about
Watershed-scale fungal community characterization along a pH gradient in a subsurface environment cocontaminated with uranium and nitrate.Characterization of archaeal community in contaminated and uncontaminated surface stream sediments.Mercury and other heavy metals influence bacterial community structure in contaminated Tennessee streamsA limited microbial consortium is responsible for extended bioreduction of uranium in a contaminated aquiferA spreadsheet program for two-well tracer test data analysis.Rhodanobacter denitrificans sp. nov., isolated from nitrate-rich zones of a contaminated aquifer.Denitrifying bacteria from the genus Rhodanobacter dominate bacterial communities in the highly contaminated subsurface of a nuclear legacy waste site.Dynamic Succession of Groundwater Functional Microbial Communities in Response to Emulsified Vegetable Oil Amendment during Sustained In Situ U(VI) Reduction.Natural bacterial communities serve as quantitative geochemical biosensors.Microbial- and thiosulfate-mediated dissolution of mercury sulfide minerals and transformation to gaseous mercury.Genome sequences for six Rhodanobacter strains, isolated from soils and the terrestrial subsurface, with variable denitrification capabilities.Genome sequences for three denitrifying bacterial strains isolated from a uranium- and nitrate-contaminated subsurface environmentFate and transport of uranium (VI) in weathered saprolite.Physicochemical and mineralogical characterization of soil-saprolite cores from a field research site, Tennessee.Prediction of uranium and technetium sorption during titration of contaminated acidic groundwater.Influence of hydrological and geochemical processes on the transport of chelated metals and chromate in fractured shale bedrock.U(VI) adsorption to heterogeneous subsurface media: application of a surface complexation model.Kinetic analysis and modeling of oleate and ethanol stimulated uranium (VI) bio-reduction in contaminated sediments under sulfate reduction conditions.In situ bioremediation of uranium with emulsified vegetable oil as the electron donor.Geochemical modeling of reactions and partitioning of trace metals and radionuclides during titration of contaminated acidic sediments.Influence of soil geochemical and physical properties on chromium(VI) sorption and bioaccessibility.pH-Dependent fate and transport of NTA-complexed cobalt through undisturbed cores of fractured shale saprolite.U(VI) bioreduction with emulsified vegetable oil as the electron donor--microcosm tests and model development.Inhibition of bacterial U(VI) reduction by calcium.Prediction of aluminum, uranium, and co-contaminants precipitation and adsorption during titration of acidic sediments.Kinetics of Methylmercury Production Revisited.A reaction-based paradigm to model reactive chemical transport in groundwater with general kinetic and equilibrium reactions.Long-term electrical resistivity monitoring of recharge-induced contaminant plume behavior.Sources of mercury in a contaminated stream--implications for the timescale of recovery.Seasonal and flow-driven dynamics of particulate and dissolved mercury and methylmercury in a stream impacted by an industrial mercury source.Estimating kinetic mass transfer by resting-period measurements in flow-interruption tracer tests.Estimating reaction rate coefficients within a travel-time modeling framework.Hg isotopes reveal in-stream processing and legacy inputs in East Fork Poplar Creek, Oak Ridge, Tennessee, USA.Periphyton Biofilms Influence Net Methylmercury Production in an Industrially Contaminated System.Formation of aqueous MgUO2(CO3)3(2-) complex and uranium anion exchange mechanism onto an exchange resin.History of mercury use and environmental contamination at the Oak Ridge Y-12 Plant.Gold nanorods for surface Plasmon resonance detection of mercury (II) in flow injection analysisIdentification of Multiple Mercury Sources to Stream Sediments near Oak Ridge, TN, USAU(VI) Bioreduction with Emulsified Vegetable Oil as the Electron Donor – Model Application to a Field TestBacterial growth phase influences methylmercury production by the sulfate-reducing bacterium Desulfovibrio desulfuricans ND132
P50
Q31147141-DE95F892-5EF0-4163-AE07-826C0D35A109Q33666980-B5E9CC70-8738-4C39-A861-9005E8C5CA2FQ33740511-B2340106-E6EE-41AA-81D4-986A8C86C197Q33963355-D2F487AC-8A64-47E9-A568-873979529EBBQ33974078-2E6B5285-E6E6-4373-AFF6-A85FAC2C83C5Q34090798-AC08629B-07D5-4DB2-BB4C-82101930315FQ34104645-6DC2DE0D-CE41-451F-8EA9-89D0EE762258Q35599389-E7547F96-B8DF-47B8-B7FA-E90C1D32BE94Q35620211-00B2C7B4-CEB2-4AAF-B563-68FE501753C2Q35686762-547BE493-35FA-4F88-B3E5-5C26FDD8AB3CQ36155281-1BB1F17F-937C-4AAF-90DE-2FAC9F868526Q36989365-76582E5B-33AA-4627-9CE7-B27A7D91ABC5Q38431179-21FE4778-27DE-4D97-ADF0-A3882D44F127Q38509219-87FAF571-2959-4934-863F-CA49505A7DCEQ39905035-D424C74B-CC0D-493B-BF0B-7EC37E72E497Q40641590-DA56CAC1-81BC-4964-B8D8-D3D371034E35Q40650249-E8BA2FF0-DD33-4AE6-95EB-8AA1D1BAEC12Q42940389-04AB4943-7E94-4E46-AF20-C16D14752C9BQ43831960-E9C0A876-282A-4852-8D33-9304909756A0Q43853617-A4E314F9-882C-4908-BF2B-8AB78CD6AAE2Q44098266-F671EB3E-9462-4523-BC59-37395D560286Q44194538-94826C78-07B8-4B11-8FCD-B129A0C6A5F9Q44270855-5659823D-D1F7-412C-9310-8AEA66B5A896Q44458820-748CA9E8-F157-47D8-B1FA-3C8154D0C661Q46439760-56676047-3840-4FB4-B846-3681521DF6E9Q48153601-97A25C8A-F6EA-43D8-98A2-EEF239F7B9BEQ51083176-B2CBF434-965A-40F3-B795-B746A5FFB9EFQ51196829-A2542BEA-E918-4264-97DD-A4672DBD82D4Q51202702-58E75A6E-A58F-4B00-885F-F1D505CFC844Q51294207-40D9A345-D65B-41FC-B58B-EF8A5377D001Q51678951-B42569E1-381D-4C5D-9F68-9B777A627174Q51724103-C9BCEE8E-0129-4B27-AA8F-CA5CD82108B9Q51742539-A4252456-9113-48C9-A03A-F82CA7BB53F9Q51768037-FBD648F3-9A33-4088-A6A6-E7F6E5154FC9Q51888528-00BB8CE3-A465-4FFC-A0AE-1D0CCF07EAA8Q53062678-E85FE28A-537F-4278-84F1-98B6C46F7CF2Q56939987-1B725155-2FB7-4E6F-87F9-21D656FD10DCQ56939991-50CD6635-24FB-491B-9190-3F2402AF7618Q56940029-1D7381E6-0C4A-42C9-9CB1-986E9F98FF50Q56940045-8F3B2270-203F-4F31-BAE9-19EF262A954F
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Scott C. Brooks
@ast
Scott C. Brooks
@en
Scott C. Brooks
@es
Scott C. Brooks
@nl
Scott C. Brooks
@sl
type
label
Scott C. Brooks
@ast
Scott C. Brooks
@en
Scott C. Brooks
@es
Scott C. Brooks
@nl
Scott C. Brooks
@sl
prefLabel
Scott C. Brooks
@ast
Scott C. Brooks
@en
Scott C. Brooks
@es
Scott C. Brooks
@nl
Scott C. Brooks
@sl
P1053
B-9439-2012
P106
P1153
7401651290
P21
P31
P3829
P496
0000-0002-8437-9788