Indication of Unconventional Oil and Gas Wastewaters Found in Local Surface Waters
Class II Injection Well Wastewater Disposal Facility with Storage Tank
Scientist Collecting Water Samples at a Wastewater Disposal Facility
Evidence indicating the presence of wastewaters from unconventional oil and gas (UOG) production was found in surface waters and surficial sediments near an UOG disposal facility in West Virginia.
What They Did
Scientists from U.S. Geological Survey (USGS), Duke University, and the University of Missouri collaborated on a study as part of a larger effort to ascertain potential impacts of unconventional oil and gas (UOG) wastewaters to surface waters. Water samples were collected upstream and downstream from the UOG injection disposal site for analyses of inorganic chemicals that are associated with UOG wastewater. The disposal facility is known to handle both shale gas and coal bed methane wastewaters. In order to understand potential environmental health concerns, microbial communities were characterized in surficial sediments, and bioassays were used to determine endocrine disruption activity in surface waters.
What They Found
Scientists found evidence of UOG wastewaters in surface waters and sediments collected downstream from the disposal facility, specifically elevated concentrations of barium, bromide, calcium, chloride, sodium, lithium, strontium, which are known markers of UOG wastewater. Iron concentrations also increased and were in excess of West Virginia Department of Environmental Protection Agency water quality standard of one microgram per liter downstream of the UOG disposal facility. Microbial communities in downstream sediments had lower diversity and shifts in community composition compared to upstream locations, which could impact nutrient cycling due to altered microbial activity. Water samples adjacent to and downstream from the disposal facility exhibited evidence of endocrine disruption activity compared to upstream samples.
Environmental Health Considerations
These collaborative studies represent a first step to fill key data gaps in understanding the potential effects of UOG operations on surface water quality and environmental health. The results of these combined multidisciplinary studies provide evidence of changes to stream chemistry and potential concerns for environmental health at sites where disposal facilities are located adjacent to streams. Although most of the chemical levels were not high enough to cause immediate and lethal concerns for aquatic life, the observed changes in the microbial community and evidence of endocrine disrupting activity indicate potential adverse health outcomes for organisms living in or near the stream.
This research was funded by the USGS Ecosystems Mission Area’s Environmental Health Program (Contaminant Biology and Toxic Substances Hydrology) as well as USGS Energy Resources, Fisheries: Aquatic and Endangered Resources, National Water Quality, and Mendenhall Research Fellowship Programs. Funding was also provided by a University of Missouri, Mizzou Advantage Grant and a STAR Fellowship Assistance Agreement (no. FP-91747101) awarded by the U.S. Environmental Protection Agency.
Below are other science projects associated with this project.
Energy Integrated Science Team
Trace Levels of Organic Chemicals Limited to Local Reaches of a Stream near an Oil and Gas Wastewater Disposal Facility
USGS Scientist Receives Award for Assistance with National Wetlands Assessment
Examining Shifts in Stream Microbial Communities Exposed to Oil and Gas Wastewaters
Understanding Pathways of Unconventional Oil and Gas Produced Water Spills in the Environment
Fate and Effects of Wastes from Unconventional Oil and Gas Development
Microbiology and Chemistry of Waters Produced from Hydraulic Fracking—A Case Study
Disinfection Byproducts from Treatment of Produced Waters
Evidence indicating the presence of wastewaters from unconventional oil and gas (UOG) production was found in surface waters and surficial sediments near an UOG disposal facility in West Virginia.
What They Did
Scientists from U.S. Geological Survey (USGS), Duke University, and the University of Missouri collaborated on a study as part of a larger effort to ascertain potential impacts of unconventional oil and gas (UOG) wastewaters to surface waters. Water samples were collected upstream and downstream from the UOG injection disposal site for analyses of inorganic chemicals that are associated with UOG wastewater. The disposal facility is known to handle both shale gas and coal bed methane wastewaters. In order to understand potential environmental health concerns, microbial communities were characterized in surficial sediments, and bioassays were used to determine endocrine disruption activity in surface waters.
What They Found
Scientists found evidence of UOG wastewaters in surface waters and sediments collected downstream from the disposal facility, specifically elevated concentrations of barium, bromide, calcium, chloride, sodium, lithium, strontium, which are known markers of UOG wastewater. Iron concentrations also increased and were in excess of West Virginia Department of Environmental Protection Agency water quality standard of one microgram per liter downstream of the UOG disposal facility. Microbial communities in downstream sediments had lower diversity and shifts in community composition compared to upstream locations, which could impact nutrient cycling due to altered microbial activity. Water samples adjacent to and downstream from the disposal facility exhibited evidence of endocrine disruption activity compared to upstream samples.
Environmental Health Considerations
These collaborative studies represent a first step to fill key data gaps in understanding the potential effects of UOG operations on surface water quality and environmental health. The results of these combined multidisciplinary studies provide evidence of changes to stream chemistry and potential concerns for environmental health at sites where disposal facilities are located adjacent to streams. Although most of the chemical levels were not high enough to cause immediate and lethal concerns for aquatic life, the observed changes in the microbial community and evidence of endocrine disrupting activity indicate potential adverse health outcomes for organisms living in or near the stream.
This research was funded by the USGS Ecosystems Mission Area’s Environmental Health Program (Contaminant Biology and Toxic Substances Hydrology) as well as USGS Energy Resources, Fisheries: Aquatic and Endangered Resources, National Water Quality, and Mendenhall Research Fellowship Programs. Funding was also provided by a University of Missouri, Mizzou Advantage Grant and a STAR Fellowship Assistance Agreement (no. FP-91747101) awarded by the U.S. Environmental Protection Agency.
Below are other science projects associated with this project.