Microbiology and Chemistry of Waters Produced from Hydraulic Fracking—A Case Study Completed
Anaerobic Microbial Cultures from Shale Gas Production Waters
A new U.S. Geological Survey (USGS) study determined that the microbiology and organic chemistry of produced waters varied widely among hydraulically fractured shale gas wells in north-central Pennsylvania.
Hydraulically fractured shales are an increasingly important source of natural gas production in the United States. This process has been known to create up to 420,000 gallons of produced water per well per day, consisting of a mixture of injected fracturing fluids and natural formation waters, for Marcellus shale wells. These large volumes of water are a waste product that present water management challenges, and operators are reusing these fluids more often in order to reduce the amount of wastewater requiring disposal.
The USGS initiated a case study in 2012 to understand the chemical and microbiological composition of produced waters. Scientists measured inorganic compounds (for example, sodium, chloride, barium, bromide, calcium, and strontium) and volatile organic compounds (VOCs) and characterized the microbiology of produced waters from 13 hydraulically fractured shale gas wells in north-central Pennsylvania.
The scientists determined that inorganic compounds were broadly similar among the wells. In contrast, there were variations in VOCs detected and microbial populations present. VOCs (benzene, toluene, tetrachloroethylene) were detected in four produced water samples at concentrations ranging from less than 1 to 11.7 micrograms per liter, although the sources (natural or industrially derived) are not clear.
Some wells were hotspots for microbial activity, which seemed to be associated with concentrations of specific organic compounds (for example, benzene or acetate, which some microbes metabolize). The connection between the presence of organic compounds and the detection of microbes was not, in itself, surprising. Many organic compounds used as hydraulic fracturing fluid additives are biodegradable and thus could have supported microbial activity at depth during shale gas production.
Variations in microbial characteristics and VOCs of the wells followed no obvious spatial pattern but may be linked to the time during which a well was in production. The VOCs from the produced waters of the tested wells could play a role in the management of produced waters, particularly since VOCs, such as benzene, may be a health concern around the well or a holding pond.
Microbes could also serve to help mitigate the effects of organic contaminants during the disposal or accidental release of produced waters. Additional research is needed to fully assess how microbial activity can most effectively be utilized to biodegrade organic compounds found in produced waters.
This research was funded by the USGS Ecosystems Mission Area’s Environmental Health Program (Contaminant Biology and Toxic Substances Hydrology) Hydrologic Research and Development, and Energy Resources Programs.
Below are other science projects associated with this project.
Energy Integrated Science Team
Quantities of water associated with oil and gas development
Trace Levels of Organic Chemicals Limited to Local Reaches of a Stream near an Oil and Gas Wastewater Disposal Facility
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
Indication of Unconventional Oil and Gas Wastewaters Found in Local Surface Waters
Fate and Effects of Wastes from Unconventional Oil and Gas Development
Pipeline Crude Oil Spill Still a Cleanup Challenge after 30 Years
Ground-Water Recharge Affects Fate of Petroleum Contaminant Plumes
- Overview
A new U.S. Geological Survey (USGS) study determined that the microbiology and organic chemistry of produced waters varied widely among hydraulically fractured shale gas wells in north-central Pennsylvania.
Sources/Usage: Some content may have restrictions. View Media DetailsUSGS scientists did laboratory experiments to assess the microbial activity of produced waters from hydraulically fractured shale gas wells in north-central Pennsylvania. Shown are bottles containing cultures of hydrogen sulfide-producing bacteria enriched from shale gas-produced waters. The black color denotes the presence of insoluble iron sulfide minerals, an indicator of bacterial sulfide production. The clear culture on the right is an uninoculated control sample. Photo Credit: Darren S. Dunlap, USGS. Hydraulically fractured shales are an increasingly important source of natural gas production in the United States. This process has been known to create up to 420,000 gallons of produced water per well per day, consisting of a mixture of injected fracturing fluids and natural formation waters, for Marcellus shale wells. These large volumes of water are a waste product that present water management challenges, and operators are reusing these fluids more often in order to reduce the amount of wastewater requiring disposal.
The USGS initiated a case study in 2012 to understand the chemical and microbiological composition of produced waters. Scientists measured inorganic compounds (for example, sodium, chloride, barium, bromide, calcium, and strontium) and volatile organic compounds (VOCs) and characterized the microbiology of produced waters from 13 hydraulically fractured shale gas wells in north-central Pennsylvania.
Sources/Usage: Public Domain. View Media DetailsThe concentration of total dissolved solids in milligrams per liter (mg/L) (A) and concentration of three volatile organic compounds (benzene, toluene, and tetrachloroethylene) in micrograms per liter (µg/L) (B) in the produced waters USGS scientists collected from 13 shale gas wells in north central Pennsylvania. Graph modified from Akob and others, 2015. The scientists determined that inorganic compounds were broadly similar among the wells. In contrast, there were variations in VOCs detected and microbial populations present. VOCs (benzene, toluene, tetrachloroethylene) were detected in four produced water samples at concentrations ranging from less than 1 to 11.7 micrograms per liter, although the sources (natural or industrially derived) are not clear.
Some wells were hotspots for microbial activity, which seemed to be associated with concentrations of specific organic compounds (for example, benzene or acetate, which some microbes metabolize). The connection between the presence of organic compounds and the detection of microbes was not, in itself, surprising. Many organic compounds used as hydraulic fracturing fluid additives are biodegradable and thus could have supported microbial activity at depth during shale gas production.
Variations in microbial characteristics and VOCs of the wells followed no obvious spatial pattern but may be linked to the time during which a well was in production. The VOCs from the produced waters of the tested wells could play a role in the management of produced waters, particularly since VOCs, such as benzene, may be a health concern around the well or a holding pond.
Microbes could also serve to help mitigate the effects of organic contaminants during the disposal or accidental release of produced waters. Additional research is needed to fully assess how microbial activity can most effectively be utilized to biodegrade organic compounds found in produced waters.
This research was funded by the USGS Ecosystems Mission Area’s Environmental Health Program (Contaminant Biology and Toxic Substances Hydrology) Hydrologic Research and Development, and Energy Resources Programs.
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Below are other science projects associated with this project.
Energy Integrated Science Team
The Energy Lifecycle Integrated Science Team focuses on the potential for contaminant exposures in the environment that might originate from energy resource activities including, extraction, production, transportation, storage, extraction, waste management and restoration. Perceived health risks to humans and other organisms will be distinguished from actual risks, if any. If actual risks are...Quantities of water associated with oil and gas development
Work in this task of the Oil and Gas Waters Project focuses on quantifying the water used during hydrocarbon development and the water produced along with oil and gas. Hydraulic fracturing is an integral part of oil and gas development in many areas, and water use for this purpose has increased considerably in the last decade. Water produced from petroleum reservoirs includes hydraulic fracturing...Trace Levels of Organic Chemicals Limited to Local Reaches of a Stream near an Oil and Gas Wastewater Disposal Facility
Organic contaminants that were present in Wolf Creek near a wastewater disposal facility were not evident farther downstream where Wolf Creek enters the New River. Wolf Creek and the New River are used for drinking water and recreational purposes.Examining Shifts in Stream Microbial Communities Exposed to Oil and Gas Wastewaters
Shifts in the overall microbial community structure were present in stream sediments that contained chemicals associated with unconventional oil and gas wastewaters. This work is part of a long-term study designed to understand persistence of chemicals from oil and gas wastewaters in sediments and water and how those factors might be related to exposures and adverse health effects, if any, on...Understanding Pathways of Unconventional Oil and Gas Produced Water Spills in the Environment
A new study measures the transport of chemicals associated with unconventional oil and gas (UOG) produced waters downstream from a pipeline leak in North Dakota. This work is part of a long-term study designed to understand chemical persistence in sediments and water and how those factors might be related to contaminant exposures and associated with adverse health effects, if any, on organisms.Indication of Unconventional Oil and Gas Wastewaters Found in Local Surface 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.Fate and Effects of Wastes from Unconventional Oil and Gas Development
This study is assessing the environmental health risks associated with wastes from unconventional oil and gas development by characterizing waste materials, identifying potential environmental pathways, and evaluating the potential effects on organisms from exposure to unintended waste releases.Pipeline Crude Oil Spill Still a Cleanup Challenge after 30 Years
Research at a 1979 crude oil spill from a ruptured pipeline has exposed and helped to overcome many challenges facing an effective, cost-efficient cleanup of crude oil, U.S. Geological Survey (USGS) scientists have found. The environmental release of crude oil occurred near Bemidji, Minnesota.Ground-Water Recharge Affects Fate of Petroleum Contaminant Plumes
U.S. Geological Survey (USGS) scientists have discovered that rainwater recharging the water table above petroleum contamination plumes affects how plumes grow and the rate that petroleum products (in this case crude oil) degrade and weather in ground water. The amount of recharge affects the migration of oil in the subsurface, how chemicals dissolve from the oil into ground water, and the... - Publications
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