Biogeochemical Controls on Technetium Mobility in Biogeochemical Controls on Technetium Mobility in FRC Sediments
Abstract
Technetium-99 is a priority pollutant at numerous DOE sites, due to its long half-life (2.1 x 10{sup 5} years), high mobility as Tc(VII) in oxic waters, and bioavailability as a sulfate analog. {sup 99}Tc is far less mobile under anaerobic conditions, forming insoluble Tc(IV) precipitates. As anaerobic microorganisms can reduce soluble Tc(VII) to insoluble Tc(IV), microbial metabolism may have the potential to treat sediments and waters contaminated with Tc. Baseline studies of fundamental mechanisms of Tc(VII) bioreduction and precipitation (reviewed by Lloyd et al, 2002) have generally used pure cultures of metal-reducing bacteria, in order to develop conceptual models for the biogeochemical cycling of Tc. There is, however, comparatively little known about interactions of metal-reducing bacteria with environmentally relevant trace concentrations of Tc, against a more complex biogeochemical background provided by mixed microbial communities in the subsurface. The objective of this new NABIR project is to probe the site specific biogeochemical conditions that control the mobility of Tc at the FRC (Oak Ridge, TN). This information is required for the rational design of in situ bioremediation strategies for technetium-contaminated subsurface environments. We will use a combination of geochemical, mineralogical, microbiological and spectroscopic techniques to determine the solubility and phase associationsmore »
- Authors:
- Publication Date:
- Research Org.:
- University of Manchester, UK; University of Leeds, UK
- Sponsoring Org.:
- USDOE Office of Science (SC)
- OSTI Identifier:
- 895388
- Report Number(s):
- CONF-NABIR2004-35
TRN: US0700455
- Resource Type:
- Conference
- Resource Relation:
- Conference: Annual NABIR PI Meeting, March 15-17, 2004, Warrenton, VA
- Country of Publication:
- United States
- Language:
- English
- Subject:
- 38 RADIATION CHEMISTRY, RADIOCHEMISTRY, AND NUCLEAR CHEMISTRY; 54 ENVIRONMENTAL SCIENCES; 59 BASIC BIOLOGICAL SCIENCES; ANAEROBIC CONDITIONS; BACTERIA; BIOREMEDIATION; COMMUNITIES; DESIGN; HALF-LIFE; METABOLISM; MICROORGANISMS; POLLUTANTS; PRECIPITATION; PROBES; SEDIMENTS; SOLUBILITY; SULFATES; TECHNETIUM; TECHNETIUM 99
Citation Formats
Lloyd, J R, McBeth, J M, Livens, F R, Bryan, N D, Ellis, B, Sharma, H, Burke, I T, and Morris, K. Biogeochemical Controls on Technetium Mobility in Biogeochemical Controls on Technetium Mobility in FRC Sediments. United States: N. p., 2004.
Web.
Lloyd, J R, McBeth, J M, Livens, F R, Bryan, N D, Ellis, B, Sharma, H, Burke, I T, & Morris, K. Biogeochemical Controls on Technetium Mobility in Biogeochemical Controls on Technetium Mobility in FRC Sediments. United States.
Lloyd, J R, McBeth, J M, Livens, F R, Bryan, N D, Ellis, B, Sharma, H, Burke, I T, and Morris, K. 2004.
"Biogeochemical Controls on Technetium Mobility in Biogeochemical Controls on Technetium Mobility in FRC Sediments". United States. https://www.osti.gov/servlets/purl/895388.
@article{osti_895388,
title = {Biogeochemical Controls on Technetium Mobility in Biogeochemical Controls on Technetium Mobility in FRC Sediments},
author = {Lloyd, J R and McBeth, J M and Livens, F R and Bryan, N D and Ellis, B and Sharma, H and Burke, I T and Morris, K},
abstractNote = {Technetium-99 is a priority pollutant at numerous DOE sites, due to its long half-life (2.1 x 10{sup 5} years), high mobility as Tc(VII) in oxic waters, and bioavailability as a sulfate analog. {sup 99}Tc is far less mobile under anaerobic conditions, forming insoluble Tc(IV) precipitates. As anaerobic microorganisms can reduce soluble Tc(VII) to insoluble Tc(IV), microbial metabolism may have the potential to treat sediments and waters contaminated with Tc. Baseline studies of fundamental mechanisms of Tc(VII) bioreduction and precipitation (reviewed by Lloyd et al, 2002) have generally used pure cultures of metal-reducing bacteria, in order to develop conceptual models for the biogeochemical cycling of Tc. There is, however, comparatively little known about interactions of metal-reducing bacteria with environmentally relevant trace concentrations of Tc, against a more complex biogeochemical background provided by mixed microbial communities in the subsurface. The objective of this new NABIR project is to probe the site specific biogeochemical conditions that control the mobility of Tc at the FRC (Oak Ridge, TN). This information is required for the rational design of in situ bioremediation strategies for technetium-contaminated subsurface environments. We will use a combination of geochemical, mineralogical, microbiological and spectroscopic techniques to determine the solubility and phase associations of Tc in FRC sediments, and characterize the underpinning biogeochemical controls. A key strength of this project is that many of the techniques we are using have already been optimized by our research team, who are also studying the biogeochemical controls on Tc mobility in marine and freshwater sediments in the UK in a NERC funded companion study.},
doi = {},
url = {https://www.osti.gov/biblio/895388},
journal = {},
number = ,
volume = ,
place = {United States},
year = {Wed Mar 17 00:00:00 EST 2004},
month = {Wed Mar 17 00:00:00 EST 2004}
}