A new three-year study involving University of Tennessee-Oak Ridge National Laboratory Governor’s Chair for Environmental Biotechnology Terry Hazen will look at how aquatic microbial communities are impacted by biocides associated with hydraulic fracking.
Fracking uses water to displace and retrieve natural gas
Much is unknown about how it affects water
Hazen is using microbial studies to gain understanding
In the News: UT fracking study to break new ground, may lead to antibiotic-resistant microbes
“Fracking is something that has really changed the energy industry, but its environmental impacts are largely disputed,” said Hazen, head of the Methane Center in UT’s Institute for a Secure and Sustainable Environment and joint UT-Oak Ridge National Laboratory Governor’s Chair for Environmental Biotechnology. “For example, biocides are used to help keep machinery and equipment protected against microbial corrosion, but that exposure can make the microbes resistant to the chemicals.”
Led by Gina Lamanendalla, Steve Techtmann, and Maria Campa, the project will look at how microbial communities are affected and consider the possibility of alternative biocides while ensuring that fracking can continue to be used to gain natural resources. Lamanendalla and Techtmann are former postdoctoral fellows of Hazen’s who are now faculty members at Juniata College and Michigan Technological University, respectively. Campa is a postdoctoral fellow with Hazen in the Methane Center.
Hazen’s team wants to clarify whether the use of biocides could lead to antibiotic-resistant strains of microbes, what the impact of the biocides is on the overall environment, and help pinpoint biocides that can continue to be used with greatest effect on equipment and the least impact on environment.
The study will specifically observe a set of streams in Pennsylvania that are near active hydro fracking sites. Those will be compared to streams not within active fracking areas.
Additionally, Hazen’s team hopes to look at what systems, biologically speaking, actively resist biocides and biocide-resistant strains.
“We’ll conduct our study over many years to help give us a better picture of what the long-term impact might be,” Hazen said. “This work could help develop future contamination-detection techniques.”
The project is backed by the National Science Foundation, with funding set to run through summer 2021.
David Goddard (865-974-0683, firstname.lastname@example.org)