, cadmium, iron, lead, manganese, mercury, nickel, boron, sodium, chloride, and sulfate. Predominance of alkaline producing materials in the rocks would likely produce alkaline pH conditions in the mine pit water and would tend to reduce metals leached from the rocks. Pit water would not reach surface streams, and no impacts on the quality of Hunting, Davis, or Knoxville creeks are anticipated.
Surface Water Impacts: Potential surface water quality impacts from tailings were not expected; however, potential
impacts from waste rock were recognized and modeled. Modeled arsenic, nickel, zinc, silver, iron and copper
concentrations were predicted to be lower and manganese higher than drinking water standards in Hunting Creek.
The modeling results were correct for zinc, silver, manganese and copper, which did not exceed standards but were
incorrect for arsenic, nickel and iron, which did exceed standards.
McLaughlin Mine:
Acid Drainage and Contaminant Leaching Potential: Ninety-two% of the waste rock has been determined to be either neutralizing or itself neutral. Comparison of the (tailings) extract analysis concentrations with the health-based Soluble Threshold Limit Concentration (STLC) based on the WET test shows that the estimated concentration of copper exceeds the STLC which could cause the tailings to be considered hazardous. In addition to high copper values, the tailings extract also had lead, arsenic, silver, and cyanide concentrations in excess of water quality standards.
Potential Water-Quality Impacts (before mitigations): Groundwater - Permanent degradation of groundwater quality is expected due to tailings seepage. Surface Water - There are three types of surface water quality impacts that may potentially occur (from the waste rock dumps): (1) increased sedimentation from runoff, (2) increased total dissolved solids from leachate, and (3) increased heavy metal concentrations from acidic leachate. Potential water quality decreases in Hunting Creek from waste rock leachate. Pit Water - Quality of water accumulated in the pit is expected to be of poor quality, with high concentrations of heavy metals and major ions including arsenic, cadmium, iron, lead, manganese, mercury, nickel, boron, sodium, chloride, and sulfate.
Mitigations: Groundwater – monitoring. Underdrains for waste rock piles. Surface Water - Sediment basins to protect streams and numerous erosion/sedimentation controls. Potentially acid generating rock will be surrounded by alkaline material during waste rock disposal. Lime will be added to sediment ponds if acidic conditions are encountered during mining. Pit Water – None.
Predicted Water-Quality Impacts (after mitigations): Groundwater - Proposed tailings facility would allow 40 gpm of seepage to local groundwater underlying the reservoir. This impact would be long term, resulting in permanent degradation of the local groundwater and potentially of the shallow groundwater flowing toward Hunting Creek. Existing groundwater data in the tailings area show poor quality water with long residence times, and very low permeabilities. Therefore, although the proposed action and alternatives would lead to permanent degradation of localized groundwater, local water supply would not be impacted, because the groundwater regime in Quarry Valley has not been found to be connected to a regional aquifer system, and the dam foundation would penetrate to less permeable material. Possible release of TDS from waste rock dump, but it will be collected in the underdrains, the diversion ditches, or in the sediment impoundment. Surface Water - Modeling indicated that arsenic, nickel, zinc, silver, iron, and copper concentrations would be lower than drinking water standards in Hunting Creek. Manganese was predicted to slightly exceed its standard. There would be no impact to surface water quality under normal operation of the mill facilities. Pit Water - The quality of water accumulated in the pit is expected to be of poor quality, with high concentrations of heavy metals and major ions including arsenic, cadmium, iron, lead, manganese, mercury, nickel, boron, sodium, chloride, and sulfate. Predominance of alkaline producing materials in the rocks would likely produce alkaline pH conditions in the mine pit water and would tend to reduce metals leached from the rocks. Pit water would not reach surface streams, and no impacts on the quality of Hunting, Davis, or Knoxville creeks are anticipated.
Surface Water Impacts: Potential surface water quality impacts from tailings were not expected; however, potential
impacts from waste rock were recognized and modeled. Modeled arsenic, nickel, zinc, silver, iron and copper
concentrations were predicted to be lower and manganese higher than drinking water standards in Hunting Creek.
The modeling results were correct for zinc, silver, manganese and copper, which did not exceed standards but were
incorrect for arsenic, nickel and iron, which did exceed standards.
30. Groundwater Examples Lone Tree, NV had inherent factors but no mining-related impact or exceedence
baseline issue
McLaughlin, CA had inherent factors and did have exceedences
regulatory exclusion for groundwater (poor quality, low K), so no violations
92% of rocks not acid generating
Tailings leachate flunked STLC – hazardous aquifer
31. McLaughlin Mine, CA: Waste Rock Monitoring Well Mining started in 1985. Don’t know why concentrations started to decrease.Mining started in 1985. Don’t know why concentrations started to decrease.
32. Case Study Mines: Water Quality Climate
Dry/Semi-Arid: 12
Marine West Coast: 1
Humid subtropical: 3
Boreal: 8
Continental: 1
Perennial streams
No info: 1
>1 mi: 6
<1 mi: 7
On site: 11 Groundwater depth
No info: 1
>200’: 3
50-200’: 4
0-50’/springs: 17
Acid drainage potential
No info: 2
Low: 12
Moderate: 8
High: 3
Contaminant leaching
No info: 3
Low: 8
Moderate: 10
High: 4 ADP: based on static testing results, sulfur or pyrite contents or simply on
statements in the EIS or EA that described the acid drainage potential as “low,” “moderate,” or “high” or that the material does or does not have the potential to produce acid. Identification of existing acid drainage was reported in some cases, but more importance was placed on the potential for acid drainage for the proposed project that was the subject of the EIS or EA. The recorded potential for acid drainage is for unit/material with the greatest potential to produce acid.
CLP: Qualitative, or based on short- or long-term leach test results:
Low - leachate does not exceed water quality standards (1)
• Moderate - leachate exceeds water quality standards by
1-10 times (2)
• High - leachate exceeds water quality standards by over
10 times (3)
ADP: based on static testing results, sulfur or pyrite contents or simply on
statements in the EIS or EA that described the acid drainage potential as “low,” “moderate,” or “high” or that the material does or does not have the potential to produce acid. Identification of existing acid drainage was reported in some cases, but more importance was placed on the potential for acid drainage for the proposed project that was the subject of the EIS or EA. The recorded potential for acid drainage is for unit/material with the greatest potential to produce acid.
CLP: Qualitative, or based on short- or long-term leach test results:
Low - leachate does not exceed water quality standards (1)
• Moderate - leachate exceeds water quality standards by
1-10 times (2)
• High - leachate exceeds water quality standards by over
10 times (3)
33. Failure Modes and Effects Analysis
34. Failure Modes and Effects Analysis Hydrological Characterization Failures:
7 of 22 mines exhibited inadequacies in hydrologic characterization
At 2 mines dilution was overestimated
At 2 mines the presence of surface water from springs or lateral flow of near surface groundwater was not detected
At 3 mines the amount of water generated was underestimated
35. Failure Modes and Effects Analysis Geochemical Characterization Failures:
11 of 22 mines exhibited inadequacies in geochemical characterization
Geochemical failures resulted from:
Assumptions made about geochemical nature of ore deposits and surrounding areas
Site analogs inappropriately applied to new proposal
Inadequate sampling
Failure to conduct and have results for long-term contaminant leaching and acid drainage testing procedures before mining begins.
Failure to conduct the proper tests, or to improperly interpret test results, or to apply the proper models
Geochemical failures resulted from:
(1) - (e.g. mining will only be done in oxidized area)
(2) - (e.g. historic underground mine workings do not produce water or did not indicate acid generation)
(3) - (e.g. geochemical characterization did not indicate potential due to composite samples or samples not being representative of actual mining)
Geochemical failures resulted from:
(1) - (e.g. mining will only be done in oxidized area)
(2) - (e.g. historic underground mine workings do not produce water or did not indicate acid generation)
(3) - (e.g. geochemical characterization did not indicate potential due to composite samples or samples not being representative of actual mining)
36. Failure Modes and Effects Analysis Mitigation Failures:
18 of 22 mines exhibited failures in mitigation measures
At 9 of the mines mitigation was not identified, inadequate or not installed
At 3 of the mines waste rock mixing and segregation was not effective
At 11 of the mines liner leaks, embankment failures or tailings spills resulted in impacts to water resources
