Modelling large-scale carbon dioxide injection into the Bunter Sandstone in the UK Southern North Sea

International Journal of Greenhouse Gas Control

Jin

Bentham

et al. 2013

Self Cite

The Bunter Sandstone Formation in the UK Southern North Sea has the potential to become an important CO 2 storage unit if carbon dioxide capture and storage becomes a widely deployed option for the mitigation of greenhouse gases. A detailed geological model of a region of the Bunter Sandstone consisting of four domed structural closures was created using existing seismic, well log and core data. Compositional simulation of CO 2 injection was performed to estimate the storage capacity of domes within the system. The injection was constrained by both pressure and CO 2 migration criteria, and the storage efficiencies of the domes (volume of stored CO 2 divided by the pore volume of the dome) were calculated when injection ceased. A sensitivity study evaluated the effect of varying the total aquifer volume, reservoir heterogeneity and injection well location. A wide range of storage efficiency values were obtained across the different simulation cases, ranging from 4% (closed dome) to 33% (homogeneous model). Intra-reservoir heterogeneity, specifically in the form of continuous low permeability layers has an important effect on storage capacity in dome-like structures, because it increases the tendency for CO 2 to migrate laterally from the storage complex via structural spill points.

Section: Storage In Multiple Domesmentioning

confidence: 56%

Section: Additional Data For Simulation Modelsmentioning

confidence: 99%

Section: Base Case Model Boundary Conditionsmentioning

confidence: 99%

Section: Aquifer Sizementioning

confidence: 99%

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Modelling carbon dioxide storage within closed structures in the UK Bunter Sandstone Formation

International Journal of Greenhouse Gas Control

Jin

Bentham

et al. 2013

Self Cite

“…From a fracture-generation perspective, the maximum sustainable reservoir pressure could be assumed to be close to the leak-off pressure (LOP), the pressure at which fracture initiation occurs (Bell 1995), although a safety margin below this pressure is likely to be required for CO 2 storage. Noy et al (2012) presented a graph of LOP against depth to seabed for the UK sector of the SNS. This includes data from all stratigraphic intervals, to a depth of 3000 m. There is considerable variation in LOP v. depth.…”

Section: Co 2 Containment In Non-gas-bearing Structures Unfaulted Strmentioning

confidence: 99%

Pressure constraints on the CO ₂ storage capacity of the saline water-bearing parts of the Bunter Sandstone Formation in the UK Southern North Sea

Holloway

2014

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The Bunter Sandstone Formation (BSF) in the UK sector of the Southern North Sea is thought to have a significant potential for the injection and storage of anthropogenic CO 2 within periclines that lie above salt domes and pillows formed by halokinesis in underlying Zechstein strata. During the formation of the periclines, the BSF and its overlying top seals were subjected to extensional stresses and, in consequence, are commonly cut by seismically resolvable faults that present a risk to the containment of gas and buoyant fluids such as supercritical CO 2 . Although most of the closed structures in the BSF are saline water-bearing, eight gas fields (total gas initially-in-place >72 bcm (billion cubic metres)) have been discovered to date. The seismically resolved structure of these gas fields demonstrates that two different top seals, the Haisborough Group and the Speeton Clay, can seal gas columns of up to 128 and 104 m respectively, despite the presence of faults with small displacements above the field gas–water contacts. The observed gas columns are equivalent to CO 2 columns of up to around 100 m in height. Simple geomechanical modelling suggests that existing optimally orientated faults may dilate or be reactivated if the pore-fluid pressure increase as a result of CO 2 injection exceeds a gradient of about 13.4 MPa km –1 , potentially resulting in loss of storage integrity.

Water Resources Research

Multiphase Flow Characteristics of Heterogeneous Rocks From CO₂ Storage Reservoirs in the United Kingdom

Reynolds

Blunt

Krevor

2018

We have studied the impact of heterogeneity on relative permeability and residual trapping for rock samples from the Bunter sandstone of the UK Southern North Sea, the Ormskirk sandstone of the East Irish Sea, and the Captain sandstone of the UK Northern North Sea. Reservoir condition CO2‐brine relative permeability measurements were made while systematically varying the ratio of viscous to capillary flow potential, across a range of flow rates, fractional flow, and during drainage and imbibition displacement. This variation resulted in observations obtained across a range of core‐scale capillary number 0.2