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Treatment plant at Minnesota Flats to treat AMD from the Richmond and Lawson Portals
Treatment plant at Minnesota Flats to treat AMD from the Richmond and Lawson Portals
The third in a series of images that shows inside of a portal that was cleaned early in the process.
The second in a series of images that shows inside of a portal that was cleaned early in the process.
The road leading to Iron Mountain Mine.
Tailings area by Richmond portal
The West Fork of Blackbird Creek diverted into a collection pond downstream of the tailings impoundment.
The top of the West Fork Tailing Facility, looking downstream
The top of the West Fork Tailing Facility, looking downstream.
The beginning of construction at one of the dams, as part of the remediation strategy.
The distinct blue in this image is caused by copper contamination, Bucktail Creek
The distinct blue in this image is caused by copper contamination, Bucktail Creek
Turning Basin, Elliott Bay
The restored bottom in the foreground of the picture.
The Save the Bay boat carries reporters to the transplant site.
The transplant team on the EPA boat after the transplant process.
The last in a series of images showing NOAA scientists at the 1997 transplant site just before transplanting the eelgrass turf.
The sixth in a series of images showing NOAA scientists at the 1997 transplant site just before transplanting the eelgrass turf.
The fifth in a series of images showing NOAA scientists at the 1997 transplant site just before transplanting the eelgrass turf.
The fourth in a series of images showing NOAA scientists at the 1997 transplant site just before transplanting the eelgrass turf.
The third in a series of images showing NOAA scientists at the 1997 transplant site just before transplanting the eelgrass turf.
The second in a series of images showing NOAA scientists at the 1997 transplant site just before transplanting the eelgrass turf.
The first in a series of images showing NOAA scientists at the 1997 transplant site just before transplanting the eelgrass turf
The third in a series of three images that illustrate the process of collecting donor eelgrass plants for transplant.
The second in a series of three images that illustrate the process of collecting donor eelgrass plants for transplant.
The first in a series of three images that illustrate the process of collecting donor eelgrass plants for transplant.
The crane lifts the culvert and places it in the area that was prepared to hold the new culvert.
The fourth image in this series shows the size of the culvert after it was placed where the main creek intersects the road
The second image that shows the construction phase of placing the new culvert at Sachuest Marsh
The first in a series of images that shows the construction phase of placing the new culvert at Sachuest Marsh
The old culvert prior to excavation on the upstream side of the road.
This image shows cutting through a water pipe that allowed workers to continue the restoration work.
The beginning of the excavation work to replace the culvert
Third Beach.
The healthy, undisturbed downstream portion of Sachuest Marsh.
The main tidal creek of Maidford River that enters Sachuest Marsh near Third Beach.
The main tidal creek of Maidford River that enters Sachuest Marsh near Third Beach.
Two University of Rhode Island scientists examine American lobster juveniles before they are tagged and released onto the reefs located around Dutch H
Two baby American lobsters in a "condo" lock claws
Two juvenile lobsters, Homarus americanus, begin to attack one another.
The average size cobble used in construction of the reef was 8"-12" in diameter and/or 12"-18" diameter stone
The reef construction operation.
The reef construction operation.
The barge with reef construction materials on board.
The crane and barge used to construct the cobble reef
The crane bucket moves from the barge to the water.
This is an image that shows Barren Island after the restoration work was completed
The crew discussing the filling of geotubes.
The restoration planting site at high tide.
Tampa Baywatch and NOAA staff observe the progress at the restoration site
The students use dibble bars to create holes to plant the smooth cordgrass, Spartina alterniflora, plants.
Tampa Bay high school volunteers arrive to begin the planting of smooth cordgrass, Spartina alterniflora, in the estuary
The restoration site after planting, during a high tide.
The planted area in the center of the island is one of the restoration sites planted using wetland nursery grown smooth cordgrass, Spartina alterniflo
This image shows the Spartina alterniflora plants in the center of the island
The surrounding shoreline and homes on Tampa Bay.
The shoreline around Tampa Bay.
Tampa Baywatch and McDill Airforce Base pontoon boats assist in the clean-up and rescue of entangled birds.
Three Brown Pelicans rest at the entrance to Maximo Park.
The Reefmaker, a vessel, and volunteers engaged in the clean-up.
The crew takes a lunch break during sampling.
The bottom of the crab pot bait well is filled with menhaden.
Trish Murphy takes measurements of the samples.
The sample catch coming on board, the fish in the net are mostly menhaden.
The bag from the net is emptied into the tote
The crew waits for the fyke nets to fish
Trish Murphy, formerly of NOAA, takes a secchi depth reading to determine water turbidity and how it relates to the ability of the fish to recognize t
The gillnet catch being hauled in.
The catch being brought in
The gillnet catch being hauled in.
The gillnet catch being brought in.
The gillnet catch being brought in
The catch being hauled in
The left hand portion of this image shows the natural marsh at Lake Barre, the foreground shows the newly planted S
This image shows the process of sediment deposition and was taken during construction
This image was taken after the oil spill but before restoration construction of the marsh platforms
This image was taken early in restoration and shows the Greenhill Oil Facility and the berm building process.
This image shows the sheen that occurred after the blow out
This image shows East Timbalier post hurricane Andrew, pre restoration.
This image shows the dredging process
The second season plants.
The second season plants.
The early stages of the newly planted restoration area.
The early stages of the newly planted restoration area, Trustees inspect.
The constructed marsh platform needed to be built to a specific elevation to support the marsh.
The constructed marsh platform ready for planting.
The constructed marsh platform ready for planting.
The pipeline running across the image is the dredge pipe that pumped sediment into the cells containing the dredge material
The pipeline running across the image is the dredge pipe that pumped sediment into the cells containing the dredge material
The restoration project underway.
The restoration work consisted of creating "cells" and then filling the cells with dredge materials that would then be planted to stabilize the sedime
The Bay side of East Timbalier Island, oiled sediments after the blowout.
This images shows the big gaps in East Timbalier Island left after Hurricane Andrew passed through the area on August 6, 1992
The Greenhill Oil Company headquarters.
The process of emptying quahogs into the rough waters of Narragansett Bay took hard work and a dedicated team of volunteers.
Two volunteers empty clams from the mother vessel into the waters of the spawner sanctuaries outside Greenwich Bay and Sakonnet River, RI.
The vessel used by RI DEM to inspect shellfish harvests.
The sun sets over Narragansett Bay, RI mid-spring.
The staging area at Greenwich Bay, RI
The first in the beginning of a series of photos that were taken while the DEM dredged and raked quahogs to determine suitable donor sites to take qua
Tall Grass near Arthur Kill Waterway, Richmond County
The auger that was used to plant the marsh grass plugs.
The Route 9 Bridge that crosses Army Creek just upstream from the tide gate
The path that leads to the tide gate at Army Creek.
Taken from the landfill looking upstream at Gambacorta.
The Army Creek landfill that was capped is in the upper-left hand corner of the image
The Delaware River at the outlet of Gambacorta Creek
The Gambacorta side of the tide gate, Gambacorta Creek is a tidal brackish creek.
The mud and sand flats of the Delaware River at the entrance to the tide gates
The tide gate from the riverside of Army Creek
The tide gate at the mouth of Army Creek on the Delaware side of the river
The septic systems of the homes on the edge of Quivett Creek marsh might have been threatened by the creation of an open channel between the two marsh
The watershed at Quivett Creek also features a beautiful old cemetery and a pond that is used by anadromous alewives for spawning and juvenile rearing
The degraded culvert that restricts water flow into the salt marsh at the Quivett Creek restoration site.
The Delaware River at Fort Mott, the bridge is the Delaware Memorial Bridge.
The Delaware side of the river, the Delaware Bridge is in the background.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
This project was conducted to determine if geotube material could be used to as suitable substrate for oyster spat.
top of Naomi Siphon
the existing siphon
Tribal fishermen on the Duwamish River.
The Seattle City Light property
The islands after the booms were placed to prevent infiltration of oil into the marsh habitats.
The third in a series of aerial images of Dixon Bay.
The second in a series of aerial images of Dixon Bay.
The first in a series of aerial images of Dixon Bay
The MV Columbus Iselin grounded on Looe Key in the Florida Keys National Marine Sanctuary in August 1994
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The introduction of toxins into the marine environment have drastic effects on the organisms that live there
The old beach at Point Au Fer.
The old beach at Point Au Fer.
The old beach at Point Au Fer.
The Mobile Oil facility off Mobile Canal.
This image shows the area cleared during the restoration
The principal investigator for this restoration project at Indian River lagoon works at cutting Brazilian Pepper out of the canopy.
The shoreline at Indian River Lagoon.
This image shows the big stumps of the Brazilian Peppers that have been cut to make way for mangroves
This area has been cleared of Brazilian Pepper to help the mangroves recolonize at the waterline.
The Indian River Lagoon provides prime estuarine habitat for native mangrove species.
The staging area at the Glade Bekken restoration site.
The spyder brings logs to the staging area at the Glade Bekken restoration site.
The new pipes that were used to replace the old culvert that inhibited coho and chum salmon from migrating to their spawning grounds.
Two men drive their horses into the stream to drop wood off at the restoration staging site.
The draft horses used to haul woody debris at the restoration site were gentle and beautiful as well as less costly than heavy machinery.
The seventh in a series of images that show the specialized "spyder" at work at the Glade Bekken restoration site
The sixth in a series of images that show the specialized "spyder" at work at the Glade Bekken restoration site
The fifth in a series of images that show the specialized "spyder" at work at the Glade Bekken restoration site
The fourth in a series of images that show the specialized "spyder" at work at the Glade Bekken restoration site
The third in a series of images that show the specialized "spyder" at work at the Glade Bekken restoration site
The second in a series of images that show the specialized "spyder" at work at the Glade Bekken restoration site
The first in a series of images that show the specialized "spyder" at work at the Glade Bekken restoration site
The old roadfill at the Glad Bekken restoration site
The pre-restored channel at the Glade Bekken restoration site.
The understory at Glade Bekken watershed is natural and desirable as spawning habitat for coho and chum salmon that are found in the streams in this w
The old fish ladder and pond at Parker River required constant maintenance and did not provide reliable access for anadromous fish to the spawning gro
The Alaskan Steep Pass fish ladder just before installation.
This image shows the height of the dam at Parker River before restoration
The completed notch in the dam just before placement of the ladder.
The crane lowers the ladder to the dam where it will be installed in a notched area designed to accommodate the ladder.
The ladder is suspended in air just before being placed in the dam.
The Alaskan Steep Pass arrives at the restoration site.
The owner of the property watches as the first piece of the ladder is fit into the dam.
Two workers guide the first section of the fish ladder into place.
The crane lowers the first section into place, it is just about to be dropped into the notched dam.
The first section of the fish passway is lowered and guided toward the notched area of the dam where it will be fitted into place and secured.
The dam before restoration, the drop creates a steep obstacle for anadromous fish returning to spawn.
The lip of the dam before restoration.
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