about
Functional diversity of bacteria in a ferruginous hydrothermal sediment.Characterization of microbial communities in heavy crude oil from Saudi Arabia.The impact of gamma radiation on sediment microbial processes.Microbial reduction of Fe(III) under alkaline conditions relevant to geological disposal.Treatment of Alkaline Cr(VI)-Contaminated Leachate with an Alkaliphilic Metal-Reducing Bacterium.Probing the biogeochemical behavior of technetium using a novel nuclear imaging approach.Role of nitrate in conditioning aquifer sediments for technetium bioreduction.Reactive azo dye reduction by Shewanella strain J18 143.Molecular analysis of a sulphate-reducing consortium used to treat metal-containing effluents.Geomicrobiological redox cycling of the transuranic element neptunium.Reoxidation behavior of technetium, iron, and sulfur in estuarine sediments.Effects of progressive anoxia on the solubility of technetium in sediments.Role of metal-reducing bacteria in arsenic release from Bengal delta sediments.Microbially mediated reduction of Np(V) by a consortium of alkaline tolerant Fe(III)-reducing bacteriaNeptunium and manganese biocycling in nuclear legacy sediment systemsThe interactions of strontium and technetium with Fe(II) bearing biominerals: Implications for bioremediation of radioactively contaminated landAlkaline Fe(III) reduction by a novel alkali-tolerant Serratia sp. isolated from surface sediments close to Sellafield nuclear facility, UKThe Synergistic Effects of High Nitrate Concentrations on Sediment BioreductionMicrobial Communities Associated with the Oxidation of Iron and Technetium in Bioreduced SedimentsAn X-ray absorption study of the fate of technetium in reduced and reoxidised sediments and mineral phasesMicrobial impacts on 99m Tc migration through sandstone under highly alkaline conditions relevant to radioactive waste disposalBiogenic methane in shale gas and coal bed methane: A review of current knowledge and gapsDo mature hydrocarbons have an influence on acid rock drainage generation?Microbial degradation of isosaccharinic acid under conditions representative for the far field of radioactive waste disposal facilitiesMicrobial selenium transformations in seleniferous soilsSeasonal Changes In Mineralogy, Geochemistry and Microbial Community of Bacteriogenic Iron Oxides (BIOS) Deposited in a Circumneutral WetlandCharacterisation of organic matter and microbial communities in contrasting arsenic-rich Holocene and arsenic-poor Pleistocene aquifers, Red River Delta, VietnamBiogeochemical behaviour of plutonium during anoxic biostimulation of contaminated sedimentsGeochemical and Microbial Controls of the Decomposition of Depleted Uranium in the Environment: Experimental Studies using Soil MicroorganismsMicrobial and geochemical features suggest iron redox cycling within bacteriogenic iron oxide-rich sedimentsBiogeochemical Controls on the Corrosion of Depleted Uranium Alloy in Subsurface SoilsCorrosion and Fate of Depleted Uranium Penetrators under Progressively Anaerobic Conditions in Estuarine SedimentIdentification and characterization of a novel acidotolerant Fe(III)-reducing bacterium from a 3000-year-old acidic rock drainage siteArsenate detoxification in a Pseudomonad hypertolerant to arsenicMicrocosm depth profiles of arsenic release in a shallow aquifer, West BengalPotential role of the Fe(III)-reducing bacteria Geobacter and Geothrix in controlling arsenic solubility in Bengal delta sedimentsThe Role of Indigenous Microorganisms in the Biodegradation of Naturally Occurring Petroleum, the Reduction of Iron, and the Mobilization of Arsenite from West Bengal Aquifer Sediments
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P50
description
hulumtues
@sq
researcher
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wetenschapper
@nl
հետազոտող
@hy
name
Christopher Boothman
@ast
Christopher Boothman
@en
Christopher Boothman
@es
Christopher Boothman
@nl
Christopher Boothman
@sl
type
label
Christopher Boothman
@ast
Christopher Boothman
@en
Christopher Boothman
@es
Christopher Boothman
@nl
Christopher Boothman
@sl
prefLabel
Christopher Boothman
@ast
Christopher Boothman
@en
Christopher Boothman
@es
Christopher Boothman
@nl
Christopher Boothman
@sl
P106
P1153
7801357587
P21
P31
P496
0000-0002-4321-1719