Description: Geochemical data (CH4, SO42−, I−, Cl−, particulate organic carbon (POC), δ13C-CH4, and δ13C-CO2) are presented from the upper 30 m of marine sediment on a tectonic submarine accretionary wedge offshore southwest Taiwan. The sampling stations covered three ridges (Tai-Nan, Yung-An, and Good Weather), each characterized by bottom simulating reflectors, acoustic turbidity, and different types of faulting and anticlines. Sulfate and iodide concentrations varied little from seawater-like values in the upper 1–3 m of sediment at all stations; a feature that is consistent with irrigation of seawater by gas bubbles rising through the soft surface sediments. Below this depth, sulfate was rapidly consumed within 5–10 m by anaerobic oxidation of methane (AOM) at the sulfate-methane transition. Carbon isotopic data imply a mainly biogenic methane source. A numerical transport-reaction model was used to identify the supply pathways of methane and estimate depth-integrated turnover rates at the three ridges. Methane gas ascending from deep layers, facilitated by thrusts and faults, was by far the dominant term in the methane budget at all sites. Differences in the proximity of the sampling sites to the faults and anticlines mainly accounted for the variability in gas fluxes and depth-integrated AOM rates. By comparison, methane produced in situ by POC degradation within the modeled sediment column was unimportant. This study demonstrates that the geochemical trends in the continental margins offshore SW Taiwan are closely related to the different geological settings.

Description: Gashydrate sind eisähnliche Verbindungen, in denen Hydratbildner, z.B. Methan, in hoher Dichte gespeichert werden können. Methanhydrate sind nur bei hohen Drücken und tiefen Temperaturen sowie in Anwesenheit hoher Methankonzentrationen stabil. Diese Stabilitätsbedingungen sind unter bestimmten Voraussetzungen in marinen Sedimenten erfüllt, in denen Methan durch den mikrobiellen Abbau von abgelagerter Biomasse entsteht oder aus größeren Tiefen zugeführt wird. Die globale Menge an Methan in marinen Gashydraten überschreitet die Menge an Erdgas in konventionellen Lagerstätten vermutlich um ein Mehrfaches. Eine potenzielle Nutzung von Gashydraten als zukünftige Energiequelle wird daher gegenwärtig weltweit untersucht. Erste Feldtests in Permafrostregionen und marinen Lagerstätten haben gezeigt, dass eine Produktion von Methan aus Gashydraten prinzipiell möglich ist. Eine Förderung von Methan aus Gashydraten kann technisch realisiert werden mittels Druckabsenkung, durch thermische Stimulation oder chemische Aktivierung. Die Injektion von CO2, ebenfalls ein Hydratbildner, kann eine solche Aktivierung der natürlichen Hydrate bewirken und das Methan in der Hydratstruktur ersetzen. Infolgedessen erscheint eine verfahrenstechnische Kombination von Hydratabbau und CO2-Speicherung als besonders sinnvoll, da im Idealfall eine emissionsarme bis -freie Energiegewinnung ermöglicht würde. Untersuchungen zur Aufklärung mechanistischer und fluiddynamischer Aspekte der CH4-CO2-Hydratumwandlung sowie zur Entwicklung eines technischen Verfahrens werden in unterschiedlichen Hochdruckanlagen auf verschiedenen Skalen durchgeführt. Diese speziellen Systeme bieten die Möglichkeit, marine Druck-, Temperatur- und Durchflussbedingungen zu simulieren. Sie sind mit verschiedenen Sensoren und Messsystemen (z.B. CTD, IR, Raman, MRI) ausgerüstet, um den Prozessverlauf störungsfrei zu überwachen. Basierend auf derzeitigen Ergebnissen erscheint die Injektion von erwärmtem, überkritischem CO2 als vielversprechender technischer Baustein für die Verfahrensentwicklung. Die Zuführung von Wärmeenergie bewirkt die initiale Destabilisierung der Gashydrate und die Freisetzung von CH4, während nach Abkühlung das CO2 seinerseits Hydrate bildet und als feste, immobile Phase im Sediment zurückgehalten wird. Sowohl Methanproduktion als auch CO2-Speicherung sind dabei abhängig von der Reservoirtemperatur, so dass die Prozesseffizienz und -ausbeute bei mittleren Temperaturen (8°C) höher ist als bei niedrigeren (2°C) und höheren Temperaturen (10°C). Dies deutet darauf hin, dass der Gesamtprozess durch die Raten der jeweiligen Teilreaktionen der Hydratzersetzung und Hydratneubildung stark beeinflusst wird. Der experimentelle Vergleich unterschiedlicher Injektionsmodi zeigt, dass eine alternierende CO2-Injektion bestehend aus Injektions- und Reaktionsintervallen höhere Ausbeuten erreicht als eine kontinuierliche Injektion.

Description: In order to proceed with speculative modelling of the impacts of potential leakage of geologically stored carbon, it is necessary to develop plausible scenarios. Here a range of such scenarios are developed based on a consensus of the possible geological mechanisms of leakage, namely abandoned wells, geological faults and operational blowouts. Whilst the resulting scenarios remain highly speculative, they do enable short term progress in modelling and provide a basis for further debate and refinement.

Description: Injection of CO2 into CH4-hydrate bearing sediments, and the resulting in-situ replacement of CH4-hydrate by CO2-hydrate, has been proposed as a technique for the emission-free production of natural gas from gas hydrates. While the hydrate conversion is thermodynamically feasible, many studies conclude that the overall process suffers from mass transfer limitations and CH4 production is limited after short time. To improve CH4 production various technical concepts have been considered, including the injection of heated supercritical CO2 combining chemical activation and thermalstimulation. While the feasibility of the concept was demonstrated in high-pressure flow-through experiments and high CH4 production efficiencies were observed, it was evident that overall yields and efficiencies were influenced by a variety of processes which could not be disclosed through bulk mass and volume analysis. Here we present different numerical simulation strategies which were developed and tested as tools to better understand the importance of mass and heat transport relative to reaction and phase transition kinetics for CH4 release and production, or for CO2 retention, respectively. The modeling approaches are discussed with respect to applicability for experimental design, process development or prediction of CH4 production from natural gas hydrate reservoirs on larger scales.

Description: Water permeability in gas hydrate bearing sediments is a crucial parameter for the prediction of gas production scenarios. So far, the commonly used permeability models are backed by very few experimental data. Furthermore, detailed knowledge of the exact formation mechanism leads to severe uncertainties in the interpretation of the experimental data. We formed CH4 hydrates from a methane saturated water solution and used Magnetic Resonance Imaging (MRI) to measure time resolved maps of the three-dimensional gas hydrate saturation. These maps were used for 3D Finite Elements Method (FEM) simulations. The simulation results enabled us to optimize existing models for permeabilities as function of gas hydrate saturation.

Description: The Alaska North Slope comprises an area of about 400,000 km2 including prominent gas and oil fields. Gas hydrates occur widely at the Alaska North Slope. A recent assessment by the USGS estimates 0.7-4.47 x 1012 m3 of technically recoverable gas hydrates based on well data and drilled hydrate accumulations. In spring 2012 a production field trial, testing CO2/N2 injection and depressurization, was conducted by USDOE/JOGMEC/ConocoPhillips at the Ignik Sikumi site. The 3D geological model of the Alaska North Slope developed by the USGS and Schlumberger is used to test the new gas hydrate module in the petroleum systems modeling software PetroMod®. Model results of the present extent of the gas hydrate stability zone (GHSZ) are in good agreement with results from well data. The model simulations reveal that the evolution of the GHSZ over time is primarily controlled by the climatic conditions regulating the extent of the permafrost during the last 1 Myr. Preliminary model runs predict the highest gas hydrate saturations near the major faults and at the bottom of the GHSZ, where thermogenic methane gas accumulates after migration through the most permeable stratigraphic layers (e.g. Sag River Sandstone Fm, Ivishak Fm). Gas hydrate saturations predicted for the Mount Elbert Stratigraphic Test Well and the Ignik Sikumi sites are basically controlled by the alternation of layers with different permeability and the fault properties (time of opening, permeability, etc). Further results including a total gas hydrate assessment for the Alaska North Slope will be presented during the conference.