Litcius/Paper detail

Swelling-induced self-sealing mechanism in fractured cap rock: Implications for carbon geosequestration

Hongyan Yu, Yihuai Zhang, Maxim Lebedev, Kun Meng, Sisi Chen, Michael Verrall, Lukman Johnson, Stefan Iglauer

2023AAPG Bulletin12 citationsDOI

Abstract

Abstract Carbon geosequestration (CGS) in geological formations is a technology that can drastically reduce anthropogenic greenhouse gas emissions. The CO2 injected into such storage formations is trapped beneath a cap rock, and it is thus obvious that cap rock sealing efficiency is an essential factor for secure CO2 storage. However, the exact effect of supercritical CO2 exposure to microfractured, clay-rich shale cap rock—note that shale cap rock commonly contains microfractures—is poorly understood. We imaged fractured cap rock shale samples before and after supercritical CO2 injection via x-ray micro computed tomography at high resolution in three dimensions (3.43 μm3) and representative reservoir conditions (i.e., a high pressure of 15 MPa and an elevated temperature of 50°C). Clearly, the fractures closed when flooded with supercritical CO2, which was most likely induced by clay swelling. As a consequence, the fracture permeability dramatically decreased, significantly increasing containment security and derisking CGS projects.

Topics & Concepts

GeologySwellingMechanism (biology)Carbon fibersGeotechnical engineeringGeochemistryPetrologyComposite materialMaterials scienceEpistemologyComposite numberPhilosophyRock Mechanics and ModelingMethane Hydrates and Related PhenomenaSeismic Imaging and Inversion Techniques