ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
&EPA
ss'&V ?
United States
Environmental Protection
Agency
Bunker Hill Mining and
Metallurgical Complex, Idaho,
Superfund Case Study
Revitalization of the Bunker Hill Hillsides
and Wetlands
This is the story of ecological revitalization at two areas of the Bunker Hill
Mining and Metallurgical Complex Superfund site (the Site), where a decades-
long cleanup continues to turn contaminated streams and land into sustainable
ecosystems. Heavy metals contamination in soil, sediment, surface water and
groundwater, the result of over 100 years of historic commercial mining, milling
and smelting industrial operations and disposal practices, has affected both
human health and environmental resources in many areas of the Site. Estimates
indicate that these mining activities resulted in more than 100 million tons of
contaminated materials distributed over thousands of acres in Northern Idaho's
Coeur d'Alene River Basin.
Erosion of contaminated soils from the hillsides, which were devoid of trees
from years of toxic emissions from mineral processing operations, has conveyed
contamination to additional areas, including streams and gulches. The remote
location, steep terrain, lack of topsoil, difficult access, and other constraints made
it challenging to reestablish fertile plants on the hillsides. The adaptive approach
to revegetation of the 1,100-acre southern hillsides near Smelterville and Kellogg,
Idaho, included preliminary studies, amending soil, planting more than two million
trees, anticipation of repair and maintenance needs during revegetation efforts, and
modifications to seed mixes and application techniques as the project progressed.
Within the main stem Coeur D'Alene River Basin, more than 15,000 acres of site
wildlife habitat contain sediments and soils that are acutely toxic to waterfowl.
Waterfowl deaths attributed to lead-contaminated sediment from historic mining
upstream have been recorded at the Site for decades. In 2011, to begin addressing the
impacts, EPA finished converting a 400-acre private agricultural property southwest
of Cataldo, Idaho, to healthy wetland habitat. The area was made into clean feeding
habitat for swans, ducks and other wetland birds, as well as large mammals such as
moose. Today, the remediated and revitalized clean habitat is attracting some of the
highest levels of waterfowl usage, waterfowl feeding, and waterfowl diversity in
the Coeur d'Alene River Basin. Moreover, blood lead data suggest that waterfowl
using the conservation easement are experiencing reduced exposures to lead.
Ecological revitalization has not only helped to mitigate environmental exposure
risks in this area, but is also providing a refuge to sustain ecological habitat and
migratory corridor connectivity while cleanup activities continue.
This case study is part of a
series focused on ecological
revitalization as part of
contaminated site remediation
and reuse; these case
studies are being compiled
by the U.S. Environmental
Protection Agency (EPA)
Technology Innovation and
Field Services Division
(TIFSD). The purpose of these
case studies is to provide
site managers with ecological
reuse information, including
principles for implementation
recommendations based
on personal experiences, a
specific point of contact, and
a network of sites with an
ecological reuse component
Topics Higlighted in
this Case Study:
Erosion
Soil Amendments
Use of Native Plants
Water Management
Wildlife Habitat
Pollinator Habitat
Freshwater Wetlands
Woodlands
Streams
Ecological
Revitalization
Ecological Revitalization is
the process of returning land
from a contaminated state to
one that supports functioning
and sustainable habitat.
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Site History
• The Site is within one of the largest historical mining districts in the world. Commercial mining for lead,
zinc, silver and other metals began in the Silver Valley in 1883.
• Smelter operations ceased in 1981, and while mining and milling activities have significantly decreased
since the late 1980s, several mining operations continue today in the Silver Valley.
• This site covers a large geographic area and is divided into three operable units (OUs) for cleanup:
OU1 - Bunker Hill Box populated areas: populated areas within a 21-square-mile area that includes
the Idaho cities of Kellogg, Wardner, Smelterville and Pinehurst.
OU2 - Bunker Hill Box non-populated areas: non-populated areas within the 21-square-mile area of
the Bunker Hill Box including the former smelter complex and large waste piles.
OU3 - Coeur d'Alene River Basin: includes all areas of the Coeur d'Alene River Basin outside the
Bunker Hill Box where mining-related contamination is located. This includes 45 miles of the South
Fork of the Coeur d'Alene River and its tributaries; 37 river miles of the main stem of the Coeur
d'Alene River and associated floodplains and lakes; Coeur d'Alene Lake; and depositional areas of the
Spokane River, which flows from Coeur d'Alene Lake into Washington State.
• Contamination from mining operations in the Silver Valley spread along more than 160 river miles and over
tens of thousands of acres of wetlands of the Coeur d'Alene and Spokane Rivers, resulting in contamination
of soil, sediment, surface water and groundwater.
• Many communities were built on mine wastes.
• Residential, community and smelter area cleanups have been ongoing since the 1980s.
• The hillsides (OU2) are located across portions of Portal, Deadwood, Magnet, Government, Page, and
Grouse Gulches, and have been affected by mining and metals-refining-related activities.
• Natural events have contributed to the severe erosion and reduced vegetation in many areas of the hillsides.
• Erosion of contaminated soils from the hillsides has conveyed contaminants to streams, sediments, gulch
floors and other areas.
• In the Coeur d'Alene River Basin, many miles of streams cannot sustain a reproducing fish population, and
a number of tri butaries have no or limited aquatic life.
• Lead poisoning is responsible for many waterfowl deaths each year.
• The site ecological cleanup goals are to reduce heavy metals contamination, improve fisheries, reduce
downstream migration of contaminated sediments, and provide safe feeding habitat for waterfowl.
Bunker Hill Hillsides Revitalization
Understanding Hillside Remediation Issues
The hillsides within the Bunker Hill Box non-populated areas (OU2) have been affected by 100 years of mining
and metals-refining-related activities. Mine waste rock dumping, and emissions and fugitive dust from processing
operations resulted in acidic soils depleted of nitrogen, phosphorus and potassium. Logging and clearing resulted
in severe erosion to the hillsides. Natural events such as forest fires, wind and flooding have further increased the
severe erosion and contributed to reduced vegetation in many areas of the hillsides. Topsoil loss has also resulted
in a lack of available soil moisture.
In addition to the lack of topsoil and adverse growing conditions for vegetation, site hillside remediation was a
challenge because of the distance from available soil amendments needed to revegetate the hillsides. Furthermore,
the hillside watersheds were topographically steep and difficult to access by land-based equipment, but the
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Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Bunker Hill
Box
\ Upper Basin,
Coeur d'Alene River,
\ South Fork
hillsides Remediation Area
Site Map
o
NORTH
0 5 10 Miles
Legend
The Bunker Hill Box:
~ Operable Units 1
(Populated Areas) and
2 (Non-populated
Areas)
O Coeur d'Alene River
Subbasin Area of
Concern Boundary
Sources: Esri, DeLorme,
AND, Tele Atlas, First
American, UNEP-WCMC,
USGS.
Lower Basin, /
Coeur d'Alene River
Clean WetlandBVrj&g1^
Coeur
d'Alene
survival of tree seedlings was imperative to reestablish the native ecosystem.
The potentially responsible parties (PRPs) tried to establish vegetation on
portions of the hillsides in 1975-1994, but efforts were largely unsuccessful.
Remediation activities on the roughly 1,100-acre hillsides project area account
for about 8 percent of the 21-square-mile Bunker Hill Box land area and include
portions of six watersheds near the towns of Smelterville and Kellogg, Idaho.
This area presented the most barren view shed to people living in and moving
through the region.
Adaptive Management
Adaptive management is
a decision-making process
based on trial, monitoring
and feedback, and employs a
multi-scalar perspective.
Hillside Remediation Objectives
The ultimate goal for the hillsides is to return them to a coniferous forest ecosystem similar to that found elsewhere
in northern Idaho. However, due to extensive soil loss in this area, the near-term focus of the hillsides project was
to reduce erosion and increase soil development to reduce pollution of the South Fork of the Coeur d'Alene River.
Adaptive management during this process allowed for decision-making flexibility.
To improve watershed function through reduced runoff, soil erosion and pollutant transport, the following goals
were established:
Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Hillsides aerial hydroseeding -1998
Establish herbaceous cover on areas with less than 50 percent cover, with priority to areas with high
contaminant levels or less than 25 percent cover.
Establish check dams in gullies and on terraces.
Establish herbaceous and woody vegetation in gullies and on terraces.
Improve physical and chemical characteristics of soil that impair watershed function and plant growth.
Reduce runoff from existing terraces.
Establish self-regenerating plant species and, where needed, soil-building plant species.
Minimize colonization by noxious weeds.
Manage the hillsides using adaptive management techniques.
Hillside Remediation Results
• Using adaptive management as a basis for the program, a phased treatment program was implemented and
the resulting hillside stability performance guided new decision-making during each phase which reduced
expenses. Prescriptions for hillside restoration were modified over time as demonstration studies matured
and results became evident.
• Plant species were chosen based on field performance and included drought and acid-tolerant species,
nitrogen-fixing species and species that establish rapidly.
• Soil amendments to offset soil nutrient deficiencies had the potential to stimulate growth of hundreds of
thousands of previously planted trees.
• Initial use of pelletized limestone for soil pH adjustment was considered relatively ineffective because the
pellets bounced and rolled down steep slopes. Instead, a hydrated lime product was subsequently applied
with a tackifier and mulch to successfully "stick" the product to the steep hill slopes.
• Changes to the seed mix and tree species composition occurred as monitoring revealed the performance of
individual species within the mix and in seedling trials.
• Sikorsky S-64 air crane helicopters were used for aerial hydroseeding and liming.
• Soil amendments were applied to 371 acres in 2000 and 132 acres in 2001, followed by tree/shrub planting.
The 2001 work represented the final, large-scale revegetation operation on the hillsides.
• The landscape monitoring program used infrared aerial imagery, GIS and land-based methods.
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Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
• Vegetation monitoring began in 2001 and was discontinued after 2005 because results indicated steady hillside
revegetation progress that was capable of controlling erosion and increasing infiltration.
• Water quality monitoring, which was discontinued in 2006, indicated the effectiveness of vegetation cover and
check dams in reducing transfer of sediments from the hillsides to streams.
• As of 2014, vegetation had been fully established at all but a few isolated rocky sites.
• Using native herbaceous plants, such as penstemon, and trees, such as woods
rose, at this site helped create an attractive habitat for wildlife and pollinators.
• Adaptive management converted the hillsides from a barren landscape to one RL JfflRRwfcj g
supporting early-successional plant communities and wildlife.
• In addition to environmental benefits, the landscape has become more scenic W. IPj, jjlHL B
and aesthetically pleasing. This has enhanced economic prospects for Idaho's MBM|Ci
Silver Valley, which is featured by the local chamber of com merce as a tourist
destination.
Hillside Team
CH2M Hill, U.S. Army
Corps of Engineers,
U.S. Forest Service,
IDEQ, EPA, DJN, Inc.
Hillsides 1993 Hillsides 2003
Hillsides 2014
2014 Hillside vegetation growth
Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Herbaceous Plant Species Used on Hillsides in Seed Mix Application
Common Name
Scientific Name
Slender wheatgrass
Elymus trachycaulus ssp. Trachycaulus var. Revenue
Idaho fescue
Festuca idahoensis var. Joseph
Sheep fescue
Festuca ovina var. Covar
Mountain brome
Bromus marginatus var. Broniar
Meadow brome
Bromus biebersteinii var. Paddock
White yarrow
Achillea millefolium
Blue flax
Lifium lewisii var. Appar
Rocky mountain penstemon
Penstemon strictus
Alfalfa*
Medicago sativa var. A! fa graze
Redtop*
Agrostis alba
Canada bluegrass*
Poa compressa
Big bluegrass
Poa ampla var. Sherman
Can by bluegrass
Poa can byi var. Canbar
Cicer rnilkvetch*
Astragalus cicer
Lupine
Lupinus perennis
*Not native to northern Idaho
Tree and Shrub Species Planted on Hillsides During 2001-2002 Planting Seasonsa
Common Name
Scientific Name
Snowbrush ceanothus
Ceanothus velutinus
Red stem ceanothus
Ceanothus sanguineus
Black locust*
Robinia pseudoacacia
Rocky mountain maple
Acer gla brum
Quaking aspen
Populus tremuioides
Saskatoon serviceberry
Amelanchier alnifolia
Woods rose
Rosa woodsii
Mountain alder
Alnus incana
a - In addition to these species, five species of conifers were planted on the hillsides in the past, including western white
pine, western larch, douglasfir, ponderosa pine, and lodgepole pine.
*Not native to northern Idaho
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Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Timeline - Hillsides
1975-1992: The Bunker HOI Company (PRP) planted about two million tree seedlings over
2,290 acres of the Site. They also hydroseeded and terraced the hillsides to control erosion
control and stabilize the hillside.
1994: EPA and the State of Idaho assumed hillside remedial work responsibility.
1996: EPA and the State of Idaho planted tree seedlings in areas not previously planted by
the PRP.
1998: EPA began aerial application of lime and hydroseeds and began check dam
installation.
1999: EPA completed check dam installation along terrace benches and began hillside
surface water quality pilot study.
2001: EPA completed liming and hydroseeding; began tree/shrub planting.
2002: EPA completed tree/shrub planting.
2005: EPA discontinued vegetation monitoring.
2006: EPA discontinued surface water monitoring.
Hillsides Map
City of
Smelterville
City of
Kellogg
Smelter Closure Area
(Former Lead Smelter)
Former Zinc Plant
WA ID
O 0 1,500 3,000 Feet
NORTH I I I I I
Sources: Esri, DeLorme, AND, Tele Atlas, First American, UNEP-WCMC, USGS.
Legend
~ Hillsides
Gulches
I:::: :l Smelter Closure Area (Former Lead Smelter)
L,. J Former Zinc Plant
Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Bunker Hill Wetlands Revitalization
Understanding Wetland Remediation Issues
About 25 miles west of the hillsides remedial area and
downstream along the Coeur d'Alene River, a private,
contaminated agricultural property was converted to
healthy wetland habitat. Soil and sediment throughout the
floodplains of the lower Coeur d'Alene River Basin (OU3)
are contaminated with lead washed downstream over
the years from the historic upper Basin mining disposal
activities. Lead contaminated sediments in the floodplains
have caused adverse effects to wildlife. Studies conducted
during the remedial investigation indicate that over 18,000
acres of waterfowl habitat in the lower Basin exceed adverse
effects levels and over 15,000 acres exceed lethal thresholds.
Notably, waterfowl, (e.g., tundra swans and ducks) ingest
highly contaminated sediment to the extent that many
have suffered toxic effects or died from ingestion of lead
The area is a critical part of the Pacific migration flyway
and waterfowl deaths due to lead-contaminated sediment
have been recorded in the Coeur d'Alene River Basin for
decades. Because lead is stable in the environment, the
contamination presents a continued unacceptable exposure
risk. Actions to address the widespread contamination in
the Lower Basin are included in EPA's 2002 OU3 (Basin)
Superfund Record of Decision.
Wetland Remediation Objectives
Under the EPA 2002 Superfund cleanup plan, the remedial
action objectives for addressing wetland areas include:
• Remediate contaminated soil, sediment and water to
create habitat areas capable of supporting a functional
ecosystem.
• Prevent ingestion and dermal contact by ecological
receptors with toxic levels of heavy metals.
Farmland before wetland restoration
(Source: http://restorationpartnership.org/wet-
land restoration proiect.html)
Wetlands Remediation
r a -1 orw: rDA a ++i • . , Tundra swans feeding in the clean wetlands
In April 2006, EPA used settlement monies to purchase a f ,, „0 t j .j* -i
1 , 1 . following Superfund remediation and
perpetual conservation easement that allows for remediation restoration by the Natura| Resource Trustees.
and restoration of a functional wetland to create a clean
waterfowl feeding habitat. Remediation of the nearly 400-
acre easement area southwest of Cataldo, Idaho, was phased starting with the smaller East Field and followed by
the larger West Field. Remedial designs were developed using a team approach involving EPA, the property owner
and the Coeur d'Alene Basin Natural Resource Trustees. The design and planning process included substantive
compliance with the Clean Water Act Sections 401 and 404, National Historic Preservation Act, and Native American
8 Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Graves Protection Repatriation Act. EPA also obtained a legal water right for the project. Design objectives included
no off-site disposal of contaminated soil and minimizing the long-term operation and maintenance requirements.
The wetland remedial action included the following construction activities:
• Remediation of soil with elevated metal concentrations using several
techniques depending on soil contamination depth.
• Installation of water diversion structures to provide clean water for the
wetland under a water right.
• Development of water control and drainage structures to allow
effective water management.
• Installation of overflowweirstoreducethe potential forrecontamination
of the wetland from flooding of the contaminated Coeur d'Alene River.
Wetland Restoration
Following EPA's implementation of the phased remedial actions using settlement monies, the Coeur d'Alene
Basin Natural Resource Trustees, led by USFWS in cooperation with Ducks Unlimited, performed restoration
activities also using settlement monies. Restoration activities included:
• Planting of native upland and meadow grasses, shrubs and trees.
• Control of invasive species such as canary grass.
• Water management.
The Coeur d'Alene Basin Natural Resource Trustees are performing habitat management and long-term operation
and maintenance using settlement monies. This project demonstrates collaboration and coordination between
Superfund and the Natural Resource Trustees resulting in ecological revitalization of this site.
Wetland Team
Private property owner, U.S.
Fish and Wildlife Service
(USFWS), Ducks Unlimited,
Coeur d'Alene Basin Natural
Resource Trustees, U.S.
Army Corps of Engineers,
CH2M Hill, and EPA
4
Environmental Outcomes of the Wetland R
• Using settlement monies, EPA's remedial action established nearly 400 acres of clean waterfowl feeding
habitat and was followed by additional restoration work by the Natural Resource Trustees.
• The Superfund remediation reduced waterfowl exposure to toxic levels of heavy metals.
• USFWS monitoring data show that the remediated and
restored clean habitat is attracting some of the highest
levels of waterfowl usage, waterfowl feeding and
waterfowl diversity in the Coeur d'Alene River Basin.
• Blood lead data suggest that waterfowl using the
conservation easement are experiencing reduced
exposures to lead.
• Using native herbaceous plants, such as buckwheat, at
this site helped create an attractive habitat for wildlife
and pollinators.
• This project is the first of its kind in the Coeur d'Alene
River Basin, and is an important step in addressing
serious ecological contamination issues in the Basin.
• The property is owned by a private party, but the operations
ofthe wetland are performed under a conservation easement other wildlife such as bull elk also use the
that governs the land use. Due to the private ownership of remediated wetlands.
the land, it is not open to the public.
Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Black
Rock
Slough
Strobl
Marsh
Killarney Lake
JT
Lane Marsh
yi
Camp be I
Marsh
Hidden
Marsh
Ag ri c u 11 u re-to-W@t I arrd
Gonye rs ipn.Eas^imi
Momtt
Slough
Ag ri cujtu re-tolW.etland
n versi o n. We sti Riel
WA
ID MT
O 0 2,500 5,000 Feet
NORTH i i I I I
Sources: Esri, DeLorme, AND, Tele Atlas, First American, UNEP-WCMC, USGS.
Legend
"##- Union Pacific Railroad (now Trail of the Coeur d'Alenes) Agriculture-to-Wetland Conversion
Water Body ll II East Field
Marsh or Slough I I West Field
Agriculture to Wetland Map
Lessons Learned/Next Steps
1. Adaptive management on the hillsides revegetation gave flexibility to engage other approaches in areas
where performance was not satisfactory (e.g., switching lime from pelletized to a hydrated product after one
year).
2. Adaptive management reduced potential expenses on the hillsides revegetation.
3. Sikorsky S-64 air crane helicopters allowed application of the hydroseed mixture in a time- and cost-effective
manner. At the time of its execution, the hillsides revegetation proj ect was the largest of its type in the world
and it was the first significant project using air cranes for hydroseeding work. The success of the hillsides
revegetation demonstrated the feasibility of this technology which can lead to subsequent application of this
technology elsewhere.
4. Cooperation between various stakeholders, including the private land owner, was essential to supporting
cleanup efforts and the agriculture-to-wetland conversion.
5. Creating alternative safe habitat, particularly for migratory species to use while cleanup activities proceed,
redirects wildlife to safer areas.
6. Lead contamination from historical mining practices continues to pose a risk to people and the environment
in the area, especially children and sensitive species. EPA is working with many partner organizations to
help reduce this risk.
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Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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ECOLOGICAL REVITALIZATION OF CONTAMINATED SITES CASE STUDY
Additional Information
Websites to obtain additional information on the Bunker Hill Mining and Metallurgical Complex Superfund
site and ecological revitalization include the following:
EPA Region 10 Site Profile
http://vosemite.epa. gov/r 10/cleanup. nsf/sites/bh
EPA's Eco Tools Website
http: //www, clu-i n. org/ecotool s/
IDEQ Site Profile
http://www.deq.idaho.gov/bunkerhillsuperfundsite
Restoration Partnership
http: // restorati onpartner shi p. org/index. htm
Frequently Asked Questions About Ecological Revitalization of Superfund Sites
http ://www. clu-in. org/download/remed/542f06002. pdf
Contact Information
For additional information on the Bunker Hill Mining and Metallurgical Complex Superfund site, you can
also contact the EPA project managers:
Ed Moreen, EPA
(208) 664-4588
moreen.ed@epa.gov
Anne Dailey, EPA
(703) 347-0373
dailev.anne@epa.gov
Bunker Hill Mining and Metallurgical Complex, Idaho, Superfund Case Study
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