Abstract
To prevent ocean acidification and mitigate greenhouse gas emissions, it is necessary to capture and store carbon dioxide. The Sleipner storage site, offshore Norway, is the world's first and largest engineered waste repository for a greenhouse gas. CO2 is separated from the Sleipner gas condensate field and stored in the pore space of the Utsira Formation, a saline aquifer approximately 1km below the surface and 200km from the coast. Statoil, the field operator, has injected almost 1Mt/yr of captured CO2 into the storage site since 1996. The buoyant CO2 plume ascended rapidly through eight thin shale barriers within the aquifer to reach the top seal in less than three years. The plume's progress has been monitored by eight seismic surveys, as well as gravimetric and electromagnetic monitoring, which record the spreading of nine thin CO2 layers. This paper presents a capillary flow model using invasion percolation physics that accurately matches the plume's geometry. The approach differs from standard Darcy flow simulations, which fail to match the plume geometry. The calibrated capillary flow simulation indicates that a mass balance for the plume is likely, but can only replicate the plume geometry if the thin intra-formational shale barriers are fractured. The model enables an estimate of the shale barrier behavior and caprock performance. The fractures are very unlikely to have been caused by CO2 injection given the confining stress of the rock and weak overpressure of the plume, and so fracturing must pre-date injection. A novel mechanism is suggested: the deglaciation of regional ice sheets that have rapidly and repeatedly unloaded approximately 1km of ice. The induced transient pore pressures are sufficient to hydro-fracture thin shales. The fractures enable fast CO2 ascent, resulting in a multi-layered plume. Shallow CO2 storage sites in the Northern North Sea and other regions that have been loaded by Quaternary ice sheets are likely to behave in a similar manner.
Highlights
Climate change and ocean acidification are driven by high rates of CO2 emission to the atmosphere
Two scenarios with identical geometry were tested by varying the threshold pressure of the shales within Utsira Formation: the first, a base case, assumed that the threshold pressure of approximately 1.6–1.9 MPa measured in core recovered from Lower Seal shales (Springer and Lindgren, 2006) is applicable to all shale barriers within the model
This paper has documented a numerical modeling approach that results in a plausible CO2 distribution and mass balance estimate
Summary
Climate change and ocean acidification are driven by high rates of CO2 emission to the atmosphere. CCS reduces the emission of CO2 at a power station, or other large industrial sources such as oil and gas fields This captured CO2 is compressed, transported by pipeline, and injected for storage into porous rock formations deep below the land or sea. The injection schedule is intended to remain at around 0.9 Mt/yr until around 2020, separating and storing CO2 from the West Sleipner gas-condensate field to prevent climate change. This is incentivized by the Norwegian state tax on offshore petroleum industry emissions, commencing in 1991 at NOK 210 and increasing to NOK 410 in 2013, equivalent to about $65 per tonne of CO2
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