Global ETD Search

1	Clay Minerals Supporting Microbial Metabolic Activities in Natural Sediments Zhang, Li 26 July 2019 (has links) No description available. Geobiology Clay minerals extracellular electron transfer NDFO, ammonium oxidation
2	Microbe-electrode interactions: The chemico-physical environment and electron transfer Gardel, Emily Jeanette 15 October 2013 (has links) This thesis presents studies that examine microbial extracellular electron transfer that an emphasis characterizing how environmental conditions influence electron flux between microbes and a solid-phase electron donor or acceptor. I used bioelectrochemical systems (BESs), fluorescence and electron microscopy, chemical measurements, 16S rRNA analysis, and qRT-PCR to study these relationships among chemical, physical and biological parameters and processes. / Engineering and Applied Sciences Biophysics Microbiology Electrical engineering bioelectrochemical systems extracellular electron transfer microbial fuel cells microbial metabolism microorganisms
3	Anaerobic ammonium oxidation (Anammox) coupled with extracellular electron transfer to semiconductive minerals by anammox bacteria Bibiano Guadarrama, Carlos 03 1900 (has links) No description available. Anammox Extracellular Electron Transfer Iron Oxide Minerals Humic Acid Isotopic Experiments
4	Extracellular electron transfer-dependent metabolism of anaerobic ammonium oxidation (Anammox) bacteria Shaw, Dario Rangel 08 1900 (has links) Anaerobic ammonium oxidation (anammox) by anammox bacteria contributes significantly to the global nitrogen cycle and plays a major role in sustainable wastewater treatment. To date, autotrophic nitrogen removal by anammox bacteria is the most efficient and environmentally friendly process for the treatment of ammonium in wastewaters; its application can save up to 60% of the energy input, nearly 100% elimination of carbon demand and 80% decrease in excess sludge compared to conventional nitrification/denitrification process. In the anammox process, ammonium (NH4+) is directly oxidized to dinitrogen gas (N2) using intracellular electron acceptors such as nitrite (NO2–) or nitric oxide (NO). In the absence of NO2– or NO, anammox bacteria can couple formate oxidation to the reduction of metal oxides such as Fe(III) or Mn(IV). Their genomes contain homologs of Geobacter and Shewanella cytochromes involved in extracellular electron transfer (EET). However, it is still unknown whether anammox bacteria have EET capability and can couple the oxidation of NH4+ with transfer of electrons to extracellular electron acceptors. In this dissertation, I discovered by using complementary approaches that in the absence of NO2–, freshwater and marine anammox bacteria couple the oxidation of NH4+ with transfer of electrons to carbon-based insoluble extracellular electron acceptors such as graphene oxide (GO) or electrodes poised at a certain potential in microbial electrolysis cells (MECs). Metagenomics, fluorescence in-situ hybridization and electrochemical analyses coupled with MEC performance confirmed that anammox electrode biofilms were responsible for current generation through EET-dependent oxidation of NH4+. 15N-labelling experiments revealed the molecular mechanism of the EET-dependent anammox process. NH4+ was oxidized to N2 via hydroxylamine (NH2OH) as intermediate when electrode was used as the terminal electron acceptor. Comparative transcriptomics analysis supported isotope labelling experiments and revealed an alternative pathway for NH4+ oxidation coupled to EET when electrode was used as electron acceptor. The results presented in my dissertation provide the first experimental evidence that marine and freshwater anammox bacteria can couple NH4+ oxidation with EET, which is a significant breakthrough that is promising in the context of implementing EET-dependent anammox process for energy-efficient treatment of nitrogen using bioelectrochemical systems. Anammox Extracellular electron transfer electroactive bacteria Bioelectrochemical systems Microbial electrolysis cell Ammonium removal
5	An Investigation Correlating Bioluminescence and Metal Ruduction Utilizing <i>Shewanella woodyi</i> Theberge, Allison Lindsey 30 May 2019 (has links) No description available. Chemistry Microbiology Shewanella woodyi extracellular electron transfer EET microbial metal reduction microbial electrochemical systems bioluminescence
6	Magnetite nanowires accelerated corrosion of C1020 carbon steel by Desulfovibrio vulgaris Alrammah, Farah 04 1900 (has links) Microbial-influenced corrosion (MIC) has been widely recognized as a significant economic and environmental problem in the oil and gas industry. MIC can be classified into two types based on the mechanisms: the extracellular electron transfer MIC (EET-MIC) and the metabolite MIC (M-MIC). The first includes electroactive bacteria that facilitate EET, while the latter includes bacteria that secrete corrosive metabolites. Sulfate-reducing bacteria (SRB) is believed to cause EET-MIC in carbon steel, a widely used metal in the oil and gas industry. In previous electroactive bacteria studies, nanowires have been shown to facilitate EET by acting as electron mediators. This study investigates the use of magnetite nanowires as electron mediators to accelerate EET-MIC of C1020 by Desulfovibrio vulgaris. The addition of 40 ppm (w/w) nanowires to carbon steel incubated with D. vulgaris, corrosive SRB species, for seven days resulted in 45% weight loss and 57% deeper pitting of carbon steel. Furthermore, electrochemical measurements of open circuit potential, linear polarization resistance and potentiodynamic polarization were found to be parallel with weight loss and pitting results. Therefore, these findings highlight the possibility of using magnetic nanowires as an electron mediator with high efficiency and selectivity to EET-MIC for future MIC studies and applications.
7	Identifications of Different Microbiologically Influenced Corrosion (MIC) Mechanisms and MIC Mitigation Using Enhanced Biocide Treatment Wang, Di 24 May 2022 (has links) No description available. Chemical Engineering Microbiologically influenced corrosion Extracellular electron transfer Biocide enhancer Electrochemical measurements Sulfate reducing bacteria Magnetite nanoparticles Peptide Biofilm
8	Microbiologically Influenced Corrosion (MIC) Mechanisms and Mitigation Xu, Dake 26 September 2013 (has links) No description available. Chemical Engineering Microbiologically Influenced Corrosion Sulfate reducing bacteria Nitrate reducing bacteria extracellular electron transfer bioenergentics D-amino acids biocide enhancer
9	Mechanisms of Microbiologically Influenced Corrosion Caused by Corrosive Biofilms and its Mitigation Using Enhanced Biocide Treatment Jia, Ru January 2018 (has links) No description available. Chemical Engineering Chemistry Microbiology Materials Science microbiologically influenced corrosion sulfate reducing bacteria sulfate reducing archaea carbon steel nitrate reducing bacteria extracellular electron transfer enhanced oil recovery biocide D-amino acid peptide electrochemical measurements
10	O<sub>2</sub>, Fe(III) mineral phase and depth controls on Fe metabolism in acid mine drainage derived iron mounds Burwick, John E. 14 September 2015 (has links) No description available. Biogeochemistry Environmental Geology Geochemistry Geobiology Geology Microbiology Acidophilic bacteria Fe metabolism Acid mine drainage Iron mound Dissolved Oxygen pH Fe II oxidation Fe III reduction Schwertmannite Goethite Fe III mineral bioavailability Fe III mineral transformation Extracellular electron transfer

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