Dynamics of shallow marine gas hydrate and free gas systems

Multi-phase fluid flow is critical to the formation and concentration of gas hydrate in marine sediments. A transient, multi-phase (hydrate, gas and liquid) fluid and heat flow model is presented to describe hydrate formation in porous media. Fluid flux and physical properties of sediment largely control the dynamics of gas hydrate formation and free gas migration. In fine-grained sediments, hydrate formation leads to rapid permeability reduction and capillary sealing. Free gas accumulates below the hydrate layer until a critical gas column builds up, thereby forcing gas upward to the seafloor. In coarse-grained sediments, large volumes of gas are transported into the hydrate region to produce a significant change in salinity. An interconnected three-phase zone with high hydrate concentration and elevated salinity develops from the base of hydrate stability to the seafloor. Both processes may drive gas venting through the hydrate stability zone.; We also extend these models to demonstrate that the likely impact of climatic warming events on marine hydrate reservoirs. If hydrates are originally formed in the two-phase region, dissociated methane cannot be released to the ocean until the warming at the seafloor exceeds a critical value. However, all of hydrates formed within the three-phase zone are already at the dissociation boundary. Thus they can be affected by small warming events and are most susceptible to environmental changes.