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Abstract

Summary

The North Sea’s potential as a Green Energy Hub depends on large-scale CO storage in shallow-marine sandstones, but the effects of geologic heterogeneity, such as permeability barriers and capillary entry pressure contrasts, remain underexplored. This study uses multiphase flow simulations on geologically realistic, surface-based reservoir models informed by outcrop analogue data from wave-dominated shoreface sandstones. We investigate how sedimentological heterogeneity influences CO plume migration, pressure evolution, and storage capacity.

Preliminary results show that capillary barriers tied to facies architecture and early cementation, conditioned to clinoform geometries, significantly control plume movement. These barriers promote lateral spreading and residual trapping, representing a potential upper limit on long-term CO storage when stable. Clinoform-related heterogeneity also induces flow compartmentalization, limiting pressure dissipation and enhancing anisotropy, which may reduce injectivity and cause spatially variable pressure buildup.

Comparisons with waterflood simulations reveal contrasting dynamics: water advances more uniformly, while CO migration is more sensitive to fine-scale architecture due to its lower interfacial tension and capillary entry pressures. These findings underscore the need to incorporate realistic sedimentological heterogeneity in dynamic models to avoid misestimating injectivity, pressure behavior, and storage security. This approach offers a robust framework for early-stage screening and risk assessment in complex storage settings.

© EAGE Publications BV
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/content/papers/10.3997/2214-4609.202521187
2025-10-27
2026-01-16

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References

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/content/papers/10.3997/2214-4609.202521187
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Capillary Pinning and the Role of Sedimentological Heterogeneity in CO2 Storage
Conference Proceedings 2025, 1 (2025); https://doi.org/10.3997/2214-4609.202521187
/content/papers/10.3997/2214-4609.202521187
/content/papers/10.3997/2214-4609.202521187
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