Mechanism and Application of Anaerobic Oxidation of Methane Coupled to Various Electron Acceptors Reduction PDF Download
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Author: 白亚南
Publisher:
ISBN:
Category : Chemistry
Languages : en
Pages : 140
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Author: 白亚南
Publisher:
ISBN:
Category : Chemistry
Languages : en
Pages : 140
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Book Description
Author: Chiara Cassarini
Publisher: CRC Press
ISBN: 042982730X
Category : Science
Languages : en
Pages : 176
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Book Description
This research investigated new approaches to control anaerobic methane oxidation coupled to sulfate reduction (AOM-SR) and enrich anaerobic methanotrophs (ANME) and sulfate reducing bacteria (SRB) with the purpose of designing a suitable bioreactor for AOM-SR at ambient pressure and temperature. The current knowledge about AOM and the microorganisms involved in AOM are discussed. The effect of different substrates and pressures was investigated on the ANME and SRB community adapted to the shallow marine Lake Grevelingen, the Netherlands. Further, microorganisms from the Alpha Mound (Spain) deep sediment were enriched with methane gas as substrate in biotrickling filters (BTF) at ambient conditions for 147-230 days of operation. The effect of alternative sulfur compounds (sulfate, thiosulfate and elemental sulfur) were studied and the microbial community was characterized. The highest AOM and sulfate reduction rates were obtained in the BTF fed with thiosulfate as the electron acceptor (~0.4 mmol l-1 day-1), but the highest number of ANME was visualized in the sulfate fed BTF (ANME-2 43% of the total visualized archaea). A BTF was proposed as a suitable bioreactor for the enrichment of ANME and SRB at ambient pressure and temperature which could be potentially used for future biotechnological applications.
Author: Roel Johannes Wilhelmus Meulepas
Publisher:
ISBN: 9789085853978
Category :
Languages : en
Pages : 173
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Book Description
Author: Gerold Wefer
Publisher: Springer
ISBN: 9783662051283
Category : Science
Languages : en
Pages : 495
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Book Description
Ocean margins are the transitional zones between the oceans and continents. They represent dynamic systems in which numerous processes shape the environment and result in impacting the utilization and hazard potentials for humans. These processes are influenced by a variety of steering mechanisms, from mountain building and climate on the land to tectonics and sea-level fluctuations in ocean margins. This book examines various aspects of regulation for the long-term development of ocean margins, of the impact of fluids and of the dynamics of benthic life at and below the seafloor in ocean margin systems.
Author: Byung Hong Kim
Publisher: Cambridge University Press
ISBN: 1107171733
Category : Medical
Languages : en
Pages : 509
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Book Description
Extensive and up-to-date review of key metabolic processes in bacteria and archaea and how metabolism is regulated under various conditions.
Author: Chiara Cassarini
Publisher: CRC Press
ISBN: 0429827296
Category : Science
Languages : en
Pages : 261
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Book Description
This research investigated new approaches to control anaerobic methane oxidation coupled to sulfate reduction (AOM-SR) and enrich anaerobic methanotrophs (ANME) and sulfate reducing bacteria (SRB) with the purpose of designing a suitable bioreactor for AOM-SR at ambient pressure and temperature. The current knowledge about AOM and the microorganisms involved in AOM are discussed. The effect of different substrates and pressures was investigated on the ANME and SRB community adapted to the shallow marine Lake Grevelingen, the Netherlands. Further, microorganisms from the Alpha Mound (Spain) deep sediment were enriched with methane gas as substrate in biotrickling filters (BTF) at ambient conditions for 147-230 days of operation. The effect of alternative sulfur compounds (sulfate, thiosulfate and elemental sulfur) were studied and the microbial community was characterized. The highest AOM and sulfate reduction rates were obtained in the BTF fed with thiosulfate as the electron acceptor (~0.4 mmol l-1 day-1), but the highest number of ANME was visualized in the sulfate fed BTF (ANME-2 43% of the total visualized archaea). A BTF was proposed as a suitable bioreactor for the enrichment of ANME and SRB at ambient pressure and temperature which could be potentially used for future biotechnological applications.
Author: Emily J. Beal
Publisher:
ISBN:
Category :
Languages : en
Pages : 151
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Book Description
Although the anaerobic oxidation of methane (AOM) is a widely studied process, many of the geochemical requirements for it remain a mystery, in part because the responsible organisms are not in pure culture. It has been shown that freshwater AOM proceeds with nitrite and nitrate. However, before this study the only known electron acceptor in marine AOM was sulfate. The work of this study helps to illuminate some of the requirements of marine AOM in the Eel River Basin (ERB), CA, focusing on the methane source and electron acceptors which allow for this globally significant process to proceed. In Chapter 2, I use a finite difference thermal history model to indicate areas within the ERB that are capable of thermogenic methane production. Using the model results, I propose a correlation between areas with high rates of hydrocarbon production, methane seep location, and thus the areas within the ERB where high rates of AOM occur. The results of this study not only provide a potential link between geophysics/tectonics and microbiology, but also provide target areas within the ERB that could be used for microbiologic studies. Chapters 3 and 4 are incubation studies, targeted at understanding the role of electron acceptors, using sediment from methane seeps in the ERB. Methane oxidation is monitored by measuring the incorporation of 13C, from 13CH4, into the carbon dioxide in the headspace. In Chapter 3, I examine how the rate of AOM changes at varying sulfate concentrations, with a focus on concentrations lower than 1 mM. Although it is often stated that methane oxidation occurs in a 1:1 ratio with sulfate reduction, I find that at these low sulfate concentrations, methane oxidation and sulfate reduction are uncoupled, with methane oxidation rates sometimes an order of magnitude higher than sulfate reduction rates. Our experimentally determined rates of AOM are then put into an early Earth atmospheric photochemical model where it is shown that AOM causes a faster rise of oxygen and faster re-rise of methane than models that do not contain AOM. In Chapter 4, I test whether electron acceptors other than sulfate can be used in marine AOM. My results show the first direct evidence that both manganese (in the form of birnessite) and iron (in the form of ferrihydrite) can be used in marine AOM. Although the rates of manganese- and iron-dependent AOM are slower than sulfate-dependent AOM, these processes have the potential to gain more energy from methane oxidation. In addition, manganese- and iron-dependent AOM have the potential to be significant processes on early Earth when sulfate levels were extremely low. Chapter 5 continues the study of manganese- and iron-dependent AOM using phylogenetics and fluorescence in situ hybridization (FISH). In addition we incubated the experiments demonstrating manganese-dependent AOM with 15NH4Cl, during which active cells incorporate the 15N, and measured target aggregates from the incubation using FISH coupled to secondary ion mass spectrometry (FISH-SIMS) to determine the active cells in our incubation. Based on phylogenetic analysis, we find that both manganese- and iron-dependent AOM appear to be performed by distinct microbial assemblages and/or mechanism as compared to sulfate dependent AOM. SIMS analysis of aggregates in the manganese incubation indicate that mixed and mixed-cluster aggregates (of archaea and bacteria) and archaea of sarcina morphology are active and thus are likely responsible for manganese-dependent AOM.
Author:
Publisher:
ISBN: 9781321363418
Category : Electronic books
Languages : en
Pages : 141
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Book Description
In this dissertation I focused on some of the least-understood aspects of the carbon cycle in northern peatlands - the biological controls on production, the presence and importance of the anaerobic CH4 consumption pathway, and the physical controls on emission. A more clear understanding of the controls on CH4 emissions from critical northern peatland systems will help constraint predictive models of carbon-climate feedbacks. In chapter 1, I evaluated the linkages between porewater CH4, CO2, and iron concentrations within the upper active layer of a chronosequence of wetland basins in Barrow, Alaska. Iron concentrations varied amongst basin ages, with younger basins containing more iron in the upper soil profiles. Basin age also correlated with the thickness of the organic layer. Basinspecific seasonal mean porewater CH4 concentrations had a negative relationship with total Fe and Fe(III) concentrations; CH4 concentrations were positively related to organic layer thickness. Thus, the highest seasonal mean concentrations of CH4 were found in older basins with thick organic layers and low Fe loads. A manipulated experiment confirmed a direct suppression effect on net CH4 fluxes following Fe(III) and humic acids soil amendments, thus connecting in situ CH4 production and release with soil electron acceptor availability. Chapters 2 and 3 present the findings of a pair of anoxic soil incubations that use stable isotope tracers to simultaneously determine methanogenesis and anaerobic oxidation of methane (AOM) rates. In both experiments, I used treatments to determine the effect of different electron acceptors on CH4 cycling rates. The in vitro incubations of Alaskan soil showed a significant positive correlation between methanogenesis and AOM rates, and an increase in methanogenesis rates with increasing depth within the active layer. There was also an interaction between soil depth and the kinetic rate constant for AOM, suggesting that AOM increased with Fe(III) presence in shallow soil depths. Genetic surveys of Barrow soils show 16S rRNA and mcrA gene evidence for microbes closely related to known methanotrophs in the ANME groups 2 and 3. In Barrow soil incubations, AOM rates were greater than methanogenesis rates, causing negative net CH4 fluxes; net fluxes were lowest in shallow, Fe(III)-treated soils. Using soils from Finland, in vitro incubations revealed no relationship between rates of methanogenesis and AOM. Nitratetreated soils showed a significant suppression of methanogenesis, and a significant delay in the onset of AOM. While methanogenesis was greater than AOM, leading to a net positive soil CH4 flux, AOM consumed a considerable percentage of CH4 produced (6-39%), constituting a formidable constraint on CH4 emissions. Chapter 4 presents the results of a year-round field campaign in Finland. The annual flux data show strong seasonality in the CH4 fluxes. Interseasonal variations in carbon fluxes were not significantly related to either air or soil temperatures, although summer fluxes were positively related to air temperatures. There is also evidence for a substantial autumnal CH4 burst, and a lesser but still distinguishable burst during spring soil thaw, which combined accounted for a significant portion of the annual landscape CH4 flux. Summer CH4 fluxes were measured in situ, which allowed for the collection of data on the frequency and magnitude of CH4 ebullition events. Growing season CH4 ebullition events contributed an additional 50% of the diffusive CH4 atmospheric flux, and showed strong fine-scale heterogeneity within the wetland landscape.
Author: David L. Kirchman
Publisher: OUP Oxford
ISBN: 0191624225
Category : Science
Languages : en
Pages : 597
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Book Description
Microbial ecology is the study of interactions among microbes in natural environments and their roles in biogeochemical cycles, food web dynamics, and the evolution of life. Microbes are the most numerous organisms in the biosphere and mediate many critical reactions in elemental cycles and biogeochemical reactions. Because microbes are essential players in the carbon cycle and related processes, microbial ecology is a vital science for understanding the role of the biosphere in global warming and the response of natural ecosystems to climate change. This novel textbook discusses the major processes carried out by viruses, bacteria, fungi, protozoa and other protists - the microbes - in freshwater, marine, and terrestrial ecosystems. It focuses on biogeochemical processes, starting with primary production and the initial fixation of carbon into cellular biomass, before exploring how that carbon is degraded in both oxygen-rich (oxic) and oxygen-deficient (anoxic) environments. These biogeochemical processes are affected by ecological interactions, including competition for limiting nutrients, viral lysis, and predation by various protists in soils and aquatic habitats. The book neatly connects processes occurring at the micron scale to events happening at the global scale, including the carbon cycle and its connection to climate change issues. A final chapter is devoted to symbiosis and other relationships between microbes and larger organisms. Microbes have huge impacts not only on biogeochemical cycles, but also on the ecology and evolution of more complex forms of life, including Homo sapiens..
Author: Edward F. DeLong
Publisher: Springer
ISBN: 9783642301193
Category : Science
Languages : en
Pages : 567
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Book Description
The Prokaryotes is a comprehensive, multi-authored, peer reviewed reference work on Bacteria and Achaea. This fourth edition of The Prokaryotes is organized to cover all taxonomic diversity, using the family level to delineate chapters. Different from other resources, this new Springer product includes not only taxonomy, but also prokaryotic biology and technology of taxa in a broad context. Technological aspects highlight the usefulness of prokaryotes in processes and products, including biocontrol agents and as genetics tools. The content of the expanded fourth edition is divided into two parts: Part 1 contains review chapters dealing with the most important general concepts in molecular, applied and general prokaryote biology; Part 2 describes the known properties of specific taxonomic groups. Two completely new sections have been added to Part 1: bacterial communities and human bacteriology. The bacterial communities section reflects the growing realization that studies on pure cultures of bacteria have led to an incomplete picture of the microbial world for two fundamental reasons: the vast majority of bacteria in soil, water and associated with biological tissues are currently not culturable, and that an understanding of microbial ecology requires knowledge on how different bacterial species interact with each other in their natural environment. The new section on human microbiology deals with bacteria associated with healthy humans and bacterial pathogenesis. Each of the major human diseases caused by bacteria is reviewed, from identifying the pathogens by classical clinical and non-culturing techniques to the biochemical mechanisms of the disease process. The 4th edition of The Prokaryotes is the most complete resource on the biology of prokaryotes. The following volumes are published consecutively within the 4th Edition: Prokaryotic Biology and Symbiotic Associations Prokaryotic Communities and Ecophysiology Prokaryotic Physiology and Biochemistry Applied Bacteriology and Biotechnology Human Microbiology Actinobacteria Firmicutes Alphaproteobacteria and Betaproteobacteria Gammaproteobacteria Deltaproteobacteria and Epsilonproteobacteria Other Major Lineages of Bacteria and the Archaea
