Anmerkung: Intro -- Foreword and Dedication -- References -- Contents -- Part I: Introduction -- Chapter 1: Introduction to the Volume -- 1.1 Background -- 1.2 Introduction to the Volume -- References -- Part II: Physics and Chemistry of Deep Oil Well Blowouts -- Chapter 2: The Importance of Understanding Fundamental Physics and Chemistry of Deep Oil Blowouts -- 2.1 Introduction -- 2.2 The Oil -- 2.3 The Reservoir -- 2.4 Subsurface Release -- 2.5 Early Far-Field Fate -- References -- Chapter 3: Physical and Chemical Properties of Oil and Gas Under Reservoir and Deep-Sea Conditions -- 3.1 Molecular Composition and Physical Properties of Petroleum in Reservoirs -- 3.1.1 Source Dependence, Generation, Accumulation, and Alteration of Petroleum -- 3.1.2 Macondo Well Oil Molecular Characteristics -- 3.2 Physical Properties of Oil Under Deep Ocean Conditions -- 3.2.1 Bubble Point -- 3.2.2 Gas Saturation -- 3.2.3 Density and Swelling -- 3.2.4 Viscosity -- 3.2.5 Diffusivity -- 3.2.6 Interfacial Tension -- 3.3 Modeling Phase Equilibria (Gas-Oil-Water) in Oil Reservoirs and in the Deep Sea and Oil Constituent Partitioning -- 3.3.1 Bubble Point -- 3.3.2 Gas Saturation -- 3.3.3 Density and Swelling -- 3.3.4 Viscosity -- 3.3.5 Diffusivity -- 3.3.6 Interfacial Tension -- 3.4 Summary -- References -- Chapter 4: Jet Formation at the Spill Site and Resulting Droplet Size Distributions -- 4.1 Introduction -- 4.2 Determination of Drop Size Distributions in Laboratory and Field Settings -- 4.2.1 Pilot-Scale Jet Experiments -- 4.2.2 Stirrer Cells -- 4.2.3 DeepSpill: Field Experiment in the Deep Sea -- 4.2.4 Equipment for Field Measurements -- 4.2.5 Critical Review of Datasets -- 4.3 Modelling Approaches -- 4.3.1 Scaling-Based Models Using Dimensionless Numbers -- 4.3.2 Mechanistic Modelling. , 4.3.3 Novel Applications of Energy Dissipation Metrics to Understand Droplet Sizes from Experimental Data -- 4.4 Effects of Deep-Sea Blowout Characteristics -- 4.4.1 Influence of Dissolved Gases on the Droplet Size Distribution -- 4.4.2 Influence of Rapid Pressure Loss at the Wellhead and Phase Changes of the Oil -- 4.5 Capabilities and Limits of Subsea Dispersant Injection -- 4.6 Conclusions and Outlooks -- References -- Chapter 5: Behavior of Rising Droplets and Bubbles: Impact on the Physics of Deep-Sea Blowouts and Oil Fate -- 5.1 Introduction -- 5.2 Correlations for the Rise Velocity of Single Fluid Particles -- 5.3 Gas Bubble Behavior: Theoretical and Experimental Insights -- 5.4 Oil Droplet Behavior: Theoretical and Experimental Insights -- 5.5 How Reservoir and Deep-Sea Conditions Change Everything: Rise Behavior of Live Oil Droplets -- 5.6 Swarm Effects, Mass Transfer, and Gas Hydrates -- 5.7 Conclusion -- References -- Part III: Transport and Degradation of Oil and Gas from Deep Spills -- Chapter 6: The Importance of Understanding Transport and Degradation of Oil and Gasses from Deep-Sea Blowouts -- 6.1 Introduction -- 6.2 How Deep Subsea Spills Differ from Surface Releases -- 6.3 Properties of Oil Related to Fate and Transport -- 6.4 Fate of Oil and Gas: Understanding Where Oil Goes -- 6.5 Fate of Oil and Gas: Understanding the Degradation of Oil Components -- 6.6 Tracing the Fate of Oil in the Deep Sea: The Mass Balance -- References -- Chapter 7: Biodegradation of Petroleum Hydrocarbons in the Deep Sea -- 7.1 Introduction -- 7.2 Biodegradation in the Water Column -- 7.2.1 Rate of Liquid and Gaseous Hydrocarbon Biodegradation in the Water Column -- 7.2.2 Microbial Community Changes During the Spill, Pre-spill, and Post-spill -- 7.2.3 The Influence of Dispersants on Microbial Community and Biodegradation -- 7.3 Biodegradation in Sediments. , 7.3.1 Biodegradation of Petroleum in Marine Sediments (DWH and Other Case Studies) -- 7.3.2 Microbial Community Response in Deep Sea Sediments -- 7.4 Effect of High Pressure on Microbially Mediated Hydrocarbon Degradation -- 7.4.1 Ex Situ Incubations of Enriched Seawater and Sediments -- 7.4.2 Pure Culture Studies -- 7.5 Conclusions -- References -- Chapter 8: Partitioning of Organics Between Oil and Water Phases with and Without the Application of Dispersants -- 8.1 Introduction -- 8.2 Partition Device -- 8.3 Results -- 8.3.1 Partition Ratio Calculations -- 8.3.2 Partition Ratios Measured with the Application of Dispersant -- 8.4 Discussion -- 8.4.1 Effects of Pressure, Temperature, and Alkylation on Partitioning of Organics -- 8.4.2 Equilibrium Partition Ratio Along the Water Column -- 8.4.3 Use of Dispersants as a Spill Response Method -- 8.5 Conclusions -- References -- Chapter 9: Dynamic Coupling of Near-Field and Far-Field Models -- 9.1 Introduction -- 9.2 Models Description and Coupling -- 9.2.1 Near-Field Modeling -- 9.2.2 Far-Field Lagrangian Modeling -- 9.3 Coupled Near-Field and Far-Field Model -- 9.4 The Next Generation of Coupled Near-Field and Far-Field Models: Advancements -- References -- Chapter 10: Effects of Oil Properties and Slick Thickness on Dispersant Field Effectiveness and Oil Fate -- 10.1 Introduction -- 10.2 How Natural or Chemical Dispersion Affects Oil Slick Fate -- 10.3 Influence of Individual Key Parameters on Dispersion and Oil Slick Elongation -- 10.3.1 Main Oil Properties -- 10.3.2 Oil Layer Thickness -- 10.3.3 Initial Slick Size -- 10.3.4 Wind Speed -- 10.3.5 Dispersants -- 10.4 Decision-Making About Application of Chemical Dispersion -- 10.4.1 Effectiveness -- 10.4.2 Effects -- 10.4.2.1 Water Column -- 10.4.2.2 Benthic -- 10.5 Concluding Remarks -- References. , Chapter 11: Far-Field Modeling of a Deep-Sea Blowout: Sensitivity Studies of Initial Conditions, Biodegradation, Sedimentation, and Subsurface Dispersant Injection on Surface Slicks and Oil Plume Concentrations -- 11.1 Far-Field Modeling of Oil Spills -- 11.2 Laboratory Experiments and Observational Data for Numerical Modeling Support -- 11.2.1 Droplet Formation in Deep-Sea Conditions -- 11.2.2 Biodegradation of Hydrocarbons in the Water Column -- 11.2.3 Sediment Analysis -- 11.3 Numerical Simulation Description -- 11.3.1 Modeling and Experimental Setup -- 11.3.2 Suite of Numerical Case Studies -- 11.3.3 Model Output and Post-processing Variables -- 11.4 Modeling Results and Analyses -- 11.4.1 Surface Oil Expression -- 11.4.2 Oil Distribution in the Water Column and SSDI Effect -- 11.4.3 Modeled Oil Residue Sedimentation -- 11.5 Summary -- References -- Part IV: Oil Spill Records in Deep Sea Sediments -- Chapter 12: Marine Oil Snow Sedimentation and Flocculent Accumulation (MOSSFA) Events: Learning from the Past to Predict the Future -- 12.1 Defining of Marine Snow: An Operational Approach -- 12.2 Oil-Particle Interactions -- 12.3 Marine "Oil" Snow -- 12.4 MOS: Microhabitat and Entry Point to the Food Web -- 12.5 MOS: Sedimentation and Flocculent Accumulation -- 12.6 MOSSFA: Unique to the Deepwater Horizon Oil Spill? -- 12.7 MOS/MOSSFA: Modeling -- References -- Chapter 13: The Sedimentary Record of MOSSFA Events in the Gulf of Mexico: A Comparison of the Deepwater Horizon (2010) and Ixtoc 1 (1979) Oil Spills -- 13.1 Introduction -- 13.2 What Were the Characteristics of MOSSFA Sedimentary Inputs? -- 13.3 What Was the Extent of MOSSFA on the Seafloor? -- 13.4 What Postdepositional Processes Took Place as a Result of MOSSFA? -- 13.5 Can MOSSFA Be Preserved in the Sedimentary Record? -- 13.6 Conclusions -- References. , Chapter 14: Characterization of the Sedimentation Associated with the Deepwater Horizon Blowout: Depositional Pulse, Initial Response, and Stabilization -- 14.1 Introduction -- 14.2 Approach/Methods -- 14.2.1 Time-Series Approach/High-Resolution Sampling -- 14.2.2 Chronometers: Timing of Deposition -- 14.2.3 Sediment Texture and Composition -- 14.3 Sedimentary Response: Depositional Pulse (2010-2011) -- 14.4 Initial Sedimentary Response: Post-event (2011-2012) -- 14.5 Stabilization/Recovery: Post-event (2013-2016) -- 14.6 Preservation Potential in the Sedimentary Record -- 14.7 Critical Approaches/Methods -- 14.7.1 Rapid Response and Collection of Cores -- 14.7.2 Time Series -- 14.7.3 Sampling Resolution -- 14.7.4 MultiDisciplinary Approach -- 14.8 Conclusions -- References -- Chapter 15: Applications of FTICR-MS in Oil Spill Studies -- 15.1 Introduction -- 15.2 FTICR-MS Basics -- 15.3 Characterization of Source Oils and Weathered Oil Residues Using FTICR-MS -- 15.4 FTICR-MS Characterization of Dissolved Organic Matter and Its Relevance for Oil Spill Assessments -- 15.5 FTICR-MS Characterization of Marine Sediments and Its Relevance for Oil Spill Assessments -- 15.5.1 FTICR-MS Characterization of Marine Oil Snow Associations Generated by Oil Spills -- 15.6 Conclusions and Future Directions -- References -- Chapter 16: Changes in Redox Conditions of Surface Sediments Following the Deepwater Horizon and Ixtoc 1 Events -- 16.1 Introduction -- 16.2 Analytical Approach -- 16.3 Results and Discussion -- 16.3.1 Pre-impact Geochemistry -- 16.3.2 Post-impact: Organic Geochemistry -- 16.3.3 Post-impact: Mn Geochemistry -- 16.3.3.1 Post-impact: Explanation of Double Mn Peak -- 16.3.4 Post-impact: Re Geochemistry -- 16.3.4.1 Post-impact: Evolution of Re Enrichment -- 16.3.5 Post-impact: Ecological Consequences - Benthic Foraminifera. , 16.3.5.1 Post-impact: Ecological Consequences - Benthic Foraminifera (C-13 Depletion).

Anmerkung: Intro -- Contents -- Introduction -- Reactive Bubbly Flows-An  Interdisciplinary Approach -- Control of the Formation and Reaction of Copper-Oxygen Adduct Complexes in Multiphase Streams -- 1 Introduction -- 1.1 Basics of Cu/O2 Chemistry -- 1.2 Classical Systems -- 2 Novel Bisguanidine Copper Systems for O2 Activation and Transfer -- 2.1 Bisguanidine Toluene Systems for O2 Activation -- 2.2 Synthesis of Bisguanidine Toluene Systems for O2 Activation -- 2.3 Bisguanidine Toluene Systems for O2 Transfer -- 2.4 Fluorescence Studies with Bisguanidine Toluene Systems for O2 Transfer -- 3 Novel Hybrid Guanidine Copper Systems for O2 Activation and Transfer -- 3.1 Hybrid Guanidine Copper Systems for O2 Activation with Non-coordinating Anions -- 3.2 Hybrid Guanidine Copper Systems for O2 Activation with Coordinating Anions -- 3.3 Variations of the Amine Moiety in Hybrid Guanidine Ligands -- 4 Conclusion and Outlook -- References -- In Situ Characterizable High-Spin Nitrosyl-Iron Complexes with Controllable Reactivity in Multiphase Reaction Media -- 1 Introduction -- 2 [Fe(H2O)5(NO)]2+, the 'Brown-Ring' Chromophore -- 3 Syntheses, Structure and Bonding of {FeNO}7- and {Fe(NO)2}9-type Halogenido Nitrosyl Ferrates -- 4 Structure and Bonding of Nitrosyl-iron(II) Compounds with Aminecarboxylato Co-Ligands in Aqueous Solution -- 4.1 First Part: Less Stable Compounds -- 4.2 Second Part: Stable Compounds -- 4.3 Stability of the Fe-NO Linkage in Aqueous Solution -- 5 The 'Non-Innocent' Nitrosyl Ligand and the Challenge of IUPAC's Oxidation-State Assignment -- References -- Formation, Reactivity Tuning and Kinetic Investigations of Iron "Dioxygen" Intermediate Complexes and Derivatives in Multiphase Flow Reactions -- 1 Introduction -- 2 O2 Activation -- 3 The Iron HPTB System -- 3.1 General Aspects -- 3.2 Previous Investigations on the Iron HPTB System. , 3.3 Investigations on the Iron HPTB System -- 4 Conclusion and Outlook -- References -- Analysis of Turbulent Mixing Und Mass Transport Processes in Bubble Swarms Under the Influence of Bubble-Induced Turbulence -- 1 Introduction -- 2 Counterflow Water Channel -- 3 Characterization of the Counter-Flow Channel -- 4 Emulation of Bubble Induced Turbulence -- 4.1 Free Moving Particle Grids -- 4.2 Characterization of the Particle Grids and Turbulence Analysis -- 4.3 Conclusion -- 5 Behavior of a Single Bubble in Swarm like Background Turbulence -- 5.1 Experimental Setup -- 6 Movement in Emulated Turbulence -- 6.1 Deformation of the Surface -- 6.2 Influence of the Turbulence on the Bubbles Wake Structures -- 6.3 Conclusion -- 7 Conclusions and Outlook -- References -- Experimental Studies on the Hydrodynamics, Mass Transfer and Reaction in Bubble Swarms with Ultrafast X-ray Tomography and Local Probes -- 1 Introduction -- 2 Reaction Systems Used for Experimental Investigation of Bubbly Flows -- 2.1 Chemical Absorption of CO2 -- 2.2 Reaction of FeII(ligand)/NO -- 3 Experimental Setup and Methods -- 3.1 Bubble Column Setup for CO2 Absorption Measurements -- 3.2 Ultrafast X-ray CT for Investigation of Bubble Column Hydrodynamics -- 3.3 Wire-Mesh Sensor for Mass Transfer Measurements -- 3.4 Experimental Setup for Experiments with the FeII(edta)/NO System -- 4 Experimental Results -- 4.1  Gas Dynamics and Bubble Properties of Uniform Bubbly Flow -- 5 Conclusion and Outlook -- References -- Experimental Investigation of Local Hydrodynamics and Chemical Reactions in Taylor Flows Using Magnetic Resonance Imaging -- 1 Introduction -- 2 Experimental Flow Setup for the Investigation of Taylor Flows Inside a Horizontal Bore MRI Scanner -- 2.1 Initial Version of the Flow Setup -- 2.2 Improved Version of the Flow Setup -- 2.3 Hydrodynamic Investigation by PIV. , 3 Development of an MRI Setup for Taylor Flow Investigations Inside a Horizontal Bore MRI Scanner -- 4 Development of an MRI Method for Taylor Flow Investigations -- 4.1 Influence of Different MRI Parameters on the Acquired Data -- 4.2 Influence of Gas-Liquid Mass Transfer on the Acquired Data -- 4.3 MRI Sequence for Taylor Flow Investigation -- 4.4 MRI Data Acquisition and Processing -- 5 MRI of Hydrodynamics Inside Taylor Flows -- 6 MRI of Chemical Reactions Inside Taylor Flows -- 7 Conclusion and Outlook -- References -- Investigation of the Influence of Transport Processes on Chemical Reactions in Bubbly Flows Using Space-Resolved In Situ Analytics and Simultaneous Characterization of Bubble Dynamics in Real-Time -- 1 Introduction and Aims -- 2 Experimental Setups -- 2.1 Taylor Flow Setup -- 2.2 Real-Time Raman Process Analysis System -- 2.3 Continuous-Flow Setup with UV/VIS Spectroscopy -- 2.4 Real-Time Tomographic Process Analysis System -- 3 Experimental Results -- 3.1 Evaluation of Chemical Reaction Systems Based on Spectroscopy -- 3.2 Evaluation of the Confocal Laser Raman Spectroscopy Setup -- 3.3 Measurements of Reaction Kinetics with a SuperFocus Mixer -- 3.4 Concentration Measurements with the Real-Time Raman Process Analysis System Applied to a Taylor Flow of Gaseous CO2 in Aqueous Sodium Hydroxide Solutions -- 3.5 Measurement of a Wake Below a Gas Bubble Using Laser Beams -- 3.6 Characterization of the Real-Time Tomographic Process Analysis System -- 4 Summary and Conclusion -- References -- Determination of Intrinsic Gas-Liquid Reaction Kinetics in Homogeneous Liquid Phase and the Impact of the Bubble Wake on Effective Reaction Rates -- 1 Introduction/Motivation -- 2 Determination of Gas-Liquid Reaction Kinetics in Homogeneous Liquid Phase -- 2.1 Experimental Setup -- 2.2 Experimental Results. , 2.3 Kinetic Model of the Toluene Oxidation -- 2.4 Validation of the Kinetic Model -- 3 Numerical Study of the Toluene Oxidation in a Reactive Bubbly Flow -- 3.1 Numerical Model -- 3.2 Results -- 4 Study of the Toluene Oxidation in a Technical Bubble Column -- 4.1 Experimental Setup -- 4.2 Experimental Conditions -- 4.3 Results -- 5 Numerical Study of the Mixing Dependencies in a Reactive Bubbly Flow -- 5.1 Preliminary Considerations -- 5.2 Is the Overall Reaction Influenced by Mixing? -- 5.3 When Does Micro Mixing Affect the Overall Reaction Rate? -- 5.4 What Causes Mixture Masking? -- 6 Conclusions -- References -- Mass Transfer Around Gas Bubbles in Reacting Liquids -- 1 Introduction -- 1.1 Fluid Dynamics of Single Bubbles -- 1.2 Mass Transfer of Single Bubbles -- 2 Experimental Setup and Methods -- 2.1 Measurement of Velocities -- 2.2 Evaluation of Mass Transfer Coefficients -- 2.3 Material Properties and Fluid Dynamics of FeII(Ligand) Systems -- 3 Physical Mass Transfer -- 4 Chemical Reaction -- 4.1 Enhancement Factors Due to Chemical Reaction of CO2 in NaOHaq -- 4.2 System NO in FeII(Ligand) -- 5 Conclusion -- References -- Experimental Investigation of Reactive Bubbly Flows-Influence of Boundary Layer Dynamics on Mass Transfer and Chemical Reactions -- 1 Introduction -- 1.1 Mass Transfer in Reactive Bubbly Flows -- 2 Determination of Mass Transfer Relevant Kinetics in a SuperFocus Mixer -- 2.1 Sodium Sulfite Oxidation as a Model Reaction -- 2.2 Concentration Measurements Using Laser Induced Fluorescence (LIF) -- 2.3 Experimental Setup and Methods -- 2.4 Experimental Results -- 3 Investigation of Chemical Reactions by Means of Taylor Bubbles -- 3.1 Experimental Setup and Methods -- 3.2 Experimental Results -- 3.3 Analyzing Wake Structures at Taylor Bubbles Using Lagrangian Coherent Structures. , 3.4 Mass Balance for Wake Structures in Taylor Flows -- 4 Local Mass Transfer Measurements at Ascending Bubbles -- 4.1 Experimental Setup and Methods -- 4.2 Experimental Results -- 5 Conclusion and Outlook -- References -- Experimental Characterization of Gas-Liquid Mass Transfer in a Reaction Bubble Column Using a Neutralization Reaction -- 1 Experimental Setup of the Bubble Column -- 2 Applied Measurement Techniques -- 2.1 Bubble Characterization with Shadowgraphy and Particle-Tracking-Velocimetry -- 2.2 Mass Transfer Measurements through 2-Tracer-Laser-Induced-Fluorescence -- 2.3 Measurement of the Liquid Flow Field by Means of Particle Image Velocimetry -- 3 Reaction System -- 4 Results -- 4.1 Bubble Parameters -- 4.2 Mass Transfer from CO2-Bubbles -- 4.3 Mass Transfer Coefficients -- 4.4 Liquid Velocity -- 5 Conclusions -- References -- Modeling and Simulation of Convection-Dominated Species Transport in the Vicinity of Rising Bubbles -- 1 Introduction -- 2 Numerical Methods -- 2.1 Geometrical Volume-of-Fluid Approach -- 2.2 Single-Phase Approximation -- 3 Modeling of Convection-Dominated Concentration Boundary Layers -- 3.1 Overview -- 3.2 Effect of Insufficient Mesh Resolution -- 3.3 Analytical and Data-Driven Profile Reconstruction -- 3.4 Implementation in Simulation Approaches -- 3.5 Validation -- 4 Reactive Species Transport Around Single Rising Bubbles -- 4.1 Overview -- 4.2 Velocity and Concentration Fields -- 4.3 Species Transfer and Enhancement -- 4.4 Local Selectivity -- 5 Conclusion and Outlook -- References -- Development and Application of Direct Numerical Simulations for Reactive Transport Processes at Single Bubbles -- 1 Introduction -- 2 Model and Method -- 2.1 Mathematical Model -- 2.2 Numerical Methods -- 3 Numerical Validation -- 3.1 Computational Case Setup -- 3.2 Validation Study. , 4 Reactive Species Transfer from Single Rising Bubbles.

Anmerkung: Intro -- Foreword and Dedication -- References -- Contents -- Part I: Overview -- Chapter 1: Introduction to the Volume -- 1.1 Introduction -- 1.2 Focus of the Book -- 1.3 Final Thoughts -- References -- Chapter 2: Deepwater Oil and Gas Production in the Gulf of Mexico and Related Global Trends -- 2.1 Introduction -- 2.2 History of Oil Development and Production in the Gulf of Mexico -- 2.3 The Future of Oil and Gas Development in the Gulf of Mexico -- 2.4 Global Deepwater Resource Development -- 2.5 Summary -- References -- Chapter 3: Spilled Oil Composition and the Natural Carbon Cycle: The True Drivers of Environmental Fate and Effects of Oil Spills -- 3.1 Introduction -- 3.2 Carbon Cycle -- 3.3 Biologically Stored Energy -- 3.4 Environmental Redox Reactions -- 3.5 Understanding the Differences Between Persistent and Reactive Pollutants -- 3.6 Origin of Crude Oil -- 3.7 Composition of Crude Oils -- 3.7.1 Aliphatic Hydrocarbons -- 3.7.2 Aromatic Hydrocarbons -- 3.7.3 Non-hydrocarbons -- 3.7.4 Live Oil Versus Dead Oil -- 3.8 Oil Weathering -- 3.8.1 Floating or Subsurface Oil -- 3.8.2 Oil Impacts in Coastal Marshes -- 3.8.3 Subsurface Oil at Released Depth -- 3.8.4 Subsurface Oil's Slow Transit to the Surface -- 3.9 What About the Next Big Spill? -- 3.9.1 Critical Review of DWH Incident -- 3.9.2 Importance of Multidisciplinary Studies and Their Implications -- 3.9.3 Multidisciplinary Scientific Publications -- 3.9.4 Explaining What Happened to Broad Audiences -- 3.10 Conclusions -- References -- Part II: Geological, Chemical, Ecological and Physical Oceanographic Settings and Baselines for Deep Oil Spills in the Gulf of Mexico -- Chapter 12: Combining Isoscapes with Tissue-Specific Isotope Records to Recreate the Geographic Histories of Fish -- 12.1 Introduction -- 12.2 Marine Isoscapes -- 12.3 Overview of Variation in δ13C and δ15N Isoscapes. , 12.4 Effects of Scale on Isoscapes -- 12.5 Tissue-Specific Isotope Analysis -- 12.6 Site Fidelity Based on Two or More Tissues (Tissue Comparison Method) -- 12.7 Lifetime Isotope Records from Eye Lenses -- 12.8 Practical Solutions for Eye-Lens Analysis -- 12.9 Interpretation of Lifetime Isotopic Histories from Eye Lenses -- References -- Chapter 13: The Utility of Stable and Radioisotopes in Fish Tissues as Biogeochemical Tracers of Marine Oil Spill Food Web Effects -- 13.1 Introduction -- 13.2 Stable Isotopes Utilized to Infer Food Web Effects -- 13.2.1 Temporal Variability in Reef Fish Muscle Stable Isotopes -- 13.3 Petrocarbon Assimilation in the Gulf of Mexico Food Web -- 13.3.1 Radiocarbon Analysis of Reef Fish Muscle Tissue -- 13.3.2 Potential Long-Term Biomarkers -- 13.4 Summary and Implications for Future Marine Oil Spills -- References -- Chapter 14: Modernizing Protocols for Aquatic Toxicity Testing of Oil and Dispersant -- 14.1 Introduction -- 14.2 Understanding the Objectives for Aquatic Toxicity Testing of Oil and Dispersants -- 14.3 The Genesis of CROSERF Protocols -- 14.4 Evolution and Modification of CROSERF Methods -- 14.5 Lessons Learned from the DWH Spill and Recommendations for Future Oil Spill Toxicology Research -- 14.5.1 Recommendations for Modernizing of CROSERF Protocols -- References -- Chapter 15: Polycyclic Aromatic Hydrocarbon Baselines in Gulf of Mexico Fishes -- 15.1 Introduction -- 15.2 Pre-DWH Polycyclic Aromatic Hydrocarbon Baselines in Fish -- 15.3 Post-DWH and Ixtoc 1 Baselines in Fish -- 15.3.1 Seafood Safety -- 15.3.2 Hepatobiliary and Extrahepatic PAH Levels in Fish -- 15.4 Conclusions -- References -- Chapter 16: Case Study: Using a Combined Laboratory, Field, and Modeling Approach to Assess Oil Spill Impacts -- 16.1 Introduction -- 16.2 Case Study Overview -- 16.2.1 Target Species -- 16.2.2 Conceptual Model. , 16.2.3 Sensitivity Analysis -- 16.2.4 Developing a Targeted Research Strategy -- 16.3 Targeted Research -- 16.3.1 Field Research -- 16.3.1.1 Habitat suitability -- 16.3.1.2 Contaminant Distribution and Composition -- 16.3.2 Laboratory Research -- 16.3.2.1 Toxicity Effects -- 16.3.2.2 Demographic Endpoints -- 16.3.2.3 Density Dependence -- 16.3.3 Modeling -- 16.3.3.1 Interaction of Density Dependence and Contaminant Effects -- 16.3.3.2 Temperature-Dependent Demographic Rates -- 16.4 Assessing Risk Using Models of Varying Complexity -- 16.4.1 Models to Evaluate Risk -- 16.4.2 Model Outcomes -- 16.5 Summary and Recommendations for Future Studies -- References -- Chapter 4: An Overview of the Geologic Origins of Hydrocarbons and Production Trends in the Gulf of Mexico -- 4.1 Introduction -- 4.2 Evolution of Gulf of Mexico -- 4.3 Basic Ingredients Required to Generate Oil/Gas Accumulations -- 4.4 Exploration and Production Trends -- 4.5 Where Is the Industry Headed Next and Why? -- 4.6 Online Resources for Up-to-Date Information -- 4.7 Conclusions -- References -- Chapter 5: Gulf of Mexico (GoM) Bottom Sediments and Depositional Processes: A Baseline for Future Oil Spills -- 5.1 Introduction -- 5.2 Gulf of Mexico Basin -- 5.2.1 Eastern GoM Basin-Mississippi Fan -- 5.2.2 Western GoM Basin -- 5.2.3 Implications for Oiled Sediment Deposition/Accumulation -- 5.3 Carbonate-Dominated Margins: West Florida and Campeche Bank -- 5.3.1 West Florida -- 5.3.2 Campeche Bank -- 5.3.3 Implications for Oiled Sediment Deposition/Accumulation -- 5.4 Siliciclastic Margins: Northwest Florida to Mexico -- 5.4.1 Northern GoM Continental Margin: Northwest Florida to Central Texas -- 5.4.2 Western GoM Margin: Texas to Mexico -- 5.4.3 Southwestern GoM Margin: Mexico -- 5.4.4 Implications for Oiled Sediment Deposition/Accumulation -- 5.5 Cuba. , 5.5.1 Implications for Oiled Sediment Deposition/Accumulation -- 5.6 Conclusions -- References -- Chapter 6: Benthic Faunal Baselines in the Gulf of Mexico: A Precursor to Evaluate Future Impacts -- 6.1 Background -- 6.2 Developing a New Normal -- 6.2.1 Benthic Foraminifera -- 6.2.2 Meiofauna -- 6.2.3 Macrofauna -- 6.3 Conclusions -- References -- Chapter 7: Linking Abiotic Variables with Macrofaunal and Meiofaunal Abundance and Community Structure Patterns on the Gulf of Mexico Continental Slope -- 7.1 Introduction -- 7.2 Methods -- 7.2.1 Abiotic Variables -- 7.2.2 Biotic Variables -- 7.2.3 Diversity and Evenness -- 7.2.4 Principal Component Analysis -- 7.2.5 Nonmetric Multidimensional Scaling -- 7.3 Results -- 7.3.1 Environmental Analyses -- 7.3.2 Benthic Abundance and Community Analyses -- 7.3.3 Linking Environment and Benthos -- 7.3.4 Temporal Change -- 7.3.5 Diversity Spatial Change -- 7.4 Discussion -- 7.4.1 Environmental Analyses -- 7.4.2 Benthic Abundance and Community Analyses -- 7.4.3 Linking Environment and Benthos -- 7.5 Conclusion -- References -- Chapter 8: The Asphalt Ecosystem of the Southern Gulf of Mexico: Abyssal Habitats Across Space and Time -- 8.1 Introduction -- 8.2 Seep Habitats in the Northern Gulf of Mexico -- 8.3 A Novel Seep Process in the Southern Gulf of Mexico -- 8.4 The Asphalt Flow at Chapopote -- 8.5 Fresh Oil and Asphalt at Mictlan -- 8.6 Gas Seeps and Hydrate at Tsanyao Yang Knoll -- 8.7 Epifauna from the Campeche Knolls Chemosynthetic Communities -- 8.8 Research Questions and Resource Protection -- References -- Chapter 9: Geochemical and Faunal Characterization in the Sediments off the Cuban North and Northwest Coast -- 9.1 Introduction -- 9.2 Geographical Setting and Sampling -- 9.3 Sediment Characterization -- 9.4 Fauna Communities -- 9.4.1 Mollusks -- 9.4.2 Meiofauna -- 9.4.3 Foraminifera -- 9.5 Conclusions. , References -- Chapter 10: Mapping Isotopic and Dissolved Organic Matter Baselines in Waters and Sediments of the Gulf of Mexico -- 10.1 Introduction -- 10.2 Analytical Approaches -- 10.2.1 High-Resolution Mass Spectrometry: FTICR-MS -- 10.2.1.1 Stable Isotope Analysis -- 10.2.1.2 Radiocarbon Analysis -- 10.3 FTICR-MS -- 10.3.1 Geochemical Characterization of the FTICR-MS Composition of the Baseline Water Column Profile (at Multiple Depths) from Northern Gulf of Mexico -- 10.3.2 Geochemical Characterization of the FTICR-MS Composition of the Baseline Sediment WEOM from Northern Gulf of Mexico -- 10.3.3 Continuum Between Water Column and Sediments -- 10.4 Stable and Radiocarbon Isotopic Composition of Gulf of Mexico Organic Matter Pools -- 10.4.1 Dissolved Organic Carbon -- 10.4.2 Sinking Particulate Organic Carbon -- 10.4.3 Sedimentary Organic Carbon -- 10.4.4 Ramped Pyrolysis-Oxidation of Sedimentary Organic Matter -- 10.5 Conclusions and Baselines -- References -- Chapter 11: Toward a Predictive Understanding of the Benthic Microbial Community Response to Oiling on the Northern Gulf of Mexico Coast -- 11.1 Introduction -- 11.2 Fate of Petroleum Hydrocarbons at Pensacola Municipal Beach -- 11.3 Diagnosis of the Oil-Induced Bacterial Bloom Using Next-Generation Sequencing Methods -- 11.4 Using Metagenomics to Determine the Functional Response to Oil Contamination -- 11.5 Linking Advances in Metagenomics to Cultivation -- 11.6 Conclusions and Guidance for Future Emergency Response Efforts -- References -- Part III: Simulations of Future Deep Spills -- Chapter 17: Testing the Effect of MOSSFA (Marine Oil Snow Sedimentation and Flocculent Accumulation) Events in Benthic Microcosms -- 17.1 Introduction -- 17.2 Experimental Setup -- 17.2.1 Test Systems -- 17.2.2 Treatments -- 17.2.3 Analyses -- 17.3 Experimental Results -- 17.3.1 Oxygen Levels. , 17.3.2 Macroinvertebrates.

Anmerkung: Kiel, Univ., Habil.-Schr., 1997

Anmerkung: Zsfassung in dt. und. engl. Sprache , Zugl.: Bremen, Univ., Diss., 1990