about
A catalytic beacon sensor for uranium with parts-per-trillion sensitivity and millionfold selectivityImpacts on microbial communities and cultivable isolates from groundwater contaminated with high levels of nitric acid-uranium waste.Composition and diversity of microbial communities recovered from surrogate minerals incubated in an acidic uranium-contaminated aquifer.Watershed-scale fungal community characterization along a pH gradient in a subsurface environment cocontaminated with uranium and nitrate.Changes in bacterial community structure correlate with initial operating conditions of a field-scale denitrifying fluidized bed reactor.Environmental whole-genome amplification to access microbial populations in contaminated sediments.Microbial communities in contaminated sediments, associated with bioremediation of uranium to submicromolar levels.Bacterial community succession during in situ uranium bioremediation: spatial similarities along controlled flow paths.Treatment of nitric acid-, U(VI)-, and Tc(VII)-contaminated groundwater in intermediate-scale physical models of an in situ biobarrier.GeoChip-based analysis of functional microbial communities during the reoxidation of a bioreduced uranium-contaminated aquifer.Metagenomic insights into evolution of a heavy metal-contaminated groundwater microbial community.Effects of nitrate on the stability of uranium in a bioreduced region of the subsurface.Denitrifying bacteria isolated from terrestrial subsurface sediments exposed to mixed-waste contamination.Dynamics of microbial community composition and function during in situ bioremediation of a uranium-contaminated aquiferA limited microbial consortium is responsible for extended bioreduction of uranium in a contaminated aquiferRhodanobacter 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.Pilot-scale in situ bioremedation of uranium in a highly contaminated aquifer. 2. Reduction of u(VI) and geochemical control of u(VI) bioavailability.Linking specific heterotrophic bacterial populations to bioreduction of uranium and nitrate in contaminated subsurface sediments by using stable isotope probingDynamic 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.Gene Expression Correlates with Process Rates Quantified for Sulfate- and Fe(III)-Reducing Bacteria in U(VI)-Contaminated SedimentsFunctional diversity and electron donor dependence of microbial populations capable of U(VI) reduction in radionuclide-contaminated subsurface sediments.Genome sequences for three denitrifying bacterial strains isolated from a uranium- and nitrate-contaminated subsurface environmentPhysicochemical and mineralogical characterization of soil-saprolite cores from a field research site, Tennessee.Distribution of uranium contamination in weathered fractured saprolite/shale and ground water.Formation of Soluble Mercury Oxide Coatings: Transformation of Elemental Mercury in Soils.Prediction of uranium and technetium sorption during titration of contaminated acidic groundwater.Utilization of microbial biofilms as monitors of bioremediation.Kinetic analysis and modeling of oleate and ethanol stimulated uranium (VI) bio-reduction in contaminated sediments under sulfate reduction conditions.Responses of microbial community functional structures to pilot-scale uranium in situ bioremediation.Uranium transformations in static microcosms.Sequestering uranium and technetium through co-precipitation with aluminum in a contaminated acidic environment.A nested-cell approach for in situ remediation.Pilot-scale in situ bioremediation of uranium in a highly contaminated aquifer. 1. Conditioning of a treatment zone.Uranium removal from contaminated groundwater by synthetic resins.Microbiological characteristics in a zero-valent iron reactive barrier.Mass-transfer limitations for nitrate removal in a uranium-contaminated aquifer.In situ bioremediation of uranium with emulsified vegetable oil as the electron donor.U(VI) bioreduction with emulsified vegetable oil as the electron donor--microcosm tests and model development.
P50
Q28287117-DA162C14-BFE5-4D1E-BED3-94B899446AE1Q30804300-1F729D52-C18F-4E16-BE12-D8771E2884D3Q31118724-F1585683-1E36-46A0-8D79-A003AED72AF3Q31147141-530D07D2-837C-45E8-90E2-4057793FEDEEQ33227348-3CB02559-2243-4ED9-A389-F41658B83749Q33242144-0C901539-ED1B-4BF7-BFEB-4B87F3D48490Q33331708-8322E3C1-3088-489F-A076-F89867B3A2BBQ33366399-A2A50FFC-DE6F-4981-9FF4-A38B71C8F7A3Q33430396-BB2D46CD-CE98-46FC-9231-8563FF3FD117Q33485498-2D23E160-5969-4B7F-BC32-295ED94F88A8Q33534155-A26AC2E6-B834-407A-9067-E71A76084EB8Q33596214-3060DFF2-908B-401C-9CE0-2960FA817FE6Q33847696-E660602A-84E9-4243-AD77-BC0B85EE543CQ33875198-2B51C126-BDA0-40EB-89C1-20F2C593A8E6Q33963355-8029E062-9E73-4763-8E67-A59AD544B623Q34090798-8B473F1C-E126-4E92-9117-04DF1A3D2F53Q34104645-7B629D06-72B4-4455-B4D3-A4A9383B9323Q34546117-CAE646B6-BBB0-419D-A1F5-14788FD8ED48Q35530144-F09C50BA-5F3E-448E-9CF3-203E705D2C64Q35599389-C51FF769-90B6-4012-A130-6AF40EDAAE05Q35620211-5888B5AF-DE6C-4E1A-AC7D-01DD336C268EQ36151444-F963ADDF-BA23-49BC-AF64-87A63A881E12Q36672703-1CE8BD55-25DD-4749-A4EB-F0C04B9991DCQ36989365-D5FEED95-7C15-4D37-8B59-3C0D7F83D4CDQ38509219-454F8DEB-1C27-42D2-8C45-A8D3903BEB10Q38509225-BBC833D3-8F21-4C39-ABF4-100B26A87FDFQ38961875-32B6CC3D-1CD3-4F78-85C9-EA7109611A07Q39905035-0E2D393D-E0FC-4F29-8865-1CD566E394ADQ41463632-6E8106C4-5C96-425F-B2A8-4A69E309BE59Q42940389-2B3F2481-7928-4636-9156-2A9151399ADAQ43125790-08B2FA3F-A738-4416-AD08-EDC7166EB070Q43230917-391A3A00-DCD0-4DDB-BBCA-D4F782EC803DQ43256827-68646501-49B9-425D-AD38-8CA4EDCC6C3FQ43333210-BB49B5BE-A15F-4DEA-A624-1080F860EE6AQ43336736-3A9AAF72-A82B-42D6-A0ED-A9636940C5C6Q43351059-6A074507-D7C9-4169-8B09-7B5F0954D37EQ43355659-CF7FC602-5B24-4478-B204-8EE365C6AB12Q43696133-921B69B7-27A6-49AA-BFA5-D6AD14BAB5BEQ43831960-040AC8BF-9E28-4C67-A9B0-98745FBB7703Q44270855-3AB5EC61-77EC-4C28-A086-C8F0D4C09C45
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
David Watson
@ast
David Watson
@en
David Watson
@es
David Watson
@nl
David Watson
@sl
type
label
David Watson
@ast
David Watson
@en
David Watson
@es
David Watson
@nl
David Watson
@sl
prefLabel
David Watson
@ast
David Watson
@en
David Watson
@es
David Watson
@nl
David Watson
@sl
P1053
C-3256-2016
P106
P21
P31
P3829
P496
0000-0002-4972-4136