Abstract
Large North Sea aquifers of high quality are the likely major target for 12 Gt of European CO2 emissions that should be stored in the subsurface by 2050. This involves an upscaling of the present combined injection rate from all European projects, which requires careful examination of the storage feasibility. Many aquifers are closed or semi-closed, with storage capacity mainly constrained by consideration of caprock failure criteria. Because the induced overpressure can propagate to sensitive regions far from the injector, the risk of caprock failure must be examined in terms of large volumes and for long times. This poses challenges with respect to fluid-flow simulation in the presence of highly uncertain aquifer properties. In this work, experts on geology, geophysics, geomechanics and simulation technique collaborate to optimize the use of existing data in an efficient simulation framework. The workflow is applied to the large North Sea Skade Formation, with potential for secondary storage and pressure dissipation in the overlying Utsira Formation. Injection at three locations in Skade gives an overall practical capacity of 1–6 Gt CO2 injected over a 50-year period, depending on the reservoir permeability and compressibility. The capacity is limited by local pressure buildup around wells for the lowest estimated reservoir permeability, and otherwise by regional pressure buildup in shallow zones far from the injection sites. Local deformation of clay due to viscoelastoplastic effects do not have an impact on leakage from the aquifer, but these effects may modify the properties of clay layers within the aquifer, which reduces the risk of lateral compartmentalization. Uplift of the seafloor does not impose constraints on the capacity beyond those set by pressure buildup.
Highlights
Carbon Capture and Storage (CCS) plays a significant role for necessary CO2 emission reductions in Europe
The workflow is applied to the large North Sea Skade Formation, with potential for secondary storage and pressure dissipation in the overlying Utsira Formation
The new geological characterization improves our understanding of the hydraulic connection between Skade and Utsira by including the proximal sands, time equivalent to Skade and Utsira, in the UK sector as part of the Utsira Formation. (The proximal sand is sometimes referred to as the Hutton Sand, a terminology choice we avoid for clarity.) In this way, we present a more reliable representation of the system boundaries
Summary
Carbon Capture and Storage (CCS) plays a significant role for necessary CO2 emission reductions in Europe. According to the energy roadmap prepared by the EU Commission (European Commission, 2011), emission reduction by CCS amounts to 12 Gt until 2050, out of a total of 80 Gt that should be kept out of the atmosphere in this time frame compared to “business as usual”. The average storage rate from 2025 to 2050 would be 500 Mt/year. Large offshore aquifers in the North Sea may account for much of these emission reductions. Several approaches of different complexity have been proposed when evaluating the suitability and capacity of target formations.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
